ChE 553 Lecture 22 Introduction To Catalysis

1

Importance Of Catalysis

• 90% of all chemical processes use catalysts

• Changes in catalysts have a giant influence on rates and selectivity’s of reactions. More than anything else

• Most real reactor design associated with optimizing performance of catalyst

2

Catalysis Definition

Ostwald defined a catalyst as a substance which changed the rate of reaction without itself being consumed in the process

Not being consumed catalyst does change

3

Catalytic Reaction Occurs Via A Catalytic Cycle:

reactants + catalyst complex

 

complex products + catalyst

4

Example: Rhodium Catalyzed CH3OH+COCH3COOH

5

HI

H O2

CH OH3

CH I3

CH COOH3

CH COI3[Rh(CO) I ]2 2

-

RhI

H C3C I

I

O

RhI

CH3

CI

I

O

CO

CO

CO

Figure 12.1 A schematic of the catalytic cycle for Acetic acid production via the Monsanto process.

Printing press analogy

The Rate Enhancement Of A Number Of Reactions In The Presence Of A Catalyst

6

Reaction Catalyst Rate Enhancement

Temperature

Ortho H2 Para H2 Pt (solid) 300K

2NH3 N2 + 3H2 Mo (solid) 600K

C2 H4 + H2 C2 H6 Pt (solid) 300K

H2 +Br2 2HBr Pt (solid) 1 108 300K

2NO + 2H2 N2 + 2H2 O Ru (solid) 3 1016 500K

CH3COH CH4 + CO I2 (gas) 4 106 500K

CH3CH3 C2H4 +H2 NO2 (gas) 1 109 750K

(CH3)3 COH

(CH3)2CH2CH2+H2O

HBr (gas) 3 108 750K

1040

1020

1042

Catalysts Do Not Work Over A Broad Temp Range

Gas Phase -- NoWall Reactions

Catalyst Alone

Approximate Effect Of Walls

0 500 1000 1500 2000 2500

Temperature, K

1E-15

1E-12

1E-9

1E-6

0.001

1

1000R

ate

, M

ole

s/lit

se

c

Figure 12.2 The rate of hydrogen oxidation on a platinum coated pore calculated with a) only heterogeneous (catalytic) reactions, b) only radical reactions, and c) combined radical, homogeneous reactions

7

Types Of Catalysts:

Homogeneous Catalysts

Heterogeneous Catalysts

8

Homogeneous Catalysts:

• Acids or Bases

• Metal salts

• Enzymes

• Radical initiators

9

Table 12.2-Some Reactions Commonly Catalyzed By Acids And Bases

10

Reaction Example Typical Application

Isomerization(Rearranging the

structure of a molecule)

CH2=CHCH2CH3

CH3CH=CHCH3

Octane EnhancementMonomer Production

Paraxylene Production

Alkylation(Making too little molecules into a

bigger one)

CH3CH=CHCH3 + CH3CH2CH2CH3

(CH3CH2)CH(CH3)(C4H9)

Pharmaceutical Production

Monomer ProductionFine Chemicals

Butane + olefin octane

Cracking(Taking a big molecule and making it into two

littler ones).

C12H24 C7H14 + C5H10 Crude Oil ConversionDigestion

Some Reactions Commonly Catalyzed By Acids And Bases Continued

11

Reaction Example Typical ApplicationEsterfication Soap Production

(Attaching an acid to a base eliminating water)

Fragrance Production

2 CH3CH2CH2CHO Fine Chemicals

+ H2O Pharmaceutical production

Alcohol Dehydration(removing a hydrogen and an OH from an alcohol,

producing a double bond)

Cationic Polymerization Propylene

polypropylenePolymer Production

Aldol Condensation Reactions (combining two aldehydes by eliminating

water)

CH3CH2OH +CH3COOH CH3COOCH2CH3 +

H2O

CH3CH2OH CH2=CH2

+ H2O

Alternative fuels

Acids And Bases As Catalysts

Benzene ethylene ethylbenzene

(12.2)

a proton reacts with the ethylene to form an ethyl ion: H CH2CH2 CH3CH2

(12.3)

12

Acids As Catalysts Continued

The ethyl ion reacts with benzene to yield and ethylbenzene ion: CH3CH2 C6H6 CH3CH2C6H6

(12.4)

Then the ethylbenzene ion loses a proton: CH3CH2C6H6 CH3CH2C6H5 H

(12.5)

13

Metal Atoms: As Catalysts

H2 2S 2H ad (12.6)

C2H4 + S C2H4 ad

(12.7)

C2H4 (ad) + H(ad) C2H5 (ad) + S

(12.8)

C2H5 ad H ad C2H6 2S

(12.9) 14

Examples Of Reactions Catalyzed By Homogeneous Transition Metal Catalysts

15

Reaction Catalyst Olefin Polymerization [TiCl2(C5H5)2]

2+ or TiCl2/Al(C2H5)3

(Ziegler-Natta Catalyst) Olefin Hydrogenation Rh(P(C6H5)3)3Cl

Wilkinson Catalyst C2H4+H2O Acetaldehyde

(Wacker Process) PdCl2(OH)2

C2H4+H2 +CO propylaldehyde (Hydroformylation)

HCo(CO)4

CH3OH + CO CH3COOH (Monsanto Carbonylation

Process)

[Rh(CO)2I2]1-

H2O2 +CH3CH2OH CH3CHO+2 H2O

Fe2+

Enzymes As Catalysts

Oxidoreductases (promote oxidation reduction

reactions)

Transferases (promote transfer of functional groups)

NADH peroxidas

e (Oxidizes

NADH with peroxides

NADH + H2O2 NAD(+)+2

H2O.

Dimethylallylcis-transferase (Transfer

dimethylallyl groups)

Dimethylallyl diphosphate + isopentenyl

disphosphatediphosphate + dimethylallylcis-

isopentenyldiphosphate

Ferroxidase (oxidizes

Iron)

4 Fe2+ + 4 H+ + O2 4 Fe3+

+ 2 H2O

Glycoaldehyde transferase(Transfer’s

Glucoaldeydes)Also called

Transketolase

Sedoheptulose 7-phosphate + D-glyceraldehyde 3-

phosphate D-ribose 5-phosphate + D-xylulose 5-

phosphate

Glucose oxidase(oxidizes Glucose)

-D-Glucose + O2 D-

glucono-1,5-lactone + H2O2

Alanine aminotransferase(Transfer amino

groups from alanine)

L-Alanine + 2-oxoglutarate pyruvate + L-glutamate

16

Enzymes Continued

Hydrolases(Promote hydrolysis/cleavage reactions)

Lyases(promote addition of CO2, H2O and NH3 to double bonds or formations of double bonds via elimination of CO2, H2O or NH3)

Carboxylesterase(Promotes hydrolysis of ester linkages)

A carboxylic ester + H2O an alcohol

+ a carboxylic anion

Carbonate dehydratase (Dehydrates carbonates)

H2CO3 CO2 + H2O

1,4-ALPHA-D-Glucan

glucanohydrolase

(also called ALPHA-Amylase)

Hydrolysis of 1,4-ALPHA-glucosidic

linkages in oligosaccharides

and polyasaccharides.

Citrate dehydratase

Citrate CIS-aconitate + H2O

Interleukin 1-beta converting enzyme

Release of interleukin 1-beta

by specific hydrolysis at 116-ASP-|-ALA-117 and 27-ASP-|-GLY-28

bonds

Pyruvate decarboxylase

A 2-OXO acid an aldehyde + CO2

17

Enzymes Continued

18

Maleate isomerase (promotes cis-trans

isomerization of Maleate)

Maleate

Fumarate

Leucine--trna ligase

ATP + L-leucine + t-RNA(leu)

AMP + diphosphate + L-

leucyl-t-RNA(leu).

Cholestenol DELTA-isomerase

5-Alpha-cholest-7-en-3-

beta-ol 5-Alpha-cholest-8-en-3-beta-ol

Pyruvate carboxylase

ATP + pyruvate +

(HCO3) ADP +

phosphate + oxaloacetate

Mannose isomerase D-Mannose

D-fructose

Aspartate--ammonia

ligase

ATP + L-aspartate

+ NH3 AMP +

diphosphate + L-asparagine

Isomerases (promote isomerization reactions)

Ligases (promotes formation of bonds - generally used to catalyze endothermic reactions requiring

ATP)

Radical Initiators As Catalysts

Example:

19

C2H6 C2H4 H2

(12.10)

X + I2 2I + X

(12.11)

Then the iodine can react with ethane to start the reaction:

I CH3CH3 HI CH2CH3 (12.12)

Free Radical Polymerization Catalysts:

R R R O O 2 O

(12.13)

Then the radical reacts with the ethylene to start the polymerization process:

R RO 2CH2 OCH2CH2 CH (12.14)

20

Free Radicals Catalysts For Ozone Destruction

Cl O3 ClO O2

(12.15)

The ClO can then react via a number of processes to reduce the ozone layer. One particular reaction is:

ClO O3 Cl 2O2 (12.16)

21

Some Examples Of Reactions Initiated Or Catalyzed By Free Radicals And Similar Species

22

Reaction Initiator Reaction Catalyst Olefin

Polymerization Peroxides,

(Ph)3CC(Ph)3 2SO2 +O2

SO3 (Lead Chamber

Process)

NO/NO2

Hydrocarbon Dehydrogenatio

n

Iodine, NO2 chlorine atoms

Ozone Depletion

Cl

Hydrocarbon Oxidations

CH CH N I ,3 2 4

CH CH N C H COO3 2 4 6 5

Solvents: As Catalysts

CH3I NaCl CH3Cl + NaI (12.17)

Table.12.6 The rate of reaction (12.17) in several solvents. All measurements have been extrapolated to 25 C

Solvent Rate const, lit/mole sec

Gas Phase about 10-45 Water 3.5 10-5 Methol 3 10-6 Methyl Cyanide

0.13

DMF 2.5 23

Next: Heterogeneous Catalysis

Examples of heterogeneous catalysts include:

 

• Supported Metals

• Transition Metal Oxides and Sulfides

• Solid Acids and Bases

• Immobilized Enzymes and Other Polymer Bound Species

24

Supported Metal Catalysts

25

Figure.12.3 A picture of a

supported metal catalyst.

Use support because platinum very expensive and only the surface is active. Spread platinum out on cheap support. Support also provides strength

Pictures Of Some Heterogenous Catalysts

26

Pores In Heterogeneous Catalysts

27

Figure 14.3 A cross sectional diagram of a typical catalyst support.

Advantage Of Heterogeneous Catalysts Compared To Homogeneous:

• Cheaper separation• More selective• Generally cheaper

 

Disadvantage• Not quite as active or a per metal atom

basis

28

A Selection Of The Reactions Catalyzed By Supported Metals

29

Reaction Catalyst Reaction Catalyst Hydrocarbon

Hydrogenation, Dehydrogenation

Pt, Pd, Ni CO + H2 Hydrocarbons

(Fischer-Tropsch)

Fe, Rh

CO oxidation, total oxidation of

hydrocarbons

Pt, Pd, Cu, Ni, Fe, Rh, Ru

Steam reforming for

production of hydrogen

Ni plus additives

CO + 2H2 CH3OH

Cu/ZnO Reforming (Isomerization of

oil)

Pt/Re/Al2O3

A Selection Of The Reactions Catalyzed By Supported Metals

Reaction Catalyst Reaction Catalyst 2 CO + 2NO

2CO2+ N2 Pt, Rh, Ru (catalytic converter)

2NH3 +O2 N2O5 +3H2O

Pt

N2 + 3 H2 2 NH3

Fe, Ru, Rh Alcohols + O2 Aldehydes +

H2O e.g. 2 CH3OH + O2

2 H2CO +H2O

Ag, Cu

2 C2H4 + O2

2 ethylene oxide Ag, Cu R-R' + H2

RH + HR' (Hydrogenolysis)

Ni, Co, Rh, Ru

30

Typical Mechanism Of Heterogeneous Catalysis (H2+C2H4C2H6)

H2 + 2S 2 H(ad) (12.18)

C2H4 S C2H4 ad

(12.19)

C2H4 ad H ad C2H5 ad S

(12.20)

C2H5 ad H ad C2H6 2S

(12.21) 31

Transition Metal Oxides, Nitrides, Sulfides:

Bond transition

Metal to O, N, S to reduce activity and to increase selectivity

32

A Selection Of The Reactions Catalyzed By Transition Metal Oxides, Nitrides, And Sulfides

Reaction Catalyst Reaction Catalyst

2 SO2 + O2 2 SO3 V2O5 CO + H2O CO2+

H2 (Water Gas Shift)

FeO, CuO, ZnO

Hydrodesulfurization CoS, MoS, WS 2(CH3)3COH Þ(CH3)3COC(CH

3)3 + H2O

TiO2

CH3CH=CH2 + O2 (Bi2O3)x(MoO3)y 2 CH3CH=CH2 + 3

O2 + 2NH3

CH2=CHCHO + (Bismuth molybate)

2CH2=CHCN +

H2O Uranium Antimonate

6 H2O

(aminoxidation)

(FeO)x(Sb2O3)y

33

A Selection Of The Reactions Catalyzed By Transition Metal Oxides, Nitrides, And Sulfides

Reaction Catalyst Reaction Catalyst

4 NH3 + 4 NO +O2

4N2 + 6 H2O

benzene+O2

maleic anhydride +

water(Selective catalytic reduction)

naphthylene+O2 phthalic anhydride +

waterCH3CH2(C6H5) +O2

CH2=CH(C6H5) + H2O

NiO, Fe2O3,

V2O5, TiO2

(styrene production) CuO, Co3, O4,

MnO2

Aromatiztione.g. Heptane Tolvene

H2 or H2O

Cr2O3/Al2O3 Hydrodenitrogenation

NiS,MoS

V2O5, TiO2 (V2O5)x(PO4)y

FeO Selective oxidation of hydrocarbons

34

Solid Acids And Bases As Catalysts

Table 12.9 Some common solid acids and bases

Material Type Material Type silica/alumina solid acid Mordenite zeolite

alumina solid acid ZSM-5 zeolite Y-zeolite Faugasite

zeolite VFI large pore zeolite

Sodalite zeolite Offretite zeolite HF-SbF5 superacid HSO3F superacid

H2[Ti6O4(SO4)4(OEt)10]

superacid Sulfated Zirconia

superacid

MgO solid base Na2O base

35

Very Complex Pore Structure

36Figure 12.4 A diagram of the pore structure in Faugasite.

Leads To Shape Selective Catalysis

C HH

HCH

HH

DiffusionChannel

Cavity

37Figure 12.27 An interconnecting pore structure which is selective for the formation of paraxylene.

Summary

• Two types of catalysts– Homogeneous– Heterogeneous

• Homogeneous more active

• Heterogeneous less expensive, easier to use/control

38