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FACULTY OF CHEMICAL TECHNOLOGY AND ENGINEERINGLIST OF COURSES FOR EXCHANGE STUDENTS

ACADEMIC YEAR 2014/2015

CHEMICAL AND PROCESSING ENGINEERING

Course code (if applicable) Course title Person responsible for the

course

Semester (winter orsummer)

ECTS points

WTICH_ICHP_1A_S_1Adsorption engineering

Bogdan Ambrożek, PhD wintersummer

4

WTICH_ICHP_2A_S_2 Agitation and agitated vessels

Joanna Karcz, Professor wintersummer

4

WTICH_ICHP_1A_S_3 Bioprocess engineering Joanna Karcz, Professor wintersummer

4

WTICH_ICHP_1A_S_4 Chemical engineering design


4

WTICH_ICHP_1A_S_5 Chemical engineering fundamentals

Joanna Karcz, Professor wintersummer

4

WTICH_ICHP_1A_S_6 Chemical reaction engineering


4

WTICH_ICHP_1A_S_7 Environmental pollution control


4

WTICH_ICHP_2A_S_8 Fluizidation Bogdan Ambrożek, PhD wintersummer

4

WTICH_ICHP_1A_S_9 Heat transfer Bogdan Ambrożek, PhD wintersummer

3

WTICH_ICHP_1A_S_10 Heterogeneous catalysis Bogdan Ambrożek, PhD wintersummer

4

WTICH_ICHP_1A_S_11 Introduction to chemical engineering

Henryk Łącki, PhDBogdan Ambrożek, PhD

wintersummer

3

WTICH_ICHP_1A_S_12 Mass transfer Bogdan Ambrożek, PhD wintersummer

3

WTICH_ICHP_1A_S_13 Mathematical methods in chemical engineering


4

WTICH_ICHP_1A_S_14 Modeling and simulation in chemical engineering


4

WTICH_ICHP_2A_S_15 Multiphase flows Joanna Karcz, Professor wintersummer

4

WTICH_ICHP_1A_S_16 Natural gas engineering Bogdan Ambrożek, PhD wintersummer

4

WTICH_ICHP_1A_S_17 Numerical methods in chemical engineering


4

1

WTICH_ICHP_2A_S_18 Particulate technology Bogdan Ambrożek, PhD wintersummer

4

WTICH_ICHP_1A_S_19 Process dynamics and control


4

WTICH_ICHP_1A_S_20 Separation processes Bogdan Ambrożek, PhD wintersummer

4

WTICH_ICHP_1A_S_21 Transport phenomena Bogdan Ambrożek, PhD wintersummer

5

WTICH_ICHP_1A_S_22 Basic principles and calculations in chemical engineering

Józef Nastaj, profesorKonrad Witkiewicz, PhD

wintersummer

4

WTICH_ICHP_1A_S_23 Bioenvironmental heat and mass transfer

Józef Nastaj, professor wintersummer

4

WTICH_ICHP_1A_S_24 Chemical and process thermodynamics

Józef Nastaj, professorKonrad Witkiewicz, PhD

wintersummer

4

WTICH_ICHP_1A_S_25 Chemical engineering kinetics


wintersummer

4

WTICH_ICHP_1A_S_26 Chemical thermodynamics Józef Nastaj, profesorKonrad Witkiewicz, PhD

wintersummer

4

WTICH_ICHP_1A_S_27 Computer aided problems in chemical engineering


wintersummer

4

WTICH_ICHP_1A_S_28 Drying of biotechnology products


wintersummer

4

WTICH_ICHP_1A_S_29 Fundamentals of reservoir fluid behavior and its properties


4

WTICH_ICHP_1A_S_30 Hydrogen as a future energy carrier


4

WTICH_ICHP_1A_S_31 Introduction to modern thermodynamics


wintersummer

4

WTICH_ICHP_1A_S_32 Modern drying techniques – theory and practice


wintersummer

4

WTICH_ICHP_1A_S_33 Polymath, mathad and matlab for chemical engineers


wintersummer

4

WTICH_ICHP_1A_S_34 Simulation of chemical engineering processes using mathad and matlab


wintersummer

4

WTICH_ICHP_1A_S_35 The properties of gases and liquids


wintersummer

4

WTiICh/ISt/ICh/D-5b_36 Energy and environment Paulina Pianko-Oprych, PhDAssistant Professor

summer 4

WTiICh/IISt/ICh/D7-4b_37 Hybrid sources of energy Paulina Pianko-OprychAssistant Professor

winter 2

WTiICh/ISt/ICh/C-19_38 Chemical reactors engineering

Paulina Pianko-OprychAssistant Professor

winter 5

WTiICh/IISt/ICh/C1-1_39 Process design Paulina Pianko-Oprych, PhDAssistant Professor

summer 9

2

WTiICh/ISt/ICh/C-6_40 Technical thermodynamics Paulina Pianko-OprychAssistant Professor

winter 3

CHEMICAL TECHNOLOGY

Course code (if applicable) Course title Person responsible for the

course

Semester (winter orsummer)

ECTS points

WTiICh/ISt/TCh_1 Analysis of water and effluents

Sylwia Mozia assistant professor

summer 4

WTiICh_TCH_2A_S_D01_09_2

Characterization methods and properties of polymeric materials

Ph.D. Agnieszka Piegat winter 3

WTiICh/IISt/TCh/D12-1_3 Chemical processes in inorganic industry and environmental engineering i – separation techniques

Professor Maria Tomaszewska winter 4

WTiICh/IISt/TCh/D12-7_4 Chemical processes in inorganic industry and environmental engineering ii

Zofia Lendzion-Bieluń PhD summer 4

WTiICh/IISt/TCh/C-3_5 Chemical reactors Professor Beata Michalkiewicz summer 3

WTiICh/IISt/TCh/D12-1_6 Chemical processes in inorganic industry and environmental engineering i - separation techniques

Professor Maria Tomaszewska winter 4

WTiICh_TCh_7 Polymer composite Krzysztof Gorący PhDRyszard Pilawka PhD

wintersummer

WTiICh/IISt/TCh/D12-5_8 Computer-aided design of chemical industrial plants

Professor Ryszard J. Kaleńczuk winter 3

WTiICh/ISt/TCh/C15a_9 Biodegradable polymers Professor Miroslawa El Fray winter 5

WTiICh/ISt/TCh/D3-2a_10 Biomaterials Professor Miroslawa El Fray summer 4

WTiICh/IISt/TCh/D11-8_11 Biochemistry and biomimetics in synthesis of polymers

Professor Miroslawa El Fray winter 5

WTiICh/IISt/TCh/D11-1_12 Biopolymers and Biomaterials


Nano_1A_S_C26_13 Characterization methods for bio- and nanomaterials

Professor Miroslawa El Fray summer 1

Nano_1A_S_D2_03_14 Nanofillers and Nanocomposites

Professor Miroslawa El Fray summer 3

WTiICh_TCh_15 Polymer Chemistry Professor Miroslawa El Fray winter 5

WTiICh/IISt/TCh/D11-7_16 Biopolymeric Implants and Tissue Engineering


3

WTiICh/IISt/TCh_17Electrical engineering Dariusz Moszyński PhD winter 3

WTiICh/IISt/TCh/A-1_18 Elements of biotechnology Professor Maria Tomaszewska winter 3

WTiICh_TCh_19 Faserverbund kunststoffe Krzysztof Gorący PhDRyszard Pilawka PhD

wintersummer

WTiICh_TCh_20 Fundamentals of chemical process calculations

Grzegorz Lewandowski PhD summer 3

WTiICh/IISt/TCh-D12-4_21 Fundamentals of inorganic chemicals commodity science

Krzysztof Lubkowski PhD winter 2

WTiICh/IISt/TCh_22 Heterogeneous catalysis Dariusz Moszyński PhD winter 4

WTiICh/IISt/TCh_23 Industrial chemistry Krzysztof Lubkowski PhD wintersummer

2

WTiICh/IISt/TCh_24 IT technologies for chemical applications

Rafał J. Wróbel assistant professor

winter 2

WTiICh/IISt/ITChO/D10_25 Technology of Pressure-Sensitive Adhesives

Professor Zbigniew Czech winter 2

WTiICh_TCh_26 Physical Chemistry of Polymers

Beata Schmidt PhDKatarzyna Wilpiszewska PhD

wintersummer

1

WTiICh_TCh_27 Paints and adhesives technology

Krzysztof Kowalczyk PhD wintersummer

WTiICh_TCh_28 Biodegradable polymers Katarzyna Wilpiszewska PhD wintersummer

WTiICh/IISt/TCh_29 Measurements and automation

Dariusz Moszyński PhD winter 3

WTiICh/IISt/TCh/D10_30 Nanoparticles and environment

Beata Tryba university professor

winter 2

WTiICh/IISt/TCh/D12-10_31

Nanotechnology and crystalline nanomaterials

Ewa Borowiak-Paleń assistant professor

summer 2

WTiICh/IISt/TCh_32 Physical chemistry of surfaces


WTiICh/IISt/TCh/D12-8_33 Power engineering in chemical industry

Marek Gryta assistant professor summer 2

WTiICh/IISt/TCh/D12-11_34

Quality and risk management in chemical industry

Krzysztof Karakulski PhD summer 2

WTiICh/IISt/TCh/D12-1_35 Separation techniques Professor Maria Tomaszewska winter 4

WTiICh/IISt/TCh-D6-9_36 Small scale products in inorganic industry

Krzysztof Lubkowski PhD summer 2

WTiICh/IISt/TCh/C01_37 Surface phenomena and industrial catalytic processes

Rafał J. Wróbel assistant professor

winter 3

4

WTiICh_TCh_38 Surfactant chemistry and technology

Ewa Janus PhD winter 4

WTiICh/IISt/TCh/D12-6_39 Technological project Marek Gryta assistant professor winter 2

TCH_2A_S_D02_01_40 Technological project II Magdalena Urbala PhD summer 2

WTiICh/IISt/TCh/D12-2_41 Technologies for waste and pollutants minimization in chemical industry

Joanna Grzechulska – Damszel PhD

winter 2

WTiICh/IISt/TCh/D12-3_42 Testing methods of inorganic products


WTiICh/IISt/TCh_43 The selected technologies of organic industry

Agnieszka Wróblewska assistant professor

summer 2

WTiICh_TCh_44 Thermische Analyse von Kunststoffen

Dr.-Ing Krzysztof GoracyDr.-Ing. Ryszard Pilawka

wintersummer

WTiICh/IISt/TCh/C-3_45 Bioenergetic technology Professor Eugeniusz MilchertRobert Pełech PhDMarcin Bartkowiak PhD

summer 3

Additional courses

WTiICh/IISt/TCh_46 Separation techniques Professor Maria Tomaszewska winter 4

WTiICh/IISt/TCh_47 Electrical engineering Dariusz Moszyński PhD winter 3

WTiICh/IISt/TCh_48 Physical chemistry of surfaces


WTiICh/IISt/TCh_49 Measurements and automation


WTiICh/IISt/TCh_50 Heterogeneous catalysis Dariusz Moszyński PhD winter 3

WTiICh/IISt/TCh_51 Industrial chemistry Krzysztof Lubkowski PhD winter 2

WTiICh/IISt/TCh_52 Analysis of water and effluents

Sylwia Mozia PhD summer 4

WTiICh/IISt/TCh_53 Nanoparticles and environment

Beata Tryba university professor

winter 2

WTiICh/IISt/TCh_54 IT technologies for chemical applications

Rafał Wróbel assistant professor

winter 2

WTiICh/IISt/OSr/C-7_55 Analysis of air pollution Elżbieta Huzar, PhD wintersummer 4

WTiICh/IISt/OSr/D-3b_56 Analysis of food contaminants Alicja Wodnicka, PhD winter

summer 2

WTiICh/IISt/TCh/D4-8_57 Chemistry and technology of medicines

Halina Kwiecień, Assistant Professor

wintersummer 4

WTiICh/IISt/OSr/C-1_58 Chromatographic methods Małgorzata Dzięcioł, PhD wintersummer 4

5

WTiICh/ISt/TCh/D2-3_59WTiICh/ISt/TCh/D2-4_60WTiICh/ISt/TCh/D2-5_61

Research project Halina Kwiecień, Assistant Professor

wintersummer 12

WTiICh/ISt/OSr/B-6-1_62WTiICh/ISt/OSr/B-6-2_63

Technologies in environmental protection I and II

Elżbieta Huzar, PhD wintersummer

3 (I)2 (II)

WTiICh/IISt/TCh/D4-5_65WTiICh/IISt/TCh/D4-11_66

Technology of dyes and intermediates I and II


winter/summer

1 (I)1 (II)

WTiICh/IISt/OSr/C-10 Toxicological assessment of materials and products Małgorzata Dzięcioł, PhD winter/

summer 4

CHEMICAL AND PROCESS ENGINEERING

Course title Adsorption engineering

Person responsible for the course Bogdan Ambrożek, PhD

E-mail address to the person responsible for the course

[email protected]

Course code (if applicable) WTICH_ICHP_1A_S_1 ECTS points 4

Type of course Obligatory Level of course S1

Semester Summer/Winter Language of instruction English

Hours per week 3 Hours per semester 45

Teaching method Lecture - 2, Project – 2

Objectives of the course

The course aims to familiarize students with the basic of adsorption processes and methods of their design.

Entry requirements Physical chemistry, Chemical engineering fundamentals

Course contents

Introduction. History of adsorption engineering. Adsorbents. Adsorption equilibria. Thermodynamic of adsorption. Adsorption of gaseous mixtures. Rates of adsorption and transport effects. Adsorption processes and adsorption cycles. Batch processes. Fixed and moving bed processes. Fluidized bed. processes. Simulated moving bed processes. Regeneration of adsorbents. Pressure swing adsorption. Thermal swing adsorption. Design of adsorption systems. Short-cut and scoping methods. Modeling and simulation of adsorption systems. Aspen adsorption. Scale-up and pilot-plant studies of adsorption processes. Selected commercial adsorption processes.

Assessment methods Exam

Recommended readings

1. Ruthven D.M., Principles of adsorption and adsorption processes, Wiley, New York 1984.

2. Suzuki M., Adsorption engineering, Kodansha, Tokyo 1990. 3. Ruthven D.M., Knaebel K.S., Pressure swing adsorption, VCH, New York 1994.4. Thomas W. J., Crittenden B., Adsorption Technology and Design, Elsevier,

Amsterdam 1998.

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5. Yang R.T., Gas Separation by Adsorption Processes, Imperial College Press, London 1997.

6. Do D.D., Adsorption analysis: equilibria and kinetics, Imperial College Press, London 1998.

7. Yang R.T., Adsorbents : fundamentals and applications, Wiley, New York 2003. 8. Valenzuela D.P., Myers A. L., Adsorption Equilibrium Data Handbook, Prentice Hall,

New Jersey 1989.

Additional information

Course title Agitation and agitated vessels

Person responsible for the course Joanna Karcz, Professor


[email protected]





Teaching method Lecture - 1, Laboratory - 1, Project – 1


The course aims to give a general introduction to the theory and practice of agitation and agitated vessels.

Entry requirements Chemical engineering fundamentals

Course contents

Introductory Remarks: Agitation and agitated vessels; Types of the agitated vessels. Types of the impellers; Hydrodynamics in agitated vessels; Mixing time; Power consumption; Heat transfer; Mass transfer; Blending of miscible liquids; Solid-liquid mixing; Gas-liquid mixing; Liquid-liquid mixing; Gas-solid-liquid mixing. Mixing with chemical reactions; Mixing of particulate solids.



1. Harnby N., Edwards M.F., Nienow A.W., Mixing in the Process Industries, Butterworth-Heinemann, Oxford, 1997.

2. Mixing Equipment (Impeller Type), AIChE Equipment Testing Procedure, 3rd Edition, New York, 2001, ISBN 0-8169-0836-2.

3. Nagata S., Mixing. Principles and Applications, Halsted Press, New York, 1975.4. Paul E.L., Atiemo-Obeng V.A, Kresta S.M; (Ed.). Handbook of Industrial Mixing, John

Wiley & Sons, Inc., New York, 2004.5. Tatterson G.B.: Fluid Mixing and Gas Dispersion in Agitated Tanks, McGraw-Hill, Inc.,

New York, 1991.


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mailto:[email protected]

Course title Bioprocess engineering



[email protected]

Course code (if applicable)

WTICH_ICHP_1A_S_3 ECTS points 4




Teaching method Lecture - 2, Project – 1

Objectives of the course The course aims to give a general introduction to the theory of bioprocess engineering.


Course contents

Introductory Remarks: Biotechnology and bioprocess engineering; Regulatory constraints. An overview of biological basics of bioprocess engineering: Enzymes; Cells; Major metabolic pathways; The grow of cells. Engineering principles for bioprocesses: Operating considerations for bioreactors; Selection, scale-up, operation, and control of bioreactors; Recovery and purification of products; Instrumentation and control; Sterilization of process fluids; Finishing steps for purification; Integration of reaction and separation. Traditional Industrial Bioprocesses. Nonconventional bioprocesses.



1. Doran P.M., Bioprocess Engineering Principles, Academic Press, London 1995.2. Dutta R., Fundamentals of Biochemical Engineering, Springer, Berlin 2008.3. Lydersen B.K., D’Elia N.A., Nelson K.L., Bioprocess Engineering, John Wiley & Sons,

Inc., New York, 1994. 4. Shuler M.L., Kargi F., Bioprocess Engineering: Basic Concepts, Prentice Hall, New

Jersey 2002.5. Van’t Riet K., Tramper J., Basic Bioreactor Design, Marcel Dekker Inc., New York,

1991.6. Flickinger M.C., Drew S.W., Encyclopedia of Bioprocess Technology: Fermentation,

Biocatalysis, and Bioseparation, Wiley, New York 1999.


Course title Chemical engineering design



[email protected]

8





Teaching method Lecture - 2, project – 1

Objectives of the course The course aims to give a general introduction to the chemical engineering design


Course contents

Introduction to design. Design information. Physical properties of chemical compounds. Materials of Construction. Costing. Mechanical design of process equipment. Flow-sheeting. Material and energy balances. Energy utilization. Piping and instrumentation. Equipment selection, specification and design: separation columns, heat-transfer equipment. Aspen simulation. Plant location and site selection. Environmental considerations. Safety and loss prevention.



1. Sinnott R.K., Coulson & Richardson’s Chemical Engineering, Vol. 6: Chemical Engineering Design, Butterworth-Heinemann, Oxford 2003.

2. Luyben W.L., Distillation design and control using Aspen simulation, Wiley, New York 2006.


Course title Chemical engineering fundamentals



[email protected]





Teaching method Lecture - 2, Classes - 1, Laboratory - 1

Objectives of the course The course aims to give a general introduction to the chemical engineering

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Entry requirements Physics, mathematics

Course contents

Introduction. Units and dimensions. Flow of fluids. Energy and momentum balance. Flow in pipes and channels. Flow of compressible fluids. Flow of multiphase mixtures. Flow measurement. Pressure measurement. Mixing of Liquids. Pumping of fluids. Heat transfer. Mass transfer. The boundary layer theory. Simultaneous momentum, heat and mass transfer. Humidification and water cooling. Particulate solids. Motion of Particles in a Fluid. Sedimentation. Fluidization. Flow of Fluids through Granular Beds and Packed Columns. Liquid Filtration. Leaching. Distillation. Absorption of gases. Liquid - liquid Extraction. Evaporation.



1. Coulson J.M., Richardson J.F., Backhurst J. R., Harker J. H., Coulson & Richardson’s Chemical Engineering, Vol. 1: Fluid Flow, Heat Transfer and Mass Transfer., Butterworth-Heinemann, Oxford 1999.

2. Coulson J.M., Richardson J.F., Backhurst J. R., Harker J. H., Coulson & Richardson’s Chemical Engineering, Vol. 2: Particle Technology and Separation Processes, Butterworth-Heinemann, Oxford 2002.

3. Richardson J.F., Peacock D.G., Coulson & Richardson’s Chemical Engineering, Vol. 3: Chemical & Biochemical Reactors & Process Control, Butterworth-Heinemann, Oxford 2007.

4. Backhurst J.R., Harker J.H., Richardson J.F., Coulson & Richardson’s Chemical Engineering, Vol. 4: Solutions to the Problems in Vol. 1, Butterworth-Heinemann, Oxford 2001.

5. Backhurst J.R., Harker J.H., Coulson & Richardson’s Chemical Engineering, Vol. 5: Solutions to the Problems in Volumes 2 and 3, Butterworth-Heinemann, Oxford 2002.

6. Sinnott R.K., Coulson & Richardson’s Chemical Engineering, Vol. 6: Chemical Engineering Design, Butterworth-Heinemann, Oxford 2003.

7. Denn M.M., Chemical Engineering. An introduction, Cambridge University Press, New York 2012.

Course title Chemical reaction engineering



[email protected]





Teaching method Lecture - 2, Classes – 2

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Objectives of the course The course aims to familiarize students with the basic of chemical reaction engineering

Entry requirements Physical chemistry

Course contents

Introduction. Fundamental concepts. Kinetics of homogeneous reactions. Ideal batch reactors. Temperature and pressure effects. Basics of non-ideal flow. Compartment models. The dispersion model. The tanks-in-series model. The convection model. Heterogeneous reactions. The packed bed catalytic reactors. Fluid bed reactors. Trickle bed reactors. Slurryreactors. Three-phase reactors. Fluid-fluid reactors. Fluid-particle reactors. Biochemical reactors.



1. Fogler H.S., Elements of chemical reaction engineering, Prentice-Hall, New Jersey 1999.

2. Levenspiel O., Chemical reaction engineering, Wiley, New York 1999.3. Luyben W.L., Chemical reactor design and control, Wiley, New York 2007


Course title Environmental pollution control



[email protected]





Teaching method Lecture – 2, Classes - 2

Objectives of the course The course aims to familiarize students with the basic of environmental pollution control


Course contents

Introduction. Basic concepts. Air Pollution. Smog in troposphere. Ozone depletion in stratosphere. Acid Rain. Aerosols: deposition and nucleation. Control of air Pollution: absorption; adsorption, biofiltration, catalytic destruction. Particles capture. Water Pollution: organic, inorganic, biological. Waste Water Treatment: aerobic and anerobic digesters, activated sludge process. Soil pollution: types of soil pollution, sources of soil pollution, effects of soil pollution. Monitoring and control of soil pollution.

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1. Peirce J.J., Vesilind P.A., Weiner R.F., Environmental Pollution and Control, Elsevier, Amsterdam 1997.

2. Hill M.K., Understanding Environmental Pollution. A Primer, Cambridge University Press, Cambridge 2004.

3. Flagan R.C., Fundamentals of air pollution engineering, Prentice-Hall, New Jersey 1988.

4. Mirsal I.A., Soil Pollution: Origin, Monitoring and Remediation, Springer, Berlin 2004.


Course title Fluizidation



[email protected]





Teaching method Lecture - 2, Classes – 1

Objectives of the course The course aims to familiarize students with the basic of fluizidation


Course contents

Introduction. Mapping of fluidization regimes. Distributors. Gas jets. Pumping power. Bubbles in dense beds. Bubbling fluidized beds. High-velocity fluidization. Mixing, segregation, and Staging. Particle-to-gas mass and heat transfer. Catalytic Reactions in Fluidized Beds. Heat transfer between fluidized beds and surfaces. Size distribution of solids in fluidized beds. Industrial applications of fluidized beds. Design of fluidized beds operations.



1. Kunii D., Levenspiel O., Fluidization Engineering, Butterworth-Heinemann, Boston 1991.

2. Gupta C.K., Sathiyamoorthy D., Fluid Bed Technology in Materials Processing, CRC, Boca Raton 1999.

3. Smith P.G., Applications of Fluidization to Food Processing, Blackwell Science, Oxford 2007.

4. Gibilaro L.G., Fluidization dynamics, Butterworth-Heinemann, Boston 2001.


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Course title Heat transfer



[email protected]





Teaching method Lecture - 2, Classes - 1

Objectives of the course The course aims to familiarize students with the basic of heat transfer

Entry requirements Mathematics, Physics

Course contentsIntroduction. Heat conduction. Convective heat transfer: laminar and turbulent. Simultaneous heat and mass transfer. Boiling. Condensation. Radiation. Heat exchanger: type of equipment. Heat exchanger calculations. Using Aspen to design of heat exchanger.



1. Incropera F.P., Lavine A.S., DeWitt D.P., Fundamentals of Heat and Mass Transfer, Wiley, New York 2011.

2. Rathore M.M., Kapuno R.R., Engineering Heat Transfer, Jones & Bartlett Learning, Sudbury 2011.


Course title Heterogeneous catalysis



[email protected]





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Objectives of the course The course aims to familiarize students with the basic of heterogeneous catalysis


Course contents

Introduction. A brief history of catalysis. Surfaces and adsorption: Energetics; Pore structure and surface area; Isotherms and rates; Experimental aspects of adsorption. The catalytic process. The catalyst and the catalytic site. Catalyst preparation. Catalyst Characterization. Catalytic Reactors: Static reactors; Stirred and recirculation reactors; Flow reactors; Pulse Reactors. Measurement of catalytic kinetics. Exemplary catalytic reactions. Catalysis in environmental protection.



1. Ross J.R.H., Heterogeneous catalysis. Fundamentals and applications, Elsevier, Amsterdam 2012.

2. Satterfield, Charles N., Mass transfer in heterogeneous catalysis, R. E. Krieger Pub. Co., Huntington, N.Y. 1981.

3. J. M. Thomas, W. J. Thomas, Principles and Practice of Heterogeneous Catalysis, VCH, Weinheim 1997.


Course title Introduction to chemical engineering

Person responsible for the course

Henryk Łącki, PhDBogdan Ambrożek, PhD


[email protected]





Teaching method Lecture – 2, Classes -1

Objectives of the course The course aims to familiarize students with the history and basic of chemical engineering


Course contents Introduction. Chemical engineering definition: What is Chemical Engineering ?; How chemical engineering differs from pure chemistry or other types of engineering? What do Chemical

14

Engineers do?; Diversity of employment. History and perspectives of chemical engineering. Concerns of chemical engineering. Concept of unit operations. Case studies and examples. Basic tools of chemical engineering: physical, chemical, mathematical and biological sciences, transport phenomena, thermodynamics, kinetics and reactors design. Scaleup, modeling and simulation. Multiscale modeling.



1. Denn M.M., Chemical Engineering. An introduction, Cambridge University Press, New York 2012.

2. Furter W.F.(Ed.), History of Chemical Engineering, Advances in Chemistry Series (190), American Chemical Society 1980.


Course title Mass transfer



[email protected]






Objectives of the course The course aims to familiarize students with the basic of mass transfer


Course contentsIntroduction. Molecular diffusion. Convective mass transfer: laminar and turbulent. Simultaneous heat and mass transfer. Interface mass transfer. Mass exchanger: type of equipment. Mass exchanger calculations. Design of mass exchanger using Aspen.



1. Incropera F.P., Lavine A.S., DeWitt D.P., Fundamentals of Heat and Mass Transfer, Wiley, New York 2011.

2. Hines A.L., Maddox R.N., Mass transfer: fundamentals and applications, Prentice-Hall, New Jersey 1985.

3. Cussler E.L., Diffusion: mass transfer in fluid systems, Cambridge University Press, New York 1997.


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Course title Mathematical methods in chemical engineering



[email protected]





Teaching method Lecture -2, Classes - 2

Objectives of the course The course aims to familiarize students with the mathematical methods applied in chemical engineering

Entry requirements Fundamentals of mathematics

Course contents

Formulation of physicochemical Problems. Modelling: model building process. Model hierarchy. Models with many variables. Boundary conditions. Vector spaces. Matrices. Matrix algebra: row operations, direct elimination methods, iterative methods. Special functions. Ordinary differential equations. First-order equations. Solution methods for second-order nonlinear equations. Linear equations of higher order. Coupled Simultaneous ODE. Series solution methods. Integral functions. Staged-process models. The calculus of finite differences. Approximate methods for ODE solution. Perturbation methods. Initial value problems. Boundary value problems: weighted residuals. Elements of complex variables. Laplace transforms. Solution techniques for solving PDEs.



1. Rice R.G., Do D.D., Applied mathematics and modeling for chemical engineers, Wiley, New York 2012.

2. Finlayson B.A., Introduction to chemical engineering computing, Wiley, New York 2005.

3. Basmadjian D., The art of modeling in science and engineering, CRC, Boca Raton 2000.


Course title Modeling and simulation in chemical engineering



[email protected]


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Teaching method Lecture -2, Classes - 2

Objectives of the course The course aims to familiarize students with the basic of modeling and simulation in chemical engineering

Entry requirements Mathematics

Course contents

Analysis of experimental results. Nonlinear parameter estimation. Dimensional analysis. Scaling. Mathematical model development. Synthesis of sub-models. Classification of models: deterministic, stochastic, lumped and distributed parameter. Modelling and simulation techniques. Population balance models. Microbial population. Monte Carlo methods. Nonlinear dynamics and chaos.

Assessment methods Exam, exercise


1. Hangos K.M., Cameron L.T., Process modelling and model analysis, Academic Press, San Diego 2001.

2. Ingham J., Dunn I.J., Heinzle E., Prenosil J.E., Snape J.B., Chemical engineering dynamics, Wiley, Weinheim 2007.

3. Dobre T.G., Marcano J.G.S., Chemical engineering. Modelling, simulation and similitude, Wiley, Weinheim 2007.


5. Finlayson B.A., Introduction to chemical engineering computing, Wiley, New York 2005.


Course title Multiphase flows



[email protected]





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Teaching method Lecture - 2, Project - 1

Objectives of the course The course aims to give a general introduction to the theory of multiphase flow and to provide the necessary theoretical basis for design of multiphase pipelines.


Course contents

Introduction to multiphase flow: basic definitions, equations of motion, interaction with turbulence. Gas–liquid and liquid-liquid flow systems. Cavitation. Boiling and condensation. Fluid–solid flow systems. Fluidized beds. Aerosol flows. Particle separation systems. Spray systems. Dry powder flows. Granular flows. Microscale and microgravity flows. Multiphase interactions. Multiphase flows in pipes: flow regime maps, concentration distributions and pressure drop.



1. Brennen Ch.E., Fundamentals of Multiphase Flow, Cambridge University Press, Cambridge 2005.

2. Crowe C.T. (Ed.), Multiphase flow handbook, CRC Press, Boca Raton 2006.3. Faghri A., Zhang Y., Transport Phenomena in Multiphase Systems, Elsevier

Academic, Boston, 20064. Perry's Chemical Engineers' Handbook, McGraw-Hill, New York 2007.


Course title Natural gas engineering



[email protected]



Semester summer Language of instruction English



Objectives of the course The course aims to familiarize students with the basic of natural gas engineering

Entry requirements Fundamentals of chemical engineering

Course contents Introduction. Origin and production of natural gas. Composition and properties of natural gas. Gas processing. Recovery, storage, and transportation. Water removal. Liquids removal.

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Nitrogen removal. Acid gas removal. Fractionation. Hydrogen sulfide conversion. Processes. Compression and cooling. Volumetric measurement. Pipeline design. Transportation of LNG. Hydrate control. Pipeline cleaning. Emissions control and environmental aspects.



1. Guo B., Ghalambor A., Natural Gas Engineering Handbook, Gulf Publishing Company, Houston 2005.

2. Younger A.H., Natural Gas Processing Principles and Technology - Part I, II, University of Calgary 2004.

3. Abdel-Aal H.K., Aggour M., Fahim M. A., Petroleum and gas field processing, Marcel Dekker New York 2003.

4. Speight J.G., Natural Gas. A Basic Handbook, Gulf Publishing Company, Houston 2007.


Course title Numerical methods in chemical engineering



[email protected]






Objectives of the course The course aims to familiarize students with the basic of numerical methods and their application in chemical engineering


Course contents

Systems of linear algebraic equations. Systems of non-linear algebraic equations. Interpolation and curve fitting. Numerical differentiation. Numerical integration. Eigenvalues and eigenvectors of matrices. Solutions of ODEs: Runge Kutta, multistep methods, Gear’s algorithm, stiffness and stability of algorithms. Solutions of PDEs: finite difference, finite elements, method of lines, shooting methods. Introduction to optimization


Recommended readings 1. Beers K.J., Numerical methods for chemical engineering. Applications in MATLAB, Cambridge University Press, Cambridge 2007.

2. Elnashaie S., Uhlig F., Numerical techniques for chemical and biological engineers using MATLAB, Springer, New York 2007.

3. Warnecke G., Analysis and numerics for conservation laws, Springer, Berlin 2005.

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5. Chapra S.C., Canale R.P., Numerical Methods for Engineers, McGraw-Hill, Boston 1998.

6. Rao S.S., Applied Numerical Methods for Engineers and Scientists, Prentice Hall, New Jersey 2002.

7. Cutlib M.B., Shacham M., Problem Solving in Chemical Engineering with Numerical Methods, Prentice Hall, New Jersey 2009.

8. Hanna O.T., Sandall O.C., Computational Methods In Chemical Engineering, Prentice Hall, New Jersey 1995.

9. Constantinides A., Mostoufi N., Numerical Methods for Chemical Engineers with Matlab Applications, Prentice Hall, New Jersey 1999.

10. Kiusalaas J., Numerical Methods in Engineering with Python 3, Cambridge University Press, Cambridge 2013.

Course title Particulate technology



[email protected]






Objectives of the course The course aims to familiarize students with the basic of particulate technology

Entry requirements Fundamentals of chemical engineering

Course contents

Particle characterization. Particle size analysis. Motion of solid particles in a fluid. Multiple particle systems. Colloids and fine particles. Fluid flow through a packed bed. Filtration. Fluidization. Pneumatic transport. Separation of particles from a gas. Mixing and segregation of particles. Particles size reduction. Particles mechanics. Discharge of particulate bulk solids. Storage and flow of powders.



1. Rhodes M., Introduction to Particle Technology, Wiley, Chichester 2008.2. Particles, bubbles and drops-their motion, heat and mass transfer, World Scientific

Publishing, London 2006.3. Aste T., Tordesillas A., Di Matteo T. (Editors), Granular and complex materials, World

Scientific Publishing, London 2007.4. Gregory J., Particles in Water. Properties and Processes, CRC, Boca Raton 2006.

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Course title Process dynamics and control



[email protected]





Teaching method Lecture – 2, Laboratory - 2

Objectives of the course The course aims to familiarize students with the basic of process dynamics and control

Entry requirements Mathematics, Fundamentals of chemical engineering

Course contents

Introduction. Process modeling fundamentals. Modeling for process operation. Transformation techniques. Linearization of model equations. Operating points of a systems. Process simulation in Matlab Simulink. Frequency response analysis. The dynamic behavior of systems. Detailed analysis of selected processes: mixing process, chemical stirred tank reactors, tubular reactors, heat exchangers, evaporators and separators, distillation columns, fermentation reactors. Black box modeling. Time-series identification. Neural networks. Fuzzy modeling. Process control and instrumentation. Behaviour of controlled processes. Control of selected processes.



1. Roffel B., Betlem B., Process Dynamics and Control. Modeling for Control and Prediction, Wiley, Chichester 2006.

2. Ingham J., Dunn I.J., Heinzle E., Pfenosi1 J.E., Chemical Engineering Dynamics, VCH, Weinheim 1994.

3. Luyben M.L., Luyben W.L., Essentials of Process Control, MCGraw-Hill 1997.


Course title Separation processes



[email protected]

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Teaching method Lecture -2. Classes - 1

Objectives of the course The course aims to familiarize students with the basic of separation processes


Course contents

Introduction. Fundamental concepts. Thermodynamics of separation processes. Mass transfer and diffusion. Single equilibrium stages calculations. Flash calculations. Cascades systems. Hybrid systems. Absorption. Stripping of dilute mixtures. Distillation. Liquid–liquid Extraction. Multicomponent, multistage separations. Supercritical extraction. Membrane separations. Adsorption. Ion exchange. Chromatography. Electrophoresis. Mechanical phase separations.



1. Seader J.D., Henley E.J., Separation process principles, Wiley, New York 2006.2. Seader J. D., Henley E.J., Roper D.K., Martin R.E., Separation process principles.

Chemical and biochemical operations, Wiley, New York 2011.3. Wankat P.C., Separation Process Engineering, Prentice Hall, New Jersey 2012.4. Noble R.D., Terry P.A., Principles of chemical separations with environmental

applications, Cambridge University Press, New York 2004.


Course title Transport phenomena



[email protected]






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Objectives of the course The course aims to familiarize students with the basic of transport phenomena

Entry requirements Mathematics, Physics

Course contents

Momentum Transport: Viscosity; Mechanisms of momentum transport; Momentum balances; Velocity distributions in laminar and turbulent flow; Interphase transport of momentum in isothermal systems; Macroscopic balances for isothermal flow systems.Energy Transport: Mechanisms of energy transport; Thermal conductivity; Energy balances; Temperature distributions in solids; The equations of change for nonisothermal systems; Temperature distributions in turbulent flow; Interphase transport in nonisothermal systems; Macroscopic balances for nonisothermal systems.Mass transport: Mechanisms of mass transport; Diffusivity; Mass balances; Concentration distributions in solids. Equations of change for multicomponent systems; Concentration distributions in turbulent flow, Interphase transport; Macroscopic mass balances for multicomponent systems.



1. Bird R.B., Stewart W.E., Lightfoot E.N., Transport Phenomena, Wiley, New York 2007.

2. Brodkey R.S., Hershey H.C., Transport phenomena. A unified approach, McGraw-Hill, New York 1988.

3. Kessler, David P. Greenkorn. Kessler D.P., Greenkorn R.A., Momentum, heat, and mass transfer fundamentals, Marcel Dekker, Basel 1999.


Course title Basic principles and calculations in chemical engineering




[email protected]


WTICH_ICHP_1A_S_22 ECTS points 4

Type of course compulsory Level of course s1

Semester summer/winter Language of instruction English

Hours per week Lecture: 1hLaboratory: 2h Hours per semester Lecture: 15h

Computer Laboratory: 30h

Teaching method Lecture, and computer laboratory

Objectives of the courseDeveloping of systematic problem solving skills. Learning what material balances are, how to formulate and apply them, and how to solve them. Learning what energy balances are and how to apply them. Learning how to deal with the complexity of big problems.

Entry requirements Mathematics, physics, chemical engineering

Course contents Introduction to chemical engineering calculations: units and dimensions, conventions in

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methods of analysis and measurement, chemical equation and stoichiometry. Problem solving: techniques of problem solving, computer-based tools, sources of data. Material balances: the material balance, program of analysis of material balance problems, solving material balance problems that do not involve chemical reactions, solving material balance problems that involve chemical reactions, solving material balance problems involving multiple subsystems, recycle, bypass, and purge calculations. Gases, vapors, liquids, and solids: ideal gas law calculations, real gas relationships, vapor pressure and liquids, vapor-liquid equilibria for multicomponent systems, partial saturation and humidity, material balances involving condensation and vaporization. Energy balances: concepts and units, calculation of enthalpy changes, application of the general energy balance without reactions occurring, energy balances that account for chemical reaction, reversible processes and the mechanical energy balance, heats of solution and mixing, humidity charts and their use. Solving simultaneous material and energy balances: analyzing the degree of freedom in a steady-state process. Unsteady-state material and energy balances.

Assessment methods Lecture: examComputer Laboratory: class test


1. D.M. Himmelblau, Basic Principles and Calculations in Chemical Engineering, Prentice Hall International (UK) Limited, London, 1996

2. W.L. Luyben, L.A. Wenzel, Chemical Process Analysis: Mass and Energy Balances, Int. Ser. in Phys. & Chem. Eng. Sci., Englewood Cliffs, NJ, Prentice Hall, 1988

3. E.I., Shaheen, Basic Practice of Chemical Engineering, 2nd ed. Boston, Houghton Mifflin, 1984

4. B.E. Poling, J.M. Prausnitz, J.P. O’Connel, The Properties of Gases and Liquids, 5-th ed., McGraw-Hill, New York, 2001

5. J.B. Riggs, An Introduction to Numerical Methods, 2nd ed., Lubbock, TX,Texas Tech. University Press, 1994

Course title Bioenvironmental heat and mass transfer

Person responsible for the course Józef Nastaj, professor


[email protected]




Hours per week Lecture: 2hLaboratory: 2h Hours per semester Lecture: 30h

Computer laboratory: 30h


Objectives of the course Presentation of the basic energy and mass transport mechanisms to many biological and environmental processes.

Entry requirements Chemical engineering, physical chemistry

Course contents Problem formulation in the transport processes. Transport in the mammalian system. Transport in plant systems. Transport in industrial food and biological processing. Transport in the bioenvironmental system. Energy transfer: equilibrium, energy conservation, and temperature. Modes of heat transfer. Governing equation and boundary conditions of heat

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transfer. Conduction heat transfer: steady-state. Conduction heat transfer: unsteady-state. Convective heat transfer. Heat transfer with change of phase: freezing and thawing, freezing of pure water, freezing of solutions and biomaterials (solutions, cellular tissues, cooling rates and success of freezing), temperature profiles and freezing time, evaporation. Tadiativeheat transfer.

Assessment methods Lecture: examComputer laboratory: class test


1. A.K. Datta, Biological and bioenvironmental heat and mass transfer, Marcel Dekker Inc., New York 2002.

2. J.C. Slattery, Advanced transport phenomena, Cambridge University Press, Cambridge, 1999.

3. S.A. Berger, W. Goldsmith, E.R. Lewis, Introduction to bioengineering, Oxford University Press, Oxford, 1999.

4. C.J. Geankoplis, Transport processes and unit operations, Prentice-Hall International Ltd, New Jersey, 1993.


Course title Chemical and process thermodynamics




[email protected]


Type of course Compulsory Level of course s1


Hours per week Lecture: 2hComputer laboratory: 2h Hours per semester Lecture: 30h



Objectives of the courseAn attempt to produce thermodynamics lecture and laboratory suitable for the age of the personal computers. Computer-aided calculations, using a general purpose numerical analysis program - Polymath


Course contents

Introduction: the terminology of thermodynamics, the variables and quantities. Thermodynamics principles for open systems. Work in open system. The First Law of thermodynamics for open systems. The Second Law of thermodynamics. The PVT behavior of fluids. Generalized equation of state. Heat effects due to change of temperature, pressure or change of phase. Mixing heat effects. Chemical heat effects. Principles of phase equilibrium and applied phase equilibrium. Additional topics in phase equilibrium: Activity coefficients based on Henry’s law, the solubility of gases in liquids, solid-liquid equilibria. Chemical equilibrium. Principles of phase equilibrium.

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1. B.G. Kyle, Chemical and Process Thermodynamics, Prentice Hall PTR, New Jersey 1999.

2. H.D.B. Jenkins, Chemical Thermodynamics at Glance, Blackwell Publishing Ltd, Oxford 2008

3. M.B. Cutlip, M. Shacham, Problem solving in chemical engineering with numerical methods, Prentice Hall International Series in the Physical and Chemical Engineering Sciences, New Jersey, 2008.

4. H.S. Fogler, Elements of chemical reaction engineering, 4 th ed., Prentice Hall International Series in the Physical and Chemical Engineering Sciences, New Jersey, 2006.

5. D. Kondepudi, Introduction to modern thermodynamics, John Wiley & Sons Inc., Chichester, UK, 2008.

Course title Chemical engineering kinetics




[email protected]







Objectives of the course Presentation of the various kinetic problems in chemical engineering.

Entry requirements Mathematics, physics, chemical engineering

Course contents

Introduction to chemical engineering calculations: units and dimensions, conventions in methods of analysis and measurement, chemical equation and stoichiometry. Basic concepts and definitions. Chemical engineering kinetics and thermodynamics. A study of the design of chemical engineering systems. Kinetics of homogeneous systems and the interpretation of kinetic data. Heterogeneous systems. Two fluid-phase systems. Adsorption into quiescent and agitated liquids. Fixed bed adsorption. Fluid bed systems. The film model. Surface renewal models. Adsorption and chemical reaction. Chemical reaction engineering. The design of single and multiple reactors for simple, simultaneous and consecutive reactions. The influence of temperature, pressure and flow on chemical engineering systems. Residence.


Recommended readings 1. H.S. Fogler, Elements of chemical reaction engineering, 4 th ed., Prentice Hall International Series in the Physical and Chemical Engineering Sciences, New Jersey, 2006.

2. D.M. Himmelblau, Basic Principles and Calculations in Chemical Engineering,

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Prentice Hall International (UK) Limited, London, 1996 3. E.I., Shaheen, Basic Practice of Chemical Engineering, 2nd ed. Boston, Houghton

Mifflin, 1984


Course title Chemical thermodynamics




[email protected]




Hours per week Lecture: 2hComputer Laboratory: 2h Hours per semester Lecture:30

Laboratory: 30h


Objectives of the coursePresentation of difficult subjects like thermodynamics in a logical but, at the same time, quite thorough way. Thermodynamics and the necessary mathematics are embodied as a series of a dozen ‘frames’.


Course contents

Introduction: the terminology of thermodynamics, the variables and quantities. Thermodynamics principles for open systems. Work in open system. The First Law of thermodynamics for open systems. The Second Law of thermodynamics. The PVT behavior of fluids. Generalized equation of state. Heat effects due to change of temperature, pressure or change of phase. Mixing heat effects. Chemical heat effects. Principles of phase equilibrium and applied phase equilibrium. Additional topics in phase equilibrium: Activity coefficients based on Henry’s law, the solubility of gases in liquids, solid-liquid equilibria. Chemical equilibrium. Gibbs-Helmholtz equation. Qualitative interpretation of Van’t Hoff equation. Coupled reaction.






Course title Computer aided problems in chemical engineering

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[email protected]




Hours per week Lecture: 1hComputer Laboratory: 2h Hours per semester Lecture: 15h



Objectives of the course Solving of the selected problems in chemical engineering using computer programs

Entry requirements Chemical engineering, chemical and process thermodynamics, numerical methods

Course contents

Fundamental logic and the definition of engineering task. Complexity. Data structures. Object representation and reasoning. Fitting polynomials and correlation equations to vapor pressure data. Bubble point and dew point for a non-ideal multi-component mixture. Regression of heterogeneous catalytic rate data. Solution of stiff ordinary differential equations. Shooting method for solving two-point boundary value problems. Laminar flow of non-Newtonian fluids in a horizontal pipe. Unsteady-state conduction in two dimensions. Multicomponent diffusion in a porous layer covering a catalyst. Semibatch reactor with reversible liquid phase reaction.



1. B. Raphael, I.A.C. Smith, Fundamentals of computer-aided engineering, John Wiley & Sons Ltd., Chichester, 2003.

2. M.B. Cutlib, M. Shacham, Problem Solving in Chemical and Biochemical Engineering with POLYMATH, Excel, and MATLAB, Prentice Hall, Boston 2008.



Course title Drying of biotechnology products




[email protected]




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Hours per week Lecture: 1hComputer Laboratory: 2h Hours per semester Lecture: 15h

Laboratory: 30h


Objectives of the course Presentation of the theory and practice of drying process. Presentation of novel techniques and apparatuses for drying of biotechnology products.

Entry requirements Chemical engineering, thermodynamics

Course contents

General characteristics of biomaterials drying. Material and gas properties. Heat and mass transfer in drying processes. Drying kinetics. Experimental methods in drying. Drying methods peculiar to biotechnology products. Characteristics of biomaterials properties as objects of drying processes. Classification of biomaterials drying methods. Novel drying methods in drying of biotechnology products.



1. C. Strumiłło, T. Kudra, Drying: Principles, Applications and Design, Gordon and Breach Sci. Publ., New York 1986.



Course title Fundamentals of reservoir fluid behavior and its properties



[email protected]







Objectives of the course Introduction to the reservoir engineering of oil and natural gas.


Course contentsFundamentals of reservoir fluid behavior: classification of reservoir and reservoir fluids, pressure-temperature diagram, oil reservoir, gas reservoir, undefined petroleum fractions. Reservoir-fluid properties: properties of natural gases, behavior of ideal gases, behavior of

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real gases, effect of non-hydrocarbon components on the Z-factor, non-hydrocarbon adjustment methods, correction for high-molecular-weight gases, gas formation volume factor, properties of crude oil systems, crude oil gravity, specific gravity of the solution gas, gas solubility, bubble-point pressure, oil formation volume factor, crude oil density, crude oil viscosity. Laboratory analysis of reservoir fluids.



1. T. Ahmed, Reservoir engineering, 2nd ed.,Gulf Professional Publishing (Butterworth-Heinemann), Boston, 2001.


3. B.E. Poling, J.M. Prausnitz, J.P. O’Connel, The Properties of Gases and Liquids, McGraw-Hill, New York 2001.


Course title Hydrogen as a future energy carrier



[email protected]






Teaching method Lecture, and laboratory

Objectives of the course Presentation of the future possibility of a hydrogen application as a future energy carrier.

Entry requirements Chemical engineering, physical chemistry, thermodynamics

Course contents

Introduction: history of hydrogen. Hydrogen as a fuel: fossil fuels, the carbon cycle and biomass energy, the hydrogen cycle. Properties of hydrogen: hydrogen gas, interaction of hydrogen with solid surfaces, the four states of hydrogen and their characteristics and properties, surface engineering of hydrides. Hydrogen production: electrolysis – hydrogen production using electricity. Hydrogen storage. Applications: internal combustion engines, hydrogen in space applications, fuel cells using hydrogen.

Assessment methodsLecture: examComputer laboratory: class test

Recommended readings Züttel, A. Borgschulte, L. Schlapbach eds., Hydrogen as a future energy carrier, Viley-

VCH, Weincheim, 2008. Elvers ed., Handbook of fuels. Energy sources fortransportation, 2007.

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G.A. Olah, A. Goeppert, G.K.S. Prakash, Beyond oil and gas: The methanol economy, Viley-VCH, Weincheim, 2006.

K. Sundmacher, A. Kienle, H.J. Pesch, J.F. Berndt, G. Huppmannn eds., Molten carbonate fuel cells, Viley-VCH, Weincheim, 2007.

B.G. Kyle, Chemical and Process Thermodynamics, Prentice Hall PTR, New Jersey 1999.


Course title Introduction to modern thermodynamics




[email protected]








Modern thermodynamics is a theory of irreversible processes. Modern thermodynamics, formulated in twentieth century by Lars Onsager, Theophile De Donder, Ilya Prigogine and others is a theory of irreversible processes that very much include time: it relates entropy, the central concept of thermodynamics, to irreversible processes.


Course contents

Introduction: the terminology of thermodynamics, the variables and quantities. Basic concepts and the laws of gases. The First Law of thermodynamics.. The Second Law of thermodynamics and the arrow of time. Entropy in the realm of chemical reactions. Premium principles and general thermodynamic relations. Applications: equilibrium and equilibrium systems. Thermodynamics of phase change. Thermodynamics of solutions. Thermodynamics of chemical transformations. Introduction to non-equilibrium systems. Thermodynamics of radiation. Biological systems. Classical stability theory. Critical phenomena and configurational heat capacity. Elements of statistical thermodynamics.



1. D. Kondepudi, Introduction to modern thermodynamics, John Wiley & Sons Inc., Chichester, UK, 2008.



4. Kondepudi, I. Prigogine, I. Modern thermodynamics: from heat engines to dissipative structures, John Wiley & Sons Inc., Chichester, UK, 1999.

5. P. Mannevile, Dissipative structures and week turbulence, Academic Press, San Diego, 1990.

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Course title Modern drying techniques – theory and practice




[email protected]




Hours per week Lecture:1hComputer laboratory: 2h Hours per semester Lecture: 15h



Objectives of the course Presentation of the theory and practice of drying process. Presentation of novel techniques and apparatuses for drying of various materials


Course contents

Moisture in gases and solids: thermodynamic of moist gas, thermodynamic of moist solids. Heat and mass transfer in drying processes. Drying kinetics. Experimental methods in drying. General principles of dryer design. Mathematical modeling of drying processes. Drying in energy fields. Performance of industrial dryers. Miscellaneous drying problems: selection of dryer, energy aspects.


Recommended readings6. C. Strumiłło, T. Kudra, Drying: Principles, Applications and Design, Gordon and Breach Sci.

Publ., New York 1986.7. B.G. Kyle, Chemical and Process Thermodynamics, Prentice Hall PTR, New Jersey 1999.


Course title Polymath, mathad and matlab for chemical engineers


Józef Nastaj, professorKonrad Witkiewicz,PhD


[email protected]




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Objectives of the course Practical use of the Polymath, Mathcad and Matlab to solving of the various computational problems appearing in chemical and process engineering

Entry requirements Chemical engineering, mathematics, numerical methods

Course contents

Problem solving with mathematical software packages. Basic principles and calculations. Regression and correlation of data. Problem solving with Polymath. Problem solving with Mathcad. Problem solving with Matlab. Advanced techniques in problem solving. Thermodynamic problems. Selected fluid mechanics problems. Selected heat transfer problems. Selected mass transfer problems. Problems of chemical reaction engineering. Phase equilibria and distillation. Process dynamic and control. Biochemical engineering.




2. H. Moore, Matlab for engineers, 2nd ed., Pearson Education International, New York, 2007.

3. O.T. Hanna, O.C. Sandall, Computational methods in chemical engineering, Prentice Hall International Series in the Physical and Chemical Engineering Sciences, New Jersey, 1995.

4. L. Fausett, Numerical methods using Mathcad, Prentice Hall, Pearson Education Ltd., London, 2002.

5. L. Fausett, Numerical methods using Matlab, Prentice Hall, Pearson Education Ltd., 2nd ed., London, 2007.

6. H.S. Fogler, Elements of chemical reaction engineering, 4 th ed., Prentice Hall International Series in the Physical and Chemical Engineering Sciences, New Jersey, 2006.

Course title Simulation of chemical engineering processes using mathad and matlab




[email protected]






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Objectives of the course Presentation of the selected chemical and process engineering problems and their solution using Mathcad or Matlab.

Entry requirements Chemical engineering, mathematics, numerical methods

Course contents

Solution of the selected problems in chemical engineering: basic principles and calculations, problems of regression and correlation of data, advanced solution methods in problem solving. Thermodynamics. Heat transfer. Mass transfer. Problems of fluid mechanics. Examples of selected problems: dew point calculation for an ideal binary mixture, variation of reaction rate with temperature, shooting method for solving two-point boundary value problems, fugacity coefficients for ammonia – experimental and predicted, optimal pipe length for draining a cylindrical tank in turbulent flow, heat transfer from a triangular fin, unsteady-state conduction in two dimensions, simultaneous heat and mass transfer in catalyst particles.



1. L. Fausett, Numerical methods using Mathcad, Prentice Hall, Pearson Education Ltd., London, 2002.

2. L. Fausett, Numerical methods using Matlab, Prentice Hall, Pearson Education Ltd., 2nd ed., London, 2007.

3. O.T. Hanna, O.C. Sandall, Computational methods in chemical engineering, Prentice Hall International Series in the Physical and Chemical Engineering Sciences, New Jersey, 1995.


5. H. Moore, Matlab for engineers, 2nd ed., Pearson Education International, New York, 2007.

Course title The properties of gases and liquids




[email protected]



Semester Summer/winter Language of instruction English

Hours per week Lecture: 2hComputer aboratory: 2h Hours per semester Lecture: 30h



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Objectives of the course The prediction methods of various properties data of the gases and liquids.


Course contents

The estimation of physical properties. Pure component constants. Thermodynamic properties of ideal gases. Pressure-Volume-Temperature relationships of pure gases and liquids. Pressure-Volume-Temperature relationships of mixtures. Thermodynamic properties of pure components and mixtures. Fluid phase equilibria in multicomponent systems. Viscosity. Thermal conductivity. Diffusion coefficient. Surface tension.

Assessment methods

Recommended readings8. B.E. Poling, J.M. Prausnitz, J.P. O’Connel, The Properties of Gases and Liquids, McGraw-

Hill, New York 2001.9. B.G. Kyle, Chemical and Process Thermodynamics, Prentice Hall PTR, New Jersey 1999.


Course title Energy and environment

Teaching method Lecture, classes


Paulina Pianko-Oprych, PhDAssistant Professor


[email protected]

Course code (if applicable) WTiICh/ISt/ICh/D-5b_36 ECTS points 4

Type of course elective Level of course S1


Hours per week Lecture: 2hClasses: 1h Hours per semester Lecture: 30h

Classes: 15h


Familiarize students with the basic concepts of integrated ways of using available renewable energy sources. As a result of completion of the course the student should understand and know the principles of operation of various types of non-conventional energy sources. Student acquire skills for calculating energy systems such as solar collectors, heat pumps, biomass boilers.

Entry requirements Mathematics, Physics, Technical Thermodynamics

Course contents Lecture: Basic concepts related to the use of energy. Environmental aspects of energy production and use: pollution of the atmosphere, hydrosphere and lithosphere, the greenhouse effect, changes in the stratospheric ozone layer, acid rain. Basic concepts and principles of thermodynamics necessary for the understanding of energy conservation. Motor cycles, refrigerators and heat pumps, the irreversibility of the process, exergy, exergy efficiency (type II). Thermodynamic analysis of thermal processes. Global energy balances. Analysis of energy utilization. Economical use of energy and how its recovery. Heat pumps, energy accumulation, isolation. Waste heat recovery. Complete heating and cooling systems in manufacturing plants. Heat exchanger network design. Combined heat and power. Renewable energy sources and assess the possibility of their use. Renewable energy technologies for the production of electricity, heat and hydrogen.Classes:Open system energy balance. Analysis of the rendering of heat: heat and mass balance in terms

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of concurrent heat exchanger and counter (heat exchange with the phase transition, and without it), driving the temperature differential, transfer coefficients and heat transfer, heat transfer surface. Basic concepts and principles of thermodynamics. Law of thermodynamics for open and closed system. Enthalpy calculations. Circuits: Clausius - Rankine, heat pumps, refrigeration applied using low temperature waste energy. Thermodynamic analysis of thermal processes. Exergy: global exergy balance, the calculation of exergy losses and efficiency.

Assessment methods Lecture: class testClasses: class test


1. DOE fundamentals Handbook Thermodynamics, heat transfer and fluid flow, Washington, 1992.

2. D.H.F. Liu, B.G. Liptak, Environmental Engineers’ Handbook, Lewis Publishers, New York, 1997.

3. W. P. Cunningham, B.W. Saigo, Environmental science: a global concern, 5 Edition, McGraw-Hill, Boston, 1999.

4. G. Miller, G. Tyler, Living in the environment: Principles, connections and solutions., Brooks Cole Publishing Company, Pacific Grove, CA, 2002.

Course title Hybrid sources of energy





[email protected]

Course code (if applicable) WTiICh/IISt/ICh/D7-4b_37 ECTS points 2

Type of course elective Level of course S2

Semester winter Language of instruction English


Classes: 15h


Familiarize students with the basic concepts of integrated ways of using available renewable energy sources.

Entry requirements Mathematics, Physics, Technical Thermodynamics

Course contents

Lecture:Basic definitions of hybrid systems. Integrated ways of using renewable energy sources: water - sun, water - wind, solar - wind, wind - the sun - the water, the integration of hydro and geothermal energy. Classifications and application of hybrid systems: the original source - solar and secondary sources: chemical battery, wind turbines, diesel generator, fuel cells. Hybrid photovoltaic systems. Construction and operation of the fuel cell. Types and performance of fuel cells. Hybrid heating systems: heat pump assisted biomass-fired boilers, solar collectors connected to a conventional heat source, heat recovery units, thermo fireplace with gas or oil boiler. Batteries and power applications. Hydrogen economy. Alternative vehicles - hybrid car with power from the fuel cell, hybrid car with a combustion engine. The efficiency of a fuel cell car. Impact on the environment. Hybrid systems in nuclear power - energy production and processing of radioactive waste. Advantages and disadvantages of hybrid energy sources. Classes:Solutions of problems connected with energy conversion technologies in industrial energy systems. Optimization of industrial energy systems considering future costs associated with greenhouse gas emissions. Overview of energy policy instruments and their impact on industrial energy system decision-making.

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2. D.H.F. Liu, B.G. Liptak, Environmental Engineers’ Handbook, Lewis Publishers, New York, 1997.

3. W. P. Cunningham, B.W. Saigo, Environmental science: a global concern, 5 Edition, McGraw-Hill, Boston, 1999.

4. G. Miller, G. Tyler, Living in the environment: Principles, connections and solutions., Brooks Cole Publishing Company, Pacific Grove, CA, 2002.

Course title Chemical reactors engineering





[email protected]

Course code (if applicable) WTiICh/ISt/ICh/C-19_38 ECTS points 5

Type of course obligatory Level of course S1



Classes: 15h

Objectives of the course Designing chemical process in reactors, use of physicochemical and mathematical knowledge. Rational design and analysis of performance of multiphase reactors.

Entry requirements Mathematics, Chemistry, Physical chemistry, Transfer of momentum, heat and mass

Course contents

Lecture: Chemical kinetics and rate equations mechanism, reaction rate, rate constant, influence of temperature, approximation in kinetics; macrokinetic equation, classification of reactors and choice of reactor type: homogeneous and heterogeneous reactors, batch reactor and continuous reactors, adiabatic and reactors with heat transfer, general material, species and thermal balances, batch reactor: reaction time, isothermal and non-isothermal operation, batch reactor: choice of volume, continuous stirred tank reactors: design equations, residence time, steady –state, tubular reactor: design equations, residence time, steady-state, continuous stirred tank and tubular reactors; heat transfer, ideal reactors; comparison for a single reaction and for multiple reactions, ideal reactors; dynamic characteristic, cascade of reactors; cell model, dispersion model, reactors for complete kinetic model.Classes:Solution of the reaction engineering projects for homogeneous tank and tubular reactors.


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2. D.H.F. Liu, B.G. Liptak Environmental Engineers’ Handbook, LewisPublishers, New York, 1997.

3. R. W. Missen, C. A. Mims, B. A. Saville, Introduction to Chemical Reaction Engineering and Kinetics, Wiley, New York 1999.

Course title Process design





[email protected]

Course code (if applicable) WTiICh/IISt/ICh/C1-1_39 ECTS points 9



Hours per week Lecture: 3hProject: 4h Hours per semester Lecture: 45h

Classes: 60h


Design procedures. Raw materials and processes chemical technology. Solutions of the process line. Selection, design and operation of large – scale industrial apparatus. Economic analysis. Solving of problems in momentum, heat and mass transfer processes. Design of selected apparatus. Balance of materials and energy. CAD for design of chemical processes.

Entry requirements Mathematics, Chemical engineering, Chemical technology

Course contents

Lecture: Procedure of elaboration new technologies; rules of preparing documentation of process design, feasibility study; raw materials and product, process description; selection of processes and operations; selection and calculation procedure of apparatus and installations; balance of materials and energy; technological scheme of an industrial installation; CAD for design of chemical processes; economic analysis of an investment enterprise.Project:Formulation of plant design problem, scope and objectives; construction of flow sheet; plant location selection; construction of process description, process flow diagram, mass and energy balance; selection and sizing of major process equipment; construction materials selection; equipment layout plot plan; construction cost estimation and plant economic analysis; piping and instrumentation diagram; plant design report preparation.

Assessment methods Lecture: class testProject: written report

Recommended readings 1. Himmelblau, Basic principles and calculation in chemical engineering, New York, 1986.2. G.I. Wells, L.M. Rose, The art of chemical process design, Elsevier, 1986.3. W. D. Seider, Process design principles, J.W.& S., 1999.4. J. B. Riggs, An Introduction to Numerical Methods for Chemical Engineers, Texas Tech

University Press, Lubbock, Texas, 1982.5. O. T. Hanna, O.C. Sandal, Computation Methods in Chemical Engineering, Prenti-Hall,

Englewood Cliff, New Jersey, 1997.6. W. D. Baasel, Preliminary Chemical Engineering Plant Design, 2 Edition, van

Nostrand, New York, 1990.7. M. S. Peters, K.D. Timmerhaus, Plant Design and Economics for Chemical Engineers,

38

McGraw-Hill Book Co., Inc., New York, 1991.8. R. K. Sinnott, Coulson-Richardson’s Chemical Engineering, vol. 6, An Introduction to

Chemical Engineering Design, Pergamon Press, Oxford, 1985.

Course title Technical thermodynamics





[email protected]

Course code (if applicable) WTiICh/ISt/ICh/C-6_40 ECTS points 3




Classes: 15h


Acquiring of technical and thermodynamic knowledge needed to study other engineering courses. The base knowledge of heat technique and engineering thermodynamics connected with thermodynamic processes and properties of pure substances and mixtures will be presented and practically tested.


Course contents

Lecture: Definition of system, units, fundamentals of equations of state: ideal gas, virial and cubic equations; First Law of Thermodynamics: energy balance, definition of internal energy, heat, work, enthalpy and heat capacity. Ideal gas energy balance: closed and open system, isothermal, isobaric, isometric and adiabatic processes. Second Law of Thermodynamics: Carnot cycle, entropy, process spontaneity criteria. Entropy change of ideal gases: isothermal, isobaric, isometric, adiabatic and mixing processes. Free energy: Gibbs and Helmholtz, lost work and exergy. Properties of real fluids: calculation of ΔU, ΔH and ΔS using thermodynamic diagrams and tables, introduction to calculations using equations of state. Estimation of density, relation between saturated vapour pressure and boiling point, variables at critical condition. Ideal gas flow systems: expansion, compression and throttling. Thermodynamic cycles: Otto, Diesel, Brayton, Rankine, refrigeration, and liquefaction.Classes:Solutions of problems connected with thermodynamic changes of ideal gases. Problems with equations of state. Determination of thermodynamic properties of pure substances. Problems about solutions. Problems concerning of phase equilibria in multicomponent systems.



1. J.M. Smith, H.C. Van Ness, M.M. Abbott: Introduction to Chemical Engineering Thermodynamics. McGraw Hill, Boston, 2001.

2. J. Gmehling, B. Kolbe: Thermodynamik. Georg Thieme, Stuttgart, 1988.3. D.P. Tassios: Applied Chemical Engineering Thermodynamics. Springer, Berlin, 1993.4. S. I. Sandler, Chemical and Engineering Thermodynamics, 2 Edition, John Wiley&

Sons, New York, 1989.

CHEMICAL TECHNOLOGY

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Course title Analysis of water and effluents

Person responsible for the course Sylwia Mozia, assistant professor


[email protected]

Course code (if applicable) WTiICh/ISt/TCh_1 ECTS points 4



Hours per weekLecture: 2hClasses: 1hLaboratory: 4h

Hours per semesterLecture: 30hClasses: 15hLaboratory: 60h

Teaching method Lecture, classes and laboratory


Chemical composition of natural waters, basic knowledge on water treatment, drinking water quality standards, methods of analysis of waterWastewaters – sources, types and characteristics, basic knowledge on wastewater treatment, wastewater quality standards, methods of analysis of wastewaters

Entry requirements Chemical technology, water and wastewater treatment

Course contents

Lecture:Characteristics of surface water and groundwater. Classification of waters. Regulations concerning drinking water quality. Characteristics of municipal wastewater and selected industrial effluents. Wastewater quality standards. Aims and ranges of water and wastewater analysis.Fundamentals of analysis of water and wastewater. Background of sampling. Sample stabilization and safe keeping. Physical and chemical indicators of water and wastewater contamination. Indicators of bacteriological contamination of water. Methods of analysis of water and wastewater.Laboratory: Determination of PO4

3-, N-NO3-, N-NH4

+ and dissolved oxygen concentrations, determination of COD-Cr, COD-Mn, TOC, alkalinity, acidity, hardness, color, turbidity and pH of water, evaluation of water corrosivity. Classes: Calculation of solutions concentrations, pH, hardness, alkalinity and acidity of natural waters, corrosivity, BOD. Regulations concerning drinking water quality.

Assessment methodsLecture: examClasses: class testLaboratory: class test


1. Handbook of Water Analysis, Second Edition, Ed. Leo M.L. Nollet, CRC Press LLC, USA, 2007.

2. K. Kaur, Handbook of water and wastewater analysis, Atlantic Publishers & Distributors (P) Ltd., 2007.

3. Kirk-Othmer, Chemical Technology and the Environment, Vol. 1 and 2, 20074. Handbook of Environmental Chemistry, ed. O. Hutzinger, Vol.5, part A, Water Pollution,

Springer-Verlag 19915. B.J. Alloway, D.C. Ayres Chemical Principles of Environmental pollution, Blackie Academic

& Professional 19936. Water treatment, Plant Design, 3th Edition, American Water Works Association, McGraw

19987. W.J. Masschelein, Unit Processes in Drinking Water Treatment, Marcel Dekker Inc. 1992

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Course title Characterization methods and properties of polymeric materials

Teaching method lectures and laboratory


Ph.D. Agnieszka Piegat,


[email protected]

Course code (if applicable) TCH_2A_S_D01_09_2 ECTS points 3



Hours per week1 lecture, 1 laboratory

Hours per semester15 lecture, 15 laboratory

Objectives of the courseThis course is aimed at giving knowledge on fundamental methods for characterization polymeric materials

Entry requirements Polymer chemistry, chemical technology, instrumental analysis

Course contents

Lectures: Classification of polymers properties ; microscopic techniques in evaluation of polymers morphology (transmission electron microscopy, scanning electron microscopy, light microscopy); mechanical properties; thermal analysis of polymers (DSC, DMTA, TGA); liquid crystal polymers; influence of different additives on selected properties.

Assessment methods written exam and grade


1. Z. Guo, L. Tan, Fundamentals and Applications of Nanomaterials, Artech House, 20092. David D.J., Misra A., Relating materials properties to structure. Handbook and

software for polymer calculations and materials properties, Technomic Publishing Co., 1999

3. Available research papers and other sources


Course title Chemical processes in inorganic industry and environmental engineering i – separation techniques


Professor Maria Tomaszewska,


[email protected]


WTiICh/IISt/TCh/D12-1_3 ECTS points 4


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Hours per week 1 lecture, 3 laboratory, 2 classes Hours per semester

15 lecture, 45 laboratory, 30 classes

Teaching method lecture, classes and laboratory


Come to know about techniques of membrane separation, methods of membrane preparation, and application of membrane techniques in chemical engineering and biotechnology

Entry requirements Chemical technology, chemical engineering

Course contents

Lectures: Introduction to membrane processes. Definition of a membrane. Membrane processes. Preparation of polymeric and inorganic membranes. Characteristics of membranes. Driving forces of mass transfer. Polarisation phenomena and membrane fouling. Membrane modules and their characteristics. Pressure driven membrane processes – microfiltration, ultrafiltration, nanofiltration, reverse osmosis. Techniques with a concentration difference as a driven force – gas and vapour separation, pervaporation, dialysis, membrane distillation. Electrically driven membrane processes – electrodialysis. Bi-polar membranes. Liquid membranes. Contactors. Membrane reactors and bioreactors. Examples of membrane processes application in chemical engineering and biotechnologyClasses: mass and heat transfer across a membrane, membrane modules, efficiency of membrane modules, fouling and polarisation phenomenaLaboratory: water and wastewater treatment using membrane processes: RO, NF, UF and MD



1. M.Mulder, Basic Principles of Membranes Technology, Kluwer Academic Publishers, 1991

2. N.N.Li, A.G.Fane, W.S.Winston Ho, T.Matsuura, Advanced Membrane Technology and Application, Wiley 2008

3. M.K.Turner, Effective Industrial Membrane Processes: Benefits and Opportunities, Elsevier Applied Science, 1991

4. Handbook of Industrial Membranes, ed. K.Scott, Elsevier Advanced Technology, 1997

Course title Chemical processes in inorganic industry and environmental engineering II

Person responsible for the course Zofia Lendzion-Bieluń PhD


[email protected]

Course code (if applicable) WTiICh/IISt/TCh-D12-7_4 ECTS points 4



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Teaching method lecture

Objectives of the course Come to know about the chemical processes in inorganic industry

Entry requirements Fundamentals of chemical technology, Chemical technology – chemical industry processes

Course contents

Metallurgy. Iron ores, pyrometallurgical process – pig iron obtaining: ores preparation, fluxing agents, introductory deoxidation, direct and indirect reduction processes, pig iron desulfurization, pig iron – composition and types. Steel-making – objectives and stages, steel refining, impurities removal. Hydrometallurgy. Copper ores, flotation, hydrometallurgical process stages, heat pretreatment – objectives and procedures. Extraction – extraction liquor, side reaction, separation of metals from solutions – direct and indirect methods.Building materials. Lime, gypsum, cement, concrete, prefabricated products. Ceramics: ceramic building materials, electroceramics, metal ceramics, ceramic whiteware. Glass and glassware. Different sorts of glass, glass wool, ceramic and glass fibres, frits. Electrolysis, electrolysers, Electrochemical synthesis of sodium hypochlorite, sodium chlorate, potassium chlorate. Electroplating. mechanism, structure of electrolytic coating, surface pretreatment, zinc, copper, nickel, chromium and gold plating.

Assessment methods exam

Course title Chemical reactors


Beata Michalkiewicz, assistant professor


[email protected]

Course code (if applicable) WTiICh/IISt/TCh/C-3_5 ECTS points 3

Type of course compulsory Level of course S2

Semester summer Language of instruction english

Hours per week 1 lecture, 1 laboratory, 1 classes Hours per semester15 lecture, 15 laboratory, 15 classes

Teaching method lecture/laboratory

Objectives of the course chemical reactors design

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Entry requirements Mathematics, Inorganic Chemistry, Physical Chemistry

Course contents

Definition of the reaction rate. Independence of the reactions. Kinetics and thermochemistry of the reactions. Rate of homogenous and heterogeneous reactions. Variables affecting the rate of reaction. Reaction in series and in parallel. Collection and analysis of rate data. Differential and integral method of analysis. Testing kinetic models. Design of continuous stirred tank reactor, tubular flow reactor, batch reactor, packed bed reactor and reactors in series.

Assessment methods written exam


1. H. Scott Fogler, Elements of chemical Reaction Engineering, Pearson Education International, 2006

2. R. Aris, Introduction to the analysis of chemical reactors, Prentice-Hall Inc. 19693. R. Aris, Elementary chemical reactor analysis, Prentice-Hall Inc. 19654. K. R. Westerterp at al. Chemical reactor design and operation, John Wiley & Sons,

1984P.N. Cheremisinoff, L.M. Ferrante, Waste Reduction for Pollution Prevention, Butterworth-Heinemenn Ltd, Linacre House, Jordan Hil, Oxford OX2 8DP, 1992.

5. Publications from the internet site: www.envirowise.gov.uk


Course title Chemical processes in inorganic industry and environmental engineering i – separation techniques


Professor Maria Tomaszewska E-mail address to the person responsible for the course

[email protected]





Hours per week 1 lecture, 3 laboratory, 2 classes Hours per semester 15 lecture, 45 laboratory, 30 classes

Teaching method lecture, classes and laboratory

Objectives of the courseCome to know about techniques of membrane separation, methods of membrane preparation, and application of membrane techniques in chemical engineering and biotechnology


Course contents Lectures: Introduction to membrane processes. Definition of a membrane. Membrane processes. Preparation of polymeric and inorganic membranes. Characteristics of membranes. Driving forces of mass transfer. Polarisation phenomena and membrane fouling. Membrane modules and their characteristics. Pressure driven membrane processes – microfiltration, ultrafiltration, nanofiltration, reverse osmosis. Techniques with a concentration difference as a driven force – gas and vapour separation, pervaporation, dialysis, membrane distillation. Electrically driven membrane processes – electrodialysis. Bi-polar membranes. Liquid

44



membranes. Contactors. Membrane reactors and bioreactors. Examples of membrane processes application in chemical engineering and biotechnologyClasses: mass and heat transfer across a membrane, membrane modules, efficiency of membrane modules, fouling and polarisation phenomenaLaboratory: water and wastewater treatment using membrane processes: RO, NF, UF and MD



1. M.Mulder, Basic Principles of Membranes Technology, Kluwer Academic Publishers, 19912. N.N.Li, A.G.Fane, W.S.Winston Ho, T.Matsuura, Advanced Membrane Technology and

Application, Wiley 20083. M.K.Turner, Effective Industrial Membrane Processes: Benefits and Opportunities, Elsevier

Applied Science, 19914. Handbook of Industrial Membranes, ed. K.Scott, Elsevier Advanced Technology, 1997

Course title Polymer Composite

Teaching method Lecture, Lab


Krzysztof Goracy PhDRyszard Pilawka Ph.D.


[email protected]

Course code (if applicable) WTiICh_TCh_7 ECTS points

Type of course Level of course

Semester Language of instruction English, German

Hours per week 2 Lecture, 2 Lab Hours per semester 60

Objectives of the course Properties of Polymer Composites, Technologies of Manufacturing

Entry requirementsPrinciples of Polymers

Polymer Properties

Course contents

Materials used in Polymer Composites (Fibers and Polymers), Properties of Polymer Composites, Methods of Investigations, Technologies for Manufacturing of Composites. Practical meaning of Composites

Assessment methods Grade,

Recommended readings Ronald F. Gibson – Principles of Composite Material Mechanics


45

Course title Computer-aided design of chemical industrial plants


professor Ryszard J. Kaleńczuk


[email protected]

Course code (if applicable) WTiICh/IISt/TCh/D12-5_8 ECTS points 3



Hours per week 1 lecture, 3 laboratory Hours per semester 15 lecture, 45 laboratory

Teaching method lecture, practice

Objectives of the courseKnowledge of the using of modern computer tools for industrial plant simulation and optimization

Entry requirements

Mathematics I, Mathematics II, Physics, Computer Science, Physical Chemistry I, Physical Chemistry II, Basis of Chemical Engineering I, Basis of Chemical Engineering II, Modelling of chemical processes, Chemical engineering- industrial processes of synthetic chemistry

Course contents

European regulations concerning waste management. Environmental impact assessment. Life Description of the computer program for the modelling and simulation of the chemical process e.g. industrial production of acid. Structure of the program, modes of the program, Presentation of the process simulation basing on the chosen example. Laboratory exercise with the program which simulates the industrial production of the chemical compounds. Modelling of its own industrial process. Optimization of the process parameters to get the highest product yield.


Recommended readings Description of computer programme for processes simulation


Course title Biodegradable Polymers



Professor Miroslawa El Fray,


[email protected]


WTiICh/ISt/TCh/C15a_9 ECTS points 5


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Hours per week2 lectures, 2 laboratory


Objectives of the courseThis course is aimed at giving an introduction to biodegradable polymeric materials, their properties and applications

Entry requirements Polymer chemistry, chemical technology

Course contents

Lectures: Synthetic and natural biodegradable polymers: starch, cellulose, chitin and chitosan, poly(lactic acid) and poly(glycolic acid), aromatic-aliphatic polyesters; monomers and polymer from renewable resources; degradation processes: hydrolytic, enzymatic and oxidative degradation; physical and structural parameters affecting application of biopolymers as drug delivery systemsLaboratory: synthesis of poly(lactic acid), determination of degree of deacetylation of chitosan, degradation of polymers in different media (PBS, SBF)



1. Belgacem M., Gandini A., Monomers, Polymers and Composites from Renewable Resources, Elsevier, Amsterdam 2008

2. Susan E.M. Selke, John D. Culter, and Ruben J. Hernandez, Plastics Packaging: Properties, Processing, Applications, and Regulations, 2nd Ed., Hanser Gardner, 2004

3. Platt D., Biodegradable Polymers, Rapra Technology, Shawbury 2006


Course title Biomaterials

Teaching method Lectures, classes and laboratory


Professor Miroslawa El Fray E-mail address to the person responsible for the course [email protected]


WTiICh/ISt/TCh/D3-2a_10 ECTS points 4



Hours per week2 lectures, 1 class, 1 laboratory

Hours per semester

30 lecture, 15, classes, 15 laboratory

Objectives of the courseThis course is aimed at giving an introduction to polymers used widely in biomedical applications; it will also cover metal and ceramic biomaterials.

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Entry requirements Polymer chemistry, polymer chemistry, biochemistry, polymer and materials endineering

Course contents

Lectures: Polymeric biomaterials: basic concepts of biocompatibility; synthetic polymers and composites as implants; biodegradable polymers for tissue engineering; stimuli responsive polymers for medical applications, including drug delivery; metals and ceramics in biomedical applications; environmental management of biodegradable polymers.Classes: determination of degree of crystallinity, calculation of molecular masses from different methodsLaboratory: extraction of different biomaterials, degradation of polymeric sutures in different media (PBS, SBF), evaluation of thermal and mechanical properties of selected implants


Recommended readings1. Black J., Bilogical Performance of Materials, Marcel Dekker, New York, 19992. Wise D.L., Biomaterials and Bioengineering Handbook, Marcel Dekker, New York, 20003. Ratner B.D., Biomaterials Science, Academic Press, New York 1996


Course title Biochemistry and Biomimetics in Synthesis of Polymers

Teaching method Lectures and laboratory




[email protected]







Objectives of the courseThis course is aimed at giving an introduction to principles of design of synthetic materials by mimicking nature.

Entry requirements Polymer chemistry, polymer chemistry, biochemistry, polymer and materials engineering

Course contents

Lectures: Basic definitions; biological design of biological materials and nano-materials; multifunctional materials; functional surfaces in biology; biological materials in engineering mechanisms; artificial muscles using electroactive polymers; artificial replacement and support of human organs; Laboratory: fabrication of microspheres and microcapsules as natural liposomes; fabrication of polymeric membranes


48


Recommended readings1.Y. Bar-Cohen, Biomimetics Biologically Inspired Technologies, CRC Taylor&Francis, 20062. Wise D.L., Biomaterials and Bioengineering Handbook, Marcel Dekker, New York, 20003. Ratner B.D., Biomaterials Science, Academic Press, New York 1996


Course title Biopolymers and Biomaterials

Teaching method Lectures, classes and laboratory




[email protected]





Hours per week2 lectures

Hours per semester30 lecture


This course is aimed at giving an introduction to natural polymers (biopolymers) and biomaterials used widely in biomedical applications; it will also cover metal and ceramic biomaterials.


Course contents

Lectures: Synthetic and natural biodegradable polymers: starch, cellulose, chitin and chitosan, poly(lactic acid) and poly(glycolic acid), aromatic-aliphatic polyesters; basic concepts of biocompatibility; biodegradable polymers for tissue engineering; stimuli responsive polymers for medical applications; polymeric implants for hard and soft tissue, polymers for cardiac applications; metals and ceramics in biomedical applications.




Course title Characterization methods for bio- and nanomaterials


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[email protected]

Course code (if applicable) Nano_1A_S_C26_13 ECTS points 1





Objectives of the courseThis course is aimed at giving knowledge on fundamental methods for characterization of bio- and nanomaterials

Entry requirements Polymer chemistry, chemical technology, nanotechnology

Course contents

Lectures: Interface phenomena(water contact angle, surface tension, water sorption); microscopic techniques in evaluation of bio- and nanomaterials (confocal microscopy, scanning electron microscopy, light microscopy); roentgen and neutron diffraction in biology and medicine; characterization of micellar structures with dynamic laser diffraction; determination of crystallinity with the use of DSC; evaluation of hydrolytic and enzymatic degradation.



1. T. Broniewski, Metody badan i ocena własciwosci tworzyw sztucznych, WNT, Warszawa, 2001

2. W. Przygocki, A. Włochowicz, Uporzadkowanie makroczasteczek w polimerach i włoknach, WNT, Warszawa, 2006

3. Z. Guo, L. Tan, Fundamentals and Applications of Nanomaterials, Artech House, 20094. Available research papers and other sources


Course title Nanofillers and Nanocomposites





[email protected]

Course code (if applicable) Nano_1A_S_D2_03_14 ECTS points 3



Hours per week 2 lectures, 1 laboratory Hours per semester 30 lecture, 15 laboratory

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Objectives of the courseThis course is aimed at giving an introduction to different nanofillers used for preparation of polymeric nanocomposites

Entry requirements Polymer chemistry, chemical technology, nanotechnology

Course contents

Lectures: Synthetic and application of nanomaterials; creation of nanostructured materials based on chemical reactions; introduction to carbon nanotubes and graphene; aluminosilicates: their structure and properties; other nanoparticles: titana, ceria and silica oxides; dispersions of nanoparticles and their characterization; preparation methods of polymeric nanocomposites; synthesis of nanocomposites via in situ polymerization



1. Kelsall R.W., Hamley I.W., Geoghegan M., Nanotechnologie, PWN, Warszawa, 20082. C. R. Martin, Nanomaterials: A membrane-based synthetic approach, Science 266,

1961–1966, 20083. Available research papers and other sources


Course title Polymer Chemistry





[email protected]

Course code (if applicable) WTiICh_TCh_15 ECTS points 5

Type of course obligatory Level of course S1, S2




Objectives of the course This course is aimed at giving an introduction to polymer chemistry

Entry requirements chemical technology, organic chemistry

Course contents Lectures: Basic definitions in polymer science: monomer, polymer, classification, synthesis methods); molecular weight of polymers and polydispersity index; fundamentals of chain polymerization: initiation, chain growth, inhibition, termination, kinetics; radical polymerization, ionic polymerization; cationic polymerization; step growth polymerizations: polycondensation: kinetics, monomers, molecular weight of polymers and polydispersity index

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of condensation polymers; examples of condensation polymers; polyaddition and examples of polymers; chain polymerization versus step growth polymerization: differences and similarities.Laboratory: synthesis of condensation polymer, synthesis of addition polymer, preparation of polymer via radical polymerization



1. A. Ravve: Principles of Polymer Chemistry, Plenum Press, New York & London, 19952. J. Scheirs, T. E. Long, Modern Polyesters: Chemistry andTechnology of Polyesters and Copolyesters, John Wiley & Sons, Ltd, Chichester 20033. H. R. Kricheldorf, O. Nuyken, G. Swift, Handbook of polymer synthesis, Marcel Dekker, 2005


Course title Biopolymeric Implants and Tissue Engineering

Teaching method Lectures and laboratory




[email protected]







Objectives of the courseThis course is aimed at giving an introduction to polymeric implants and tissue engineering which combines application of materials (polymers) and cells to produce new tissues.


Course contents

Lectures: Basic concepts of biocompatibility; cell-tissue interaction; polymeric implants for hard and soft tissue, polymers for cardiac applications; metals and ceramics in biomedical applications; biodegradable polymers; porous structures: manufacturing and characterization; polymer fibers and nano-fibers; cell cultures and cell differentiation; optimization of bioreactor processes; Laboratory: extraction of different biomaterials, degradation of polymeric sutures in different media (PBS, SBF), evaluation of thermal and mechanical properties of selected implants; fabrication of porous materials as 3-D scaffolds



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4. Lanza R., Langer R., Vacanti J, Principles of Tissue Engineering, Elsevier, Amsterdam 2007 5. Stevens E.S., Green Plastics: An Introduction to the New Science of Biodegradable Plastics, Princeton University Press, 2002.


Course title Electrical engineering

Person responsible for the course Dariusz Moszyński Ph.D.


[email protected]

Course code (if applicable) WTiICh/IISt/TCh_17 ECTS points 3


Semester winter Language of instruction english


Teaching method lecture, laboratory

Objectives of the course Come to know the basic laws of electrical engineering, electrical circuits and appliances

Entry requirements Mathematics, physics

Course contents

Basic concepts of electricity. Ohm’s law. Electrical safety. Series and parallel circuits. Kirchhoff’s law. DC network analysis. Batteries and power systems. Conductors and insulators. Capacitors. Magnetism and electromagnetism. Basic AC Theory. Reactance and impedance. Transformers, Generators, Motors. Polyphase AC circuits. DC and AC metering circuits. Basic semiconductor theory



William H. Roadstrum, Dan H. Wolaver: Electrical engineering for all engineers. Wiley, New York 1987.D.F. Warne: Newnes Electrical Engineer’s Handbook. Newnes, Oxford 2000.


Course title Elements of biotechnology


professor Maria Tomaszewska


[email protected]

Course code (if applicable) WTiICh/IISt/TCh/A-1_18 ECTS points 3

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Semester I Language of instruction English



Objectives of the courseThe course will offer a methods of biotechnology, application of microorganisms and enzymes in bioremediation and technology including examples of real-world applications

Entry requirements Biology (college or higher) taken within the last 5 years.

Course contents

Different approaches to the term of biotechnology. Definition of terms: remediation, bioremediation, phytoremediation. Microorganisms and enzymes used in bioremediation technologies. Microbial remediation of metals. Anaerobic biodegradation in landfill. Techniques and biochemistry of fermentation. Production of microbial biomass. Biosynthesis of lactic, citric, gluconic, itaconic, malic, butyric, propionic, tartaric acids. An introduction to biocatalysis. Kinetics and characteristics of enzymes. Biohydrometalurgy.

Assessment methods Written exam


1. Alexander M., Biodegradation and Bioremediation (2nd edition), Academic Press, Cornell University, Ithaca, New York, 1999.

2. Evans G. M., Furlong J. C., Environmental Biotechnology : Theory and Application, Wiley, New York, 2003.

3. Vogel H. C., Todaro C. L., Fermentation and Biochemical Engineering Handbook: Principles, Process Design, and Equipment (2nd edition), William Andrew Pub, New York, 1996.

4. Additional/optional5. Ratledge C., Kristiansen B., Basic Biotechnology (2nd edition), Cambridge University Press,

Cambridge, 2006.6. Volmar B., Götz F., Microbial Fundamentals of Biotechnology, Wiley-VCH , New York,

2001.

Course title Faserverbund Kunststoffe

Teaching method Vorlesung, Praktika




[email protected]



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Semester Winter oder sommer Language of instruction Deutsch

Hours per week 2 Vorlesung, 2 Praktika Hours per semester 60

Objectives of the course Eigenschaften der Faserverbund Kunststoffe, Verarbeiten von Verbunden

Entry requirementsGrundlagen der Polymere

Polymereigenschaften

Course contentsVerstärkung Materialien und Kunststoffmatrix, Eigenschaften von Kompositen, Prüfungs- Methoden, Verarbeiten von Faserverbunden, Praktische Anwendung von Faserverbunden

Assessment methods schriftlich

Recommended readings G.W. Ehrenstein – Faserverbund Kunststoffe


Course title (nazwa przedmiotu) Fundamentals of chemical process calculations

Teaching method lecture, classes


Grzegorz Lewandowski


[email protected]




Hours per weekLecture: 1hClasses: 1h Hours per semester

Lecture: 15hClasses: 15h

Objectives of the course Provide a basic framework for formulate and solve material and energy balances for various operations and processes.

Entry requirements The fundamental course of organic chemistry, chemical technology and organic technology

Course contents

Lecture: Stoichiometry, conversion, yield, and selectivity Concepts of material and energy balances. Material and energy balances without chemical reactions. Material and energy balances with chemical reactions. Classes: Develop and practice of material and energy balances for various operations and processes.

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Assessment methods Lecture: written examClasses: class test


T.G. Hicks, P.E., N.P. Chopey, Handbook of Chemical Engineering Calculations, 4th ed., The McGraw-Hill Companies, Inc., 2012R.M. Felder, R.W. Rousseau, Elementary Principles of Chemical Processes, 3rd Edition, Wiley, 1999KIRK-OTHMER Encyclopedia of Chemical Technology, 5th ed., John Wiley & Sons, 2004S.F. Fogler, Elements of Chemical Reaction Engineering, 4th Edition, Pearson Education, 2006

Course title Fundamentals of inorganic chemicals commodity science


Krzysztof Lubkowski PhD E-mail address to the person responsible for the course

[email protected]






Objectives of the course Come to know about the inorganic chemicals commodity science

Entry requirements

Bases of economy, management and marketing, Management of quality and chemical products, Production management, Unit processes in chemical technology, Chemical technology – raw materials, Chemical technology – chemical industry processes, Nitrogen industry, Mineral fertilizers.

Course contents

Basic concepts in commodity science. Characteristics of raw materials and products of inorganic chemistry with regard to their physicochemical and commercial properties, obtaining and processing technology. Quality evaluation of raw materials and inorganic products in terms of their compliance with the law. Standards and laws governing the quality of inorganic products and their designation. Packing and its influence on the quality of inorganic products. Storage and transport conditions of inorganic products. Inorganic product market.


Recommended readings 1. Hocking M.B., Modern Chemical Technology and Emission Control, Springer-Verlag, Berlin 1985.

2. Budde F., Farha G.A., Frankemolle H., Value Creation: Strategies for the Chemical Industry, Wiley-VCH, New York 2001.

3. The Chemical Industry at the Millennium: Maturity, Restructuring, and Globalization , Peter H. Spitz (ed.), Chemical Heritage Foundation, New York 2003.

4. Industrial Minerals & Rocks: Commodities, Markets, and Uses, J.E. Kogel, N.C. Trivedi, J.M. Barker, S.T. Krukowski (Eds), Society of Mining Metallurgy and Exploration, New York 2006.

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http://www.amazon.com/exec/obidos/search-handle-url/102-5380050-2103348?_encoding=UTF8&search-type=ss&index=books&field-author=Stanley%20T.%20Krukowsk

http://www.amazon.com/exec/obidos/search-handle-url/102-5380050-2103348?_encoding=UTF8&search-type=ss&index=books&field-author=James%20M.%20Barker

http://www.amazon.com/exec/obidos/search-handle-url/102-5380050-2103348?_encoding=UTF8&search-type=ss&index=books&field-author=James%20M.%20Barker

http://www.amazon.com/exec/obidos/search-handle-url/102-5380050-2103348?_encoding=UTF8&search-type=ss&index=books&field-author=Nikhil%20C.%20Trivedi

http://www.amazon.com/exec/obidos/search-handle-url/102-5380050-2103348?_encoding=UTF8&search-type=ss&index=books&field-author=Jessica%20Elzea%20Kogel

5. Feingenbaum A.V., Total Quality Control – Engineering and Management, Mc Graw-Hill Book, New York 1961.


Course title Heterogeneous catalysis



[email protected]






Objectives of the course Come to know the catalytic action of solids, physicochemical background of these processes and their applications in chemical industry

Entry requirements Inorganic and organic chemistry, Physical chemistry, Physical chemistry of surfaces

Course contents

Catalyst and catalysis in heterogeneous systems. Catalytic action. Catalyst preparation, deactivation, regeneration. The experimental methods for catalysts’ examination. Most frequently used catalytic materials. Industrial catalytic processes in inorganic, organic and polymer industries.


Recommended readingsG.A. Somorjai: Introduction to surface chemistry and catalysis. Wiley, New York 1994.

Catalysis: an integrated approach. Elsevier, Amsterdam 2000.Encyclopedia of catalysis. Wiley, Hoboken 2003.


Course title Industrial chemistry


Krzysztof Lubkowski PhD, Institute of Chemical and Environment Engineering


[email protected]


Type of course optional Level of course S1

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Semester winter/summer Language of instruction English



Objectives of the course Come to know about the production methods of industrial chemicals

Entry requirements Unit processes and operations in chemical technology, Chemical technology – raw materials, Chemical engineering.

Course contents

Natural and derived sodium and potassium salt, industrial bases (calcium and sodium carbonate, calcium oxide), sulfur and sulfuric acid, phosphorus and phosphoric acid, ammonia, nitric acid, mineral fertilizers, glass, construction materials – lime, cement, gypsum, pigments, aluminium and its compounds.



1. Büchner W., Schliebs R., Winter G., Büchel K.H., Industrial Inorganic Chemistry, VCH, Weinheim 1989.

2. White H.L., Introduction to Industrial Chemistry, John Wiley and Sons, New York 1986.3. Hocking M.B., Modern Chemical Technology and Emission Control, Springer-Verlag, Berlin

1985.4. The Chemical Industry, Edited by C.A. Heaton, Blackie, London 1982.5. R. Norris Shrere, J.A. Brink, Chemical Process Industries, McGraw-Hill Book Company, New

York 1977.6. Riegel’s Handbook of Industrial Chemistry, 7th edition, Edited by James K. Kent, Van

Nostrand Reinhold Company, New York 1974.7. K.K. Kobe, Inorganic Process Industries, The Macmillan Company, New York 1948.


Course title IT technologies for chemical applications


Rafał J. Wróbel, assistant professor


[email protected]




Hours per week 1 lecture Hours per semester 15


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Ability of solving physical and chemical problems by numerical methods. Ability of publishing data in web. Ability of creation of online tools for chemical applications.

Entry requirements Basics of Mathematics, Physics, Chemistry

Course contentsShort introduction to MS Windows system and file managers. Numerical methods in MS Excel. Basic of programming in c++, js, python for solving physical and chemical problems. Basics of html, css and php MySQL for web applications.



6. http://www.delawarepersonnel.com/training/documents/adv_excel_handbook.pdf 7. http://html.net/8. www.php.net/tut.php


Course title Technology of Pressure-Sensitive Adhesives

Person responsible for the course Prof. dr Zbigniew Czech


[email protected]

Course code (if applicable) WTiICh/IISt/ITChO/D10_25 ECTS points 2




Teaching method Lecture

Objectives of the course Research, development and application of self-adhesive materials based on PSA technology

Entry requirementsFundamentals of PSA technology, characterization of self-adhesive materials

Course contentsIntroduction into new techniques for manufacturing of PSA and self-adhesive materials. Development on the area of crosslinking agents. PSA modification and application of UV technology.


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1. Developments in Pressure-Sensitive Products”, Edited by Istvan Benedek, Taylor & Francis a CRC Press Book (2006)

2. Pressure-Sensitive Design, Theoretical Aspects", Vol. 1, I. Benedek, VSP Leiden Boston (2006).


Course title Physical Chemistry of Polymers

Teaching method Lab


Beata Schmidt PhDKatarzyna Wilpiszewska Ph.D.


[email protected]


Type of course compulsory Level of course

Semester Language of instruction English

Hours per week 1h Lab Hours per semester 15

Objectives of the course Come to know about the fundamental knowledge about physical chemistry of polymers.

Entry requirements Polymer Properties, Fundamentals of Polymer Chemistry

Course contentsMeasurement of average molecular weight by capillary viscosimetric and gel permeation chromatography method; the reo-viscosity of polymers.

Assessment methods Grade

Recommended readings Fundamental of Polymer Chemistry,Physical Chemistry of Polymers


Course title Paints and adhesives technology

Teaching method lecture, classes and lab classes


Ph.D. Krzysztof Kowalczyk,


[email protected]

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Objectives of the courseTo gain the knowledge about technology and application of organic varnishes (decorative, protective) paints as well as adhesives


Course contents

Lectures: Definitions of a varnish, paint, adhesive, binder, film forming substance, pigment, filler, solvent, diluent. Characterization of the most popular binders, fillers, pigments (decorative, anticorrosive), solvents, additives. Preparation of solventless, solventborne, powder as well as waterborne coating compositions. Preparation of liquid and solid adhesives. Application of coating compositions. Testing methods of liquid and dry/cured coating compositions. Testing methods of adhesives and joints. Classes: Determination of glass transition temperature of acrylic film forming copolymers, Pigment Volume Concentration (PVC) and Critical Pigment Volume Concentration (CPVC), parameterLab classes: Preparation of 1K and 2K coating compositions, testing of coating compositions and adhesives.



1. Z. Wicks, F. Jones: Organic, John Wiley&Sons, Hoboken 2007;2. M. Xanthos: Functional fillers for plastics, Wiley-VCH, Weinheim 2005;3. J. Bieleman: Additives for coatings, Wiley-VCH, Weinheim 2000;4. J. Koleske: Paint and coating testing manual, ASTM, Philadelphia, 1995.


Course title Biodegradable polymers

Teaching method Lecture and laboratory classes


Ph.D. Katarzyna Wilpiszewska,


[email protected]


Type of course facultative Level of course S2



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Objectives of the courseTo gain the knowledge on biodegradable polymer: natural and biotechnological polymers, their structure, properties, modification and application.

Entry requirements Chemical technology, organic chemistry

Course contents

Lectures: - Definition of biodegradability and methods of its determination.- The most important groups of biopolymers: polysaccharides (cellulose, starch,

chitosan, alginates), proteins, and latex – structure, properties, modification, and application (including nanostructures). Polymers prepared via biochemical synthesis – properties, and application.

Lab classes: Modification of polysaccharides (i.e. starch, cellulose) and using titration as well as spectrometric methods for polysaccharide characterisation, thermal properties of biopolymers, biopolymers as fillers. Applying biopolymers (microcapsules, paper glues, flocculants, etc).

Assessment methods Written examination, an laboratory exams


1. M. Stevens, Polymer chemistry, 1999, Oxford University Press2. C. Bastioli (Ed.), Handbook of biodegradable polymers, 2005, Rapra Technology Ltd.3. R. Smith, Biodegradable polymers for industrial applications, 2005, Woodhead

Publishing Ltd.


Course title Measurements and automation



[email protected]



Semester I Language of instruction english



Objectives of the course Come to know the theory of metrology, the techniques of measurement and regulation

Entry requirements Mathematics, physics, electrical engineering, analytical chemistry

Course contentsThe basics of metrology, techniques of measurements: mass, temperature, pressure, flow, electrical properties, chemical composition of gas mixtures. Theory of regulation. Regulators, actuators. The techniques of regulation: temperature, pressure, flow.

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D.M. Anthony: Engineering metrology. Pergamon, Oxford 1986. James Ronald Leigh: Temperature measurement and control. P.Peregrinus, London 1988.


Course title Nanoparticles and environment

Person responsible for the course Beata Tryba, university professor


[email protected]

Course code (if applicable) WTiICh/IISt/TCh/D10_30 ECTS points 2

Type of course Compulsory Level of course S2

Semester Winter Language of instruction english



Objectives of the courseCome to know about the influence of nanotechnology and nanoparticles on the human life and environment; regulations about management of the nanomaterials; risk assesment of the nanoparticles effect on the human body

Entry requirementsFundamentals of nanotechnology, Characterization techniques of nanomaterials.

Course contents

Introduction to nanotechnology and nanoparticles. Characteristics of nanoparticles in the environment. Risk assesment of the nanoparticles effect on the human body and environment – regulations, law, ethics. Assesment of nanoparticles toxicology - in vitro and in vivo as well as simulation computer methods - QSAR.



1. J.C. Miller, R. Serrato, J. M. Represas-Cardenas, G. Kundahl “The Handbook of Nanotechnology, Business, Policy, and Intellectual property Law”, John Wiley & Sons, Inc.

2. G. Hunt, M. Mehta, „Nanotechnology, Risk, Ethics and Law”.3. Ecotoxicology, 17(1-8) (2008), Springer


Course title Nanotechnology and crystalline nanomaterials


Ewa Borowiak-Paleń, assistant professor

E-mail address to the person responsible for

[email protected]

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the course



Semester summer Language of instruction english



Objectives of the course Come to know about the fundamental knowledge about nanotechnology and nanosize effect in nanocrystalline materials

Entry requirementsFundamentals of chemical engineering, Characterization techniques of materials.

Course contents

Introduction to nanotechnology. Morphology of different carbon nanostructures and crystalline nanomaterials. Preperation techniques of nano—sized materials. Size effect in properties of materials. Characterization of nanomaterials. Examples of application of nanomaterials in industry

Assessment methods oral exam


1. M.D. Ventra, S. Evoy, J.R. Heflin, “Introduction to nanoscale science and technology”, Springer 2004.

2. W.A. Goddard, D.W. Brenner, S.E. Lyshevski, G. J. Lafrate, „Handbook of nanoscience, engineering and technology”, CRC Press LLC 2003.


Course title Physical chemistry of surfaces



[email protected]



Semester I Language of instruction english


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Objectives of the course Come to know the processes taking place on the surface of solids, the mechanisms and laws ruling them

Entry requirements Inorganic and organic chemistry, Physical chemistry

Course contents

Materials of developed surface. Surfaces and interfaces. The techniques of surface science. Electrical, mechanical and optical properties of surfaces. Thermodynamics on surfaces. Surface phenomena. Sorption processes. Adsorption and desorption. Lubrication, wetting, adhesion. Macromolecular surface films. Chemical reactions on surfaces. Solid – gas reactions. Oxidation, passivation and structure of thin films.



1. G.A. Somorjai: Introduction to surface chemistry and catalysis. Wiley, New York 1994.

2. John C. Vickerman, Ian S. Gilmore: Surface analysis: the principal techniques. Wiley, New York 2009.


Course title (nazwa przedmiotu) Power engineering in chemical industry

Person responsible for the course Marek Gryta, assistant professor


[email protected]






Objectives of the course The energy sources used in chemical industry

Entry requirements Chemical technology, Unit operations in chemical engineering and water technology

Course contents Characteristics of basic methods of energy transfer. Characterisation of the types of energy used in chemical industry. Natural resources of raw materials used by chemical industry. Power demand of the major unit operation. Principles of management of heat and cold in the production processes. Heat transfer medium in chemical industry: low and high pressure steam, organic liquids, silicone oils, air, water, brines. Methods of heat generation. Fuel combustion. Electric and exhaust gas heating. Water for steam boilers and coolant circuit. Solid and liquid wastes, pollution emission. Cooling. Cooling tower and others methods of cold production. Heat

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exchangers. Heat of reactions. Heat exchange in an exemplary technological process. Search for new sources of energy. Non-conventional sources of energy.



1. Porritt J., Energy and the environmental, Oxford University Press, Oxford 19932. Barid C., Environmental chemistry, Freeman and Company, New York 19983. Powell S.T., Water conditioning for industry, McGraw-Hill, New York, 19544. Heaton C.A., Industrial Chemistry, Blackie and Sons, Glasgow 19915. L. Anderson. D.T. Uman, Fuels from wastes, London, 19776. Additional/optional7. KIRK-OTHMER Encyclopedia of Chemical Technology, 5th ed., John Wiley & Sons, 20048. K. Scott, Handbook of industrial membranes, Elsevier, Kidlington (UK) 19979. D.L. Wise, D. Trantdo, Process engineering for pollution control and waste minimization,

Marcel Dekker, New York 199410. N.I. Sax, Industrial Pollution, VNR, Melbourne, 197411. Block H.P., Practical lubricantion for industrial facilities, Marcel Dekker, New York 200012. L.D. Smoot, P.J. Smith, Coal combustion and gasification, Plenum Press, London 1985

Course title Quality and risk management in chemical industry

Person responsible for the course Krzysztof Karakulski PhD


[email protected]


Type of course Obligatory/optional Level of course S2




Objectives of the course Presentation of procedures of product control in chemical industry in compliance with ISO standards and general hazards resulting from utilization of installation in chemical industry

Entry requirements Chemical technology, Unit operations in chemical technology, ISO standards, European regulations on industrial safety

Course contents

European regulations concerning quality management according to ISO standards. Techniques of products control. Systems of environment management and industry safety. Operation with dangerous liquids, internal transport, electric energy versus industrial safety. Problems of ventilation. Storage and transport of chemicals and dangerous substances. Protection of machines and devices, explosive limits of gaseous mixtures, evaluation of fire hazard of constructional materials, self-igniting substances. Case studies – examples from industry.


Recommended readings1. R.L. Hoover, R.L. Hancock, Health, Safety and Environment Control, Van Nostrand,

New York, 1989. 2. N.I. Sax, Dangerous Properties of Industrial Materials, 7 th ed., Van Nostrand, New

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York, 1989. 3. L.N. Moses, D. Lindstrom, Transportation of Hazardous Materials, Kluwer Academic

Publishers, Boston, 1993.4. Publications from the internet site: www.envirowise.gov.uk


Course title Separation techniques


Professor Maria Tomaszewicz


maria.tomaszewska@zu t.edu. pl






Hours per semester 30 lecture, 45 laboratory

Teaching method lecture and laboratory

Objectives of the courseCome to know about techniques of membrane separation, methods of membrane preparation, and application of membrane techniques in chemical engineering and biotechnology


Course contents

Lectures: Introduction to membrane processes. Definition of a membrane. Membrane processes. Preparation of polymeric and inorganic membranes. Characteristics of membranes. Driving forces of mass transfer. Polarisation phenomena and membrane fouling. Membrane modules and their characteristics. Pressure driven membrane processes – microfiltration, ultrafiltration, nanofiltration, reverse osmosis. Techniques with a concentration difference as a driven force – gas and vapour separation, pervaporation, dialysis, membrane distillation. Electrically driven membrane processes – electrodialysis. Bi-polar membranes. Liquid membranes. Contactors. Membrane reactors and bioreactors. Examples of membrane processes application in chemical engineering and biotechnologyLaboratory: water and wastewater treatment using membrane processes: RO, NF, UF and MD



5. M.Mulder, Basic Principles of Membranes Technology, Kluwer Academic Publishers, 19916. N.N.Li, A.G.Fane, W.S.Winston Ho, T.Matsuura, Advanced Membrane Technology and

Application, Wiley 20087. M.K.Turner, Effective Industrial Membrane Processes: Benefits and Opportunities, Elsevier

Applied Science, 19918. Handbook of Industrial Membranes, ed. K.Scott, Elsevier Advanced Technology, 1997

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Course title Small scale products in inorganic industry


Krzysztof Lubkowski PhD E-mail address to the person responsible for the course

[email protected]






Objectives of the course Come to know about the production methods of small scale inorganic chemicals

Entry requirements Unit processes and operations in chemical technology, Chemical technology – raw materials, Chemical technology – chemical industry processes, Chemical engineering.

Course contents Inorganic pigments, sorbents, fillers, coagulants, silicon emulsions, silicon pastes, inorganic phosphorous compounds - characteristics, properties, methods of production, application.



1. Hocking M.B., Modern Chemical Technology and Emission Control, Springer-Verlag, Berlin 1985.

2. The Chemistry of synthetic dyes and pigments, H.E. Lubs (ed), Reinhold, New York 1955. 3. Pigment Handbook, P.A. Lewis (ed.), John Wiley & Sons, New York 1988.4. Winkler, J., Titanium Dioxide, Vincentz Network, Hannover, 2003.5. Industrial Inorganic Pigments, G. Buxbaum, G. Pfaff (eds.), Wiley-VCH, Weinheim 2005.6. High performance pigments, H.M. Smith (ed), Wiley-VCH, Weinheim 2001.7. Wypych G., Handbook of Fillers, The Definitive User's Guide and Databook of Properties,

Effects and Uses, Plastics Design Library, 1998.8. Jancar J., Mineral fillers in thermoplastics: raw materials and processing, Springer-Verlag,

Berlin - Heidelberg 1999.9. Corbridge D.E.C., Phosphorus: an outline of its chemistry, biochemistry and technology,

Elsevier Scientific Publ. Co., Amsterdam 1978.10. Yang R.T., Adsorbents: fundamentals and applications, John Wiley and Sons,

Hoboken, 2003.


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Course title Surface phenomena and industrial catalytic processes


Rafał J. Wróbel, assistant professor


[email protected]

Course code (if applicable) WTiICh/IISt/TCh/C01_37 ECTS points 3



Hours per week 1 lecture, 2 laboratory, 1 classes Hours per semester15 lecture, 30 laboratory, 15 classes

Teaching method lecture/laboratory


Understanding of the catalytic processes and surface methods required for investigation of catalytic phenomena

Entry requirements Mathematics, Physics, Inorganic Chemistry, Physical Chemistry

Course contentsIntroduction to surface phenomena. Elementary steps in heterogeneous reactions. Surface reactions. Structure and production of catalysts. Industrial application of catalysts. Basics of XPS, AES, MS, EDX, SEM, TEM, STM, AFM, FIM, FEM etc. techniques.



1. Handbook of heterogeneous Catalysis, John Wiley and Sons, 2014, ISBN: 9783527610044

2. J. C. Riviere, S. Myhra, Handbook of Surface and Interface Analysis, CRC Press, 2009


Course title (nazwa przedmiotu) Surfactant chemistry and technology

Teaching method Lecture, laboratory


Ewa Janus, PhD E-mail address to the person responsible for the course

[email protected]



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Hours per week L: 2hLab: 3h Hours per semester L: 30h

Lab: 45h

Objectives of the course This course provides an overview of surfactant properties, their interaction with substrates and selected application technologies.

Entry requirements Organic chemistry

Course contents

L: structure of surfactants; physical properties of surfactants and their solutions – solubility, Krafft point, cloud point, adsorption at interfacial surface, interfacial tension; colloids with surfactants - micelles, emulsions and microemulsions, liquid crystals; effects delivered by surfactants - including wetting, foaming, detergency, emulsification, solubilization; the application of surfactants – an overview including cleaning, personal care, paints and coatings, crop protection, rheology modification.Lab: determination of physicochemical properties of surfactants and their solutions - Krafft point, cloud point, interfacial tension, critical micelle concentration. Emulsion formation - the choice of emulsifier.

Assessment methods written exam, project work


1. Richard J. Farn, Chemistry and Technology of Surfactants, John Wiley & Sons, 20082. I.D. Morrison, S. Ross, Colloidal dispersions, Suspensions, Emulsions and Foams, Willey-Interscience, New York, 2002.3. H. Mollet, A. Grubenmann, Formulation Technology. Emulsions, suspensions, solid forms, Wiley-VCH, Weinheim, 2001.

Course title (nazwa przedmiotu) Technological project

Person responsible for the course Marek Gryta


[email protected]




Hours per week 2 Hours per semester Liczba godzin przedmiotu w semestrze


Objectives of the course Design the structure of chemical technology processes

Entry requirements Chemical technology, Unit operations in chemical engineering

Course contents The students accomplish the technological project concerning a given subject: a description of

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technological concept, a block diagram of assumed manner of its realization, selection and description of used raw materials, characteristic of obtained products, description of wastes and a proposal of their management, flow diagram with description of control measurement instruments, fundamental project calculations, mass balance calculations and Sankey’s diagram



Obligatory C.A. Heaton, Industrial Chemistry, Blackie and Sons, Glasgow 1991 Lees’ Loss Prevention in the Process Industries, Vol.1-3 (3rd Ed.)ed. By Mannau S.,

Elsevier 2005 D.L. Wise, D. Trantdo, Process engineering for pollution control and waste

minimization, Marcel Dekker, New York 1994Additional/optional

CRC Handbook of Chemistry and Physics, 87 th ed., 2006-2007, Taylor & Francis 2006 KIRK-OTHMER Encyclopedia of Chemical Technology, 5th ed., John Wiley & Sons, 2004 Hewitt G.F., Handbook of Heat Exchanger Design, Hemisphere Pub., Washington DC

1990

Course title Technological project II

Teaching method Project

Person responsible for the course Magdalena Urbala


[email protected]

Course code (if applicable) TCH_2A_S_D02_01_40 ECTS points 2.0




Objectives of the courseThe student after finished the course should possess fundamental knowledge to design the technological project of selected organic product.

Entry requirements The fundamental course of organic chemistry, chemical technology and organic technology

Course contents

This course introduces students to the technological project of selected technology of organic products with description of technologies of chosen product, characteristic of the physic-chemical propriety of all reagents, calculations of material and energy balances, Sankey’s diagrams – material and energy balances visualization, description of wastes and a proposal of their management.

Assessment methods Project work

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Jess, P. Wasserscheid, Chemical Technology: An Integral Textbook Wiley-VCH, 2012 T.G. Hicks, P.E., N.P. Chopey, Handbook of Chemical Engineering Calculations, 4th ed., The McGraw-Hill Companies, Inc., 2012KIRK-OTHMER Encyclopedia of Chemical Technology, 5th ed., John Wiley & Sons, 2004


Course title Technologies for waste and pollutants minimization in chemical industry



Joanna Grzechulska – Damszel PhD


[email protected]



Semester Winter Language of instruction English


Objectives of the course Come to know about the legal regulations and technologies concerning waste and pollutants minimization in chemical industry

Entry requirements Chemical technology, Unit operations in water and wastewater treatment, Technology of water and wastewater

Course contentsEuropean regulations concerning waste management. Environmental impact assessment. Life cycle analysis. Responsible Care Program. The concept of cleaner production. Techniques of waste and pollutants minimization. Case studies – examples from industry.



Obligatory1. N. P. Cheremisinoff, Handbook of Solid Waste Management and Waste

Minimization Technologies, Elsevier, 2003.2. Crittenden, S. Kolaczkowski, Waste minimization guide, Institute of Chemical

Engineers, UK, 1995.3. Process engineering for pollution control and waste minimization / edited by

Donald L. Wise, Debra J. Trantolo, Marcel Dekker, New York, 1994.Additional/optional

P.N. Cheremisinoff, L.M. Ferrante, Waste Reduction for Pollution Prevention, Butterworth-Heinemenn Ltd, Linacre House, Jordan Hil, Oxford OX2 8DP, 1992.

Publications from the internet site: www.envirowise.gov.uk


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Course title Testing methods of inorganic products



[email protected]



Semester Winter Language of instruction english

Hours per week 3 lecture, 4 laboratory Hours per semester 45 lecture, 60 laboratory


Objectives of the course Come to know the theory and techniques of instrumental methods for materials characterization

Entry requirements Inorganic chemistry, Physical chemistry, Physics

Course contents

Instrumental methods of chemical composition analysis. Selecting of a proper analytical methods. Theoretical basics of atomic spectroscopy. Inductively Coupled Plasma, ICP. Atomic absorption spectroscopy, AAS. Molecular spectra method. Infrared Spectroscopy, IR, Raman Spectroscopy RS. X-ray methods. X-Ray Fluorescence, XRF. X-Ray Microanalysis).Chemical analysis of the surface of solid state. Physicochemical basics of Electro-spectroscopy methods. Methods: Electron Spectroscopy for Chemical Analysis, ESCA, including X-ray Photoelectron Spectroscopy, XPS, and Ultraviolet Photoemission Spectroscopy, UPS; Auger Electron Spectroscopy, AES, Electron Energy Loss Spectroscopy.Adsorption/desorption methods and temperature programmed techniques. Thermogravimetry, TG, Temperature Programmed Desorption, TPD, Temperature Programmed Oxidation, TPO, Temperature Programmed Reduction, TPR, Temperature Programmed Surface Reaction, TPSR. Mass spectrometry. Analysis of phase composition, structure and topography. X-Ray Diffraction, XRD, Reflection High Energy Electron Diffraction, RHEED, Low Energy Electron Diffraction, LEED. Mössbauer Spectroscopy. Scanning Electron Microscopy, SEM, and Transmission Electron Microscopy, TEM, Atomic Force Microscopy, AFM.


Recommended readingsJohn A. Dean, Analytical Chemistry Handbook, McGraw-Hill Companies, 2000Helmut Günzler, Alex Williams, Handbook of Analytical Techniques, Wiley-VCH, 2001.

Course title The selected technologies of organic industry


Agnieszka Wróblewska, assistant professor


[email protected]

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Semester Summer Language of instruction english



Objectives of the course Come to know about the newest methods production in organic industry.

Entry requirementsFundamentals of organic chemistry. Mechanisms of reactions. Fundamentals of chemical technology. Fundamentals of chemical engineering.

Course contents

Introduction to the newest processes of the organic industry. The division of the contemporary organic industry. The characteristic of the chosen kinds of the production. The catalysts in the newest organic processes (homogeneous and heterogeneous). Zeolites in organic processes. The contemporary methods of production: drugs, vitamins, flavor compounds and surface active compounds.



1. Moulijn J.A., Makkee M., A. van Diepen, Chemical Process Technolgy, John Wiley & Sons Ltd, Chichester, 2001.

2. Mills P.L., Chaudhari R.V., Multiphase catalytic reactor engineering and design for pharmaceuticals and fine chemicals, Catal. Today 37, 367-404, 1997.

3. Sheldon R.A., Selective catalytic synthesis of fine chemicals: opportunities and trends, J. Mol. Catal. A: Chemical 107, 75-83., 1996.

4. Blaser H.-U., Studer M., The role of catalysis for the clean production of fine chemicals, Appl. Catal. A: General 189, 191-204, 1999.

5. Ertl G., Knozinger H., Wietkamp J., Handbook of Heterogeneous Catalysis, Wiley Company, Weinheim, 1997, Vol. 1-5.

6. Wittcoff H.A., Reuben B.G.,, Industrial Organic Chemicals, Wiley & Sons Inc., Chichester, 1996.

7. Weitkamp J., Puppe L., Catalysis and zeolites. Fundamentals and Applications, Springer, 1999.

8. Xu R., Pang W., Yu J., Hou Q., Chen J.,, Chemistry of zeolites and related porous materials, John Wiley & Sons Ltd., Singapore, 2007.

Course title Thermische Analyse von Kunststoffen

Teaching method Vorlesung, Praktika




[email protected]

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Semester Winter oder sommer Language of instruction Deutsch

Hours per week 2 Vorlesung, 2 Praktika Hours per semester 60

Objectives of the course Ziel der Thermischen Analyse, Geräte, Praxis der Thermischen Analyse

Entry requirementsGrundlagen der Kunststoffen

Kunststoffeigenschaften

Course contentsMethoden der thermischen Analyse, physikalische Grundlagen der thermischen Analyse, Geräte Bedienung. Praktische Auswertung der Ergebnisse

Assessment methods schriftlich

Recommended readingsG.W Ehrenstein, G. Riedel, P. Trawiel; Praxis der Thermischen Analyse von Kunststoffen


Course title Bioenergetic Technology


Eugeniusz Milchert, Prof.Robert Pełech, Ph.D.Marcin Bartkowiak, Ph.D.


[email protected]

Course code (if applicable) WTiICh/IISt/TCh/C-3_45 ECTS points 3


Semester Summer Language of instruction English

Hours per week 1 lecture, 1 classes Hours per semester 15 lecture, 15 classes

Teaching method lecture/classes

Objectives of the course bioenergetic technology design

Entry requirements Mathematics, Chemistry, Physical Chemistry

Course contents Definition of the biofuels. Low emmision sources of energy. Renewable energy sources. Fundamentals of biofuels chemistry. Higher and Lower Calorific Value calculations. CO2 emission

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calculations. Combustion gas composition. Heat and power demand and fuel requirements calculations.



Dimian, C. Bildea, Chemical process design. Wiley-WCH, Weinheim 2008. K. Sundmacher, A. Kienle, A. Seidel-Morgensstern, Integrated chemical processes:

Synthesis, Operation, Analysis, and Control. Willey-VCH, Weinheim, 2005. V. Smil, Energy in Nature and Society: General Energetics of Complex Systems. The

MIT Press, Massachusetts 2008. W. Kemp, Biodiesel Basics and Beyond: A Comprehensive Guide to Production and Use

for the Home and Farm. Aztext Press, Ontario 2006. Drapcho, J. Nghiem, T. Walker, Biofuels Engineering Process Technology. The McGraw

Hill 2008. Hodge, Alternative Energy Systems and Applications. Wiley 2010. A Wellinger, J. Patrick Murphy, D. Baxter The Biogas Handbook: Science, Production

And Applications. Woodhead Publishing 2013.


Course title Analysis of air pollution

Person responsible for the course Elżbieta Huzar, PhD


[email protected]

Course code (if applicable) WTiICh/IISt/OSr/C-7_55 ECTS points 4


Semester Summer or winter Language of instruction English

Hours per week 5 Hours per semester 75 (15 lecture, 60 laboratory)

Teaching method lecture: 1hlaboratory: 4h

Objectives of the course Methods of samples collection and analysis of common air pollutants.

Entry requirements

Course contents

Lecture: Problems in trace analysis. Collection and pretreatment of samples. Isolation and aspiration techniques. Enrichment of analytes. Passive, dynamic and denuder methods. Use of glass scrubbers, solid adsorbents and cryogenic traps. Preparation of gas standard mixtures. Sampling of aerosols. Air monitoring.Laboratory: Collection of air samples by isolation and aspiration techniques. Determination of organic and inorganic air pollutants (acetone, diethyl ether, phenol, aromatic hydrocarbons, hydrochloride, carbon disulfide) by spectrophotometric and chromatographic methods. Validation of applied methods.

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Assessment methods Lecture: written examLaboratory: written reports


Mudakavi J.R., Principles and Practices of Air Pollution Control and Analysis, I.K. International Publishing House Pvt. Ltd., New Delhi 2010.

Berezkin V.G., Drugov Y.S., Gas chromatography in air pollution analysis, Journal of Chromatography Library, Volume 49, Elsevier 1991.

Mullins E., Statistics for the quality control chemistry laboratory, RSC, Cambridge 2003. New horizons and challenges in environmental analysis and monitoring, ed. J. Namieśnik,

W. Chrzanowski, P. Żmijewska, CEEAM, Gdańsk 2003. (http://www.pg.gda.pl/chem/CEEAM/Dokumenty/CEEAM_ksiazka/New_ANG.htm)


Course title Analysis of food contaminants

Person responsible for the course Alicja Wodnicka, PhD


[email protected]

Course code (if applicable) WTiICh/IISt/OSr/D-3b_56 ECTS points 2

Type of course Optional Level of course S2



Teaching method laboratory: 3h

Objectives of the course Analysis of typical contaminants naturally generated in food and brought from environment.

Entry requirements

Course contents

Natural contaminations present in foods. Natural toxicants generated in food during spoilage processes. Examination of ethanol content in beverages. Changes in plant oils at high temperature. Products of fats oxidation. Environmental toxicants (pesticides, industrial contaminants). Pesticide residues in food. Examination of adulterated food.

Assessment methods Laboratory written reports and test


1. Food Safety: Contaminants and Toxins, ed. J.P.F. D'Mello, CABI, Trowbrige 2003.2. Toxins in Food, ed. W.M. Dąbrowski, Z.E. Sikorski, CRC Press, Boca Raton, Florida 2005.3. Coultate T.P., Food: the Chemistry of its Components, RSC, Cambridge 2009.


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http://www.pg.gda.pl/chem/CEEAM/Dokumenty/CEEAM_ksiazka/New_ANG.htm

Course title Chemistry and technology of medicines

Person responsible for the course Halina Kwiecień, Assistant ssor


[email protected]




Hours per week 5 Hours per semester 75 (30 lecture, 45 laboratory)


Objectives of the course Come to know about chemistry and technology of medicines, methods of drug discovery and development of pharmaceutical industry

Entry requirements Organic chemistry, biochemistry, stereochemistry, chemical technology, chemical engineering

Course contents

Lectures: Nomenclature and classification of medicines. Biologics, derived from natural product source, semisynthetics and synthetics drugs. Mechanism of action and biotransformation. Methods of new drug discovery, combinatorial chemistry. Processes and apparatus in pharmaceutical industry. Wastes and “green” pharmaceutical technology. Chemistry and technology of following groups of drugs: analgesic, sulfonamides, cardiovascular, anticancer antihistaminic, psychotropic, antifungal. Biotechnology, natural and synthetic antibiotics.

Laboratory: synthesis of 1-2 products by standard processes in pharmaceutical chemistry. Purification, chromatographic and spectral analyses of the products.



1. Lednicer D., „The Organic chemistry of Drug Synthesis”, Willey, New York, 19952. Kleemann A., Engel J „Pharmaceutical Substances. Syntheses, Patents, Applications”,

Thieme, Stuttgard, 4th Edition, 20013. Furniss B.S., Hannaford A.J., Smith, P.W.G., Tatchell A.R. “Vogel’s Textbook of Practical

Organic chemistry”. Fifth Ed., The School of Chemistry, Thames Polytechnic, London, 1989.


Course title Chromatographic methods


Małgorzata Dzięcioł, PhD E-mail address to the person responsible for the course

[email protected]



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Hours per week 6 Hours per semester 90(30 lecture, 60 laboratory)


Objectives of the course Theoretical and practical aspects of chromatographic methods.

Entry requirements

Course contents

Lecture: General theory of chromatography. Classification of chromatographic methods. Retention parameters. Resolution. Separation efficiency of column. Identification and quantification methods in chromatography. Gas chromatography (GC) – principles, instrumentation, carrier gas, columns and stationary phases, sampling, detectors, applications. High performance liquid chromatography (HPLC) – instrumentation, eluents, stationary phases, normal and reversed-phase chromatography, isocratic and gradient elution, detectors, applications. Thin layer chromatography (TLC) – principles, adsorbents and plates, chambers, development techniques, densitometry. Laboratory: Qualitative and quantitative analysis in gas chromatography. Column efficiency – theoretical plate number. Application of GC/MS method in identification of compounds. Qualitative and quantitative analysis in HPLC method.

Assessment methods Lecture - written examLaboratory – written reports

Course title Research project




[email protected]


WTiICh/ISt/TCh/D2-3_59WTiICh/ISt/TCh/D2-4_60WTiICh/ISt/TCh/D2-5_61

ECTS points 12


Semester winter or summer Language of instruction English

Hours per week 9 Hours per semester 135(105 laboratory, 30 seminar)

Teaching method laboratory: 7hseminar: 2h

Objectives of the course Applying of knowledge and skills learned during studies to solving a practical research problem.

Entry requirements Fundamentals of chemistry, mathematics and analytical methods.

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Course contents

The students accomplish the research project concerning a given subject. It consist of literature studies, concept of project realization, selection of used materials, performing the selected process, characteristic of obtained products, control measurements using proper methods and instruments, calculations, discussion of the results, conclusions. Description of all this aspects should be given in the written project report.

Assessment methods- assessment of progess of the work (presentations during seminar)- assessment of the quality of written project report- oral exam, including final presentation

Recommended readings Literature connected with the research subject, including books, articles and patents.


Course title Technologies in environmental protection I and II

Person responsible for the course Elżbieta Huzar, PhD


[email protected]


WTiICh/ISt/OSr/B-6-1 _62WTiICh/ISt/OSr/B-6-2_63 ECTS points 3 (I)

2 (II)



Hours per week 3 (I)2 (II) Hours per semester 45 (I): 15 lecture + 30 classes

30 (II): laboratory

Teaching methodlecture: 1hclasses: 2hlaboratory: 2h

Objectives of the course Knowledge about contaminations in air, waters and soil. Technologies for removing contaminations from air, water and wastewater and soil.

Entry requirements Inorganic and organic chemistry

Course contents Lectures: Contaminants in air, water and soil. Kind and sources of air contaminants and global problems of protection of air. Methods of dust extraction and types of dust collectors: inertial separators, fabric filters, wet scrubbers, electrostatic precipitators, unit collectors. Systems of monitoring of contaminations in air. Role of green in protection of air. Alternative sources of energies. Classification and protection of natural water. Sources of water pollutants. Characteristic, classification, composition and specificity of effluents. Technologies for removing of contaminants from water. Conventional treatment systems: primary treatment, secondary treatment. Advanced treatment processes: filtration system, oxidation processes, ultraviolet treatment, electrolysis. Natural processes of clean up of water from contaminations. Contaminations in soil and methods of bioremediation.Classes: methods of emission control, methods of disulphurize in combustion gases, methods of clean-up of municipal effluents and industrial. Laboratory: measurements of emissions of contaminations: SO2 and NOx, and hydrocarbons; assessment of concentration of dust contaminations and research of their characteristic;

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estimate of efficiency of method of clean-up of water.



1. Wilhelm Batel, Dust Extraction Technology: Principles, Methods, Measurement Technique, John Wiley & Sons Ltd , 1973

2. Horan, N. J. , Biological wastewater treatment systems: theory and operation. John Wiley & Sons Ltd, 1989

3. Matthew A. Tarr, Chemical Degradation Methods for Wastes and Pollutants - Environmental and Industrial Applications, Marcel Dekker, 2003

4. Donald L Sparks, Environmental Soil Chemistry, Academic Press 2003


Course title Technology of dyes and intermediates I and II




[email protected]


WTiICh/IISt/TCh/D4-5_64WTiICh/IISt/TCh/D4-11_65 ECTS points 1 (I)

1 (II)



Hours per week 1 (I)1 (II) Hours per semester 15 (I): lecture

15 (II): laboratory


Objectives of the course Come to know about chemistry and applications of dyes, technology of dyes and development in dyes industry.

Entry requirements Organic chemistry and technology, physical chemistry, chemical engineering

Course contents

Lectures: Introduction: historical development of synthetic dyes, development of colour and constitution theory. Classification of colorants by chemical structures and by application. Azo dyes, structure, synthesis and properties. Carbocyclic and heterocyclic mono-and poly- azo dyes. Basic structure, synthesis and properties following dyes: anthraquinone, triarylmethane and their heterocyclic analogues, polycyclic aromatic carbonyl, indigoid, dyes, polimethine and phthalocyanine. Production of dyes, “green processes” in dyes industry. Application of colorants. Dyeing of wool, cellulosic, acetate polyester, polyamide and acrylic fibres. Dyes for nontextile applications. Dyes in the new technology industries: for displays, for optical data storage, laser dyes. Laboratory: synthesis of 1-2 dyes (acid, basic, direct or reactive dyes), purification, chromatographic and UV-VIS analysis of the products. Dyeing of wool or cellulosic fibres.

Assessment methods test and grade

Recommended readings1. Waring D.R., Hallas G., „The Chemistry and Application of Dyes”, Plenum Press, New

York, 1994 2. Furniss B.S., Hannaford A.J., Smith, P.W.G., Tatchell A.R. “Vogel’s Textbook of Practical

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http://www.cabdirect.org:80/search.html?q=pb%3A%22John+Wiley+%26+Sons+Ltd.%22


http://www.cabdirect.org:80/search.html?q=do%3A%22Biological+wastewater+treatment+systems%3A+theory+and+operation.%22

http://www.cabdirect.org:80/search.html?q=au%3A%22Horan%2C+N.+J.%22


Organic chemistry”. Fifth Ed., The School of Chemistry, Thames Polytechnic, London, 1989.


Course title Toxicological assessment of materials and products


Małgorzata Dzięcioł, PhD E-mail address to the person responsible for the course

[email protected]




Hours per week 2 lecture, 4 laboratory Hours per semester 90(30 lecture, 60 laboratory)


Objectives of the course Toxicological aspects of raw materials and industrial products daily use. Methods of studies in quality control of products.

Entry requirements

Course contents

Lecture: Sources of toxic substances in environment. Toxic effects of chemical substances. Factors influencing toxicity. Health risk assessment of daily use products. Toxicological aspects connected with polymeric materials. Emission of toxic compounds from plastics during production, processing and fire. Methods of studies of emission from plastics. Static and dynamic headspace technique. Migration testing of plastic materials intended to come into contact with food. Overall and specific migration. Food simulants. Toxic substances in food. Food contamination from environment. Toxic products of food processing. Food additives. Natural harmful food components. Toxic ingredients of cosmetics.Laboratory: Analysis of toxic components of products. Studies of emission of volatile compounds from daily use products. Analysis of preservatives and toxic compounds in food.

Assessment methods Lecture - written examLaboratory – written reports


9. Fundamental Toxicology, ed. Duffus J.H., Worth H.G.J., RSC Publishing 200610. Henneuse-Boxus C., Pacary T., Emissions from Plastics, Report 161, Rapra Review Reports,

200311. Crompton T.R., Additive Migration from Plastics into Foods – a Guide for Analytical

Chemists, Smithers Rapra Technology Limited, 200712. Food Safety and Food Quality, ed. Hester R.E., Harrison R.M., The Royal Society of

Chemistry, 200113. Food Safety: Contaminants and Toxins, ed. D’Mello J.P.F., CABI Publishing, 2003


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