use of supercritical fluids for enhancement of polymerization process office 2007 file
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USE OF SUPERCRITICAL FLUIDS IN ENHANCEMENT OF POLYMERIZATION PROCESS (REVIEW).
CHINMAY P TIWARI AKSHAY G CHOTHANI DEPARTMENT OF CHEMICAL ENGINEERING DEPARTMENT OF CHEMICAL ENGINEERING L.D. COLLEGE OF ENGINEERING L.D. COLLEGE OF ENGINEERING AHMEDABAD AHMEDABAD chinmaytiwari15@gmail.com akshaychothani1995@gmail.com
Abstract
Our review paper is about one of the recent
advancement in the polymerization process
and discussing the methodology of
supercritical polymerization using the fluids in
their supercritical state for the process to take
place. Supercritical fluids are having
temperature and pressure higher than the
critical temperature. Major examples of fluids
used in supercritical state are CO2 and
Propane. Use of supercritical fluids in polymer
processing increases the rate of reaction and
thus decreases the reaction time which is
helpful. Supercritical fluids provides higher
mass transfer coefficients as compared to
liquid phase and hence they provide higher
value of overall rate of reaction in
polymerization process.
Keywords
Supercritical polymerization, fast polymer
processing.
Introduction
Supercritical fluids (SCFs) have unique properties that may enhance many types of chemical processes. An additional advantage of using SCFs stems from the fact that they may replace many environmentally harmful solvents currently used in industry. In particular, SCFs represent an attractive alternative to organic solvents for use as additives in polymer processing. For example, supercritical carbon dioxide (scCO2), which is by far the most widely used SCF, is relatively cheap, nontoxic, and non-flammable and has zero ozone-depletion potential. Moreover, the fact that CO2 is a gas under ambient conditions makes its removal from the polymeric product very easy, avoiding for example, the costly processes of drying or solvent removal, which is very important in the processing of polymer based materials. But what are the properties of an SCF? A supercritical fluid is defined as a substance above its critical pressure and temperature. However, there is still no apparent distinction between a high-pressure gas and
an SCF because, under all circumstances, such a fluid will occupy the full volume of its container, demonstrating the typical behavior of a gas. Nevertheless, such a fluid is usually not called a high-pressure gas but a supercritical fluid. The reason is that one cannot liquefy such a fluid under any pressure once it is heated above its critical temperature (it should be noted, how- ever, that it can still be solidified at extremely high pressures). No phase separation occurs for any substance at pressures or temperatures above its critical values. In other words, the critical point represents the highest temperature and pressure at which gas and liquid can coexist in equilibrium. However, it is very important to note that this definition is for a pure substance. Polymerization process is to react monomer molecules together to form a polymer chain or a 3-D network.
An example of alkene polymerization, in which each styrene monomer's double bond reforms as a single bond plus a bond another styrene monomer. The product is polystyrene.
Polymers can be synthesized and/or modified in a supercritical medium. Most polymers show some solubility, plasticization, or swelling in supercritical fluid media. Depending on the choice of polymer-SCF medium, the degree of solubilization, plasticization, or swelling varies.
Properties of Supercritical CO2 and its effects on the polymerization process
CO2 is used in majority as a supercritical fluid as it’s cheaper, non-poisonous and easily available and its critical properties are easily attainable with respect to others as seen from the phase diagram of CO2.
USE OF SUPERCRITICAL FLUIDS IN ENHANCEMENT OF POLYMERIZATION PROCESS (REVIEW).
CHINMAY P TIWARI AKSHAY G CHOTHANI DEPARTMENT OF CHEMICAL ENGINEERING DEPARTMENT OF CHEMICAL ENGINEERING L.D. COLLEGE OF ENGINEERING L.D. COLLEGE OF ENGINEERING AHMEDABAD AHMEDABAD chinmaytiwari15@gmail.com akshaychothani1995@gmail.com
There have been many application of different spectroscopic methods and other new techniques at molecular level to identify for the first time specific molecular interactions between CO2 and polymers
that may be responsible for the plasticization of glassy polymers. The changes in IR spectra of CO2 incorporated
into various
polymers indicate a specific interaction between CO2 and polymer functional
groups. Increased polymer segmental mobility has also been observed, indicative of the plasticization phenomenon.
Fig. Visualization of the relative effort required for polymerization and
solvent recovery in conventional catalytic polymerization processes based on organic solvents. Thus polymerization with supercritical fluids is preferred.
Supercritical fluids, mainly supercritical CO2,
have been widely applied in the chemistry and processing of polymers. Elevated pressure CO2 is known to swell and
plasticize glassy polymers. The increase in the polymer inter-chain distance upon
plasticization by CO2 is accompanied by the
enhanced mobility of polymer segments, similar to the plasticizing effect by ordinary solvents. One of the differences between common liquid plasticizers and CO2 is that
CO2 is easily removable from the processed
polymers, and thus may be used for “solvent-free” incorporation of additives. It is possible to change the degree of plasticization and swelling of such a polymer, and consequently it’s free- volume, merely by changing the density of the CO2.
The motivation for using SCFs in polymer processing stems not just from the environmental impetus for their use as the benign (not harmful) solvents. As explained above, SCFs have a number of unique properties that could be utilized for polymer synthesis in these media.
In addition, it is the molecular structure of some specific fluids, primarily supercritical CO2 that plays a major beneficial role in
polymer-processing. The sorption of scCO2 into polymers results in their swelling and changes the mechanical and physical properties of the polymers. The most important effect is the reduction of the glass transition temperature (Tg) of glassy polymers
subjected to scCO2, often simply called
plasticization. The plasticization of polymers induced by scCO2 has an impact on many
polymer-processing operations, These include viscosity reduction for polymer extrusion and blending, enhancement of the diffusion of additives through polymer matrices for impregnation and extraction, enhancement of monomer diffusion for polymer synthesis, foaming of polymers, and changes in polymer morphology due to induced crystallization.
Illustrations of enhancement in polymer processing using supercritical fluid
Decomposition of Waste Plastics in Super critical Water
USE OF SUPERCRITICAL FLUIDS IN ENHANCEMENT OF POLYMERIZATION PROCESS (REVIEW).
CHINMAY P TIWARI AKSHAY G CHOTHANI DEPARTMENT OF CHEMICAL ENGINEERING DEPARTMENT OF CHEMICAL ENGINEERING L.D. COLLEGE OF ENGINEERING L.D. COLLEGE OF ENGINEERING AHMEDABAD AHMEDABAD chinmaytiwari15@gmail.com akshaychothani1995@gmail.com
1. Property of super critical water
Water, most important solvent in nature, has fascinating properties as a reaction solvent in its super critical condition. The super critical water is the fluid that is over the critical point of vapour-liquid coexistence state. The critical temperature and critical pressure of water are 647K and 22MPa, respectively. The density of super critical water can continuously be controlled between gas like and liquid like values by varying its pressure and temperature. The value of dielectric constant that is one of the parameter estimating the solvent polarity, increase with increasing density. The relation between dielectric constant and density is shown in figure 1.
fig1. Dielectric constant of water
At super critical condition, the values of the constant between 5 to 25 can be obtained. This corresponds to the dielectric properties of polar organic liquids under normal condition. This property partially explain its ability to dissolve nonpolar organic compounds.
At standard conditions, water dissociates slightly into hydrated hydrogen and hydroxyl ions: the "ion product" (Kw) of their concentrations is about 10-14(mol/1)2. The ion product of water is strongly dependent on density and weakly dependent on temperature. This is shown in figure 2
fig2. Ion product of water
At super critical condition, for example at 573K and 34.5MPa, the value of ion product is 10-11. This value means hydrogen ion concentration of super critical water is almost 3*10-7 and this value means that the super critical water at this condition acts the role as acid solutions catalyst.
2. Hydrolysis of plastic in super critical
water
By the fascinating properties of super critical
water, the substance with ether, ester and
isocyanate bond which are the condensation
polymerization plastic can easily be
decomposed to their monomer when super
critical water is used as reaction solvent. It is
experienced that the PET (Polyethylene
terephthalate) is decomposed to their monomer
in the super critical water by the batch-
continuous apparatus. Fig.3 shows the relation
between the recovery yield of monomer and
reaction temperature at 25MPa and 30MPa.
The recovery yield of TPA (Ter-phthalic acid)
reaches almost 100% over 350K of the
temperature. However, yield of EG (Ethylene
glycol) is about 30% at the same temperature.
It seems that this due to effect of acid catalyst
of recovered TPA in super critical water.
USE OF SUPERCRITICAL FLUIDS IN ENHANCEMENT OF POLYMERIZATION PROCESS (REVIEW).
CHINMAY P TIWARI AKSHAY G CHOTHANI DEPARTMENT OF CHEMICAL ENGINEERING DEPARTMENT OF CHEMICAL ENGINEERING L.D. COLLEGE OF ENGINEERING L.D. COLLEGE OF ENGINEERING AHMEDABAD AHMEDABAD chinmaytiwari15@gmail.com akshaychothani1995@gmail.com
Fig.3 Relation between recovery yield of TPA from
PET and reaction temperature at 25, 30MPa
3. Pyrolysis of plastic in super critical
water
When the super critical water is used as
reaction solvent, the temperature of water
used as reaction medium is over the pyrolysis
condition of plastics. The addition
polymerization plastic is converted to the oil in
the super critical water.
4. Application off super critical water in
waste plastic treatment field
When the waste material which is composed
of the condensation polymerization plastic and
the addition polymerization plastic, is treated
in the super critical water, the former one is
selectively decomposed to their monomer in
short time, that is the chemicals, and at this
time latter one is not decomposed. The
addition polymerization polymer, however, is
continuously converted to oil following to the
monomerization of the condensation
polymerization plastic. The technology on this
decomposition of plastics in the super critical
water is expected as the novel waste material
treatment process.
fig.4
Polymer clay nanocomposites (illustration 2)
CO2 has a readily accessible critical point and
is a relatively inexpensive, non-toxic, and
environmentally friendly solvent. Our research
has shown that soaking commercial clays in
supercritical CO2, followed by a rapid
depressurization can produce significant clay
dispersion without any additional modification
of the clays or their modifiers. Clay dispersion
has been achieved with a variety of different
clays, with and without the presence of polymer
The extent of dispersion is characterized by a
wide range of characterization tools, such as
WAXD (wide-angle X-ray diffraction), SEM
(scanning electron microscope), TEM
(Transmission electron microscopy), rheology,
USE OF SUPERCRITICAL FLUIDS IN ENHANCEMENT OF POLYMERIZATION PROCESS (REVIEW).
CHINMAY P TIWARI AKSHAY G CHOTHANI DEPARTMENT OF CHEMICAL ENGINEERING DEPARTMENT OF CHEMICAL ENGINEERING L.D. COLLEGE OF ENGINEERING L.D. COLLEGE OF ENGINEERING AHMEDABAD AHMEDABAD chinmaytiwari15@gmail.com akshaychothani1995@gmail.com
tensile and permeability testing.
The scCO2-processed samples have been benchmarked with solution blended and melt-compounded PS nanocomposites. The results suggest that the supercritical CO2-processing produces significant dispersion and improves polymer-clay interactions. The low-frequency modulus of scCO2-processed PS/clay melts are more than an order of magnitude better than those prepared by solution blending and melt compounding, for the same clay loading.
Conclusion These theories shows that conventional
processes for polymerization mainly uses
liquids as solvents which has its own
demerits while using supercritical fluids
has its own merits. In using liquid solvents
for polymerization their revival from the
reaction mixture is costlier whereas it may
sometime contaminate the product by its
presence but by using non-toxic, non-
flammable gas like carbon dioxide easy
separations plus higher rate of reaction
due to formation of microcellular structure
takes place as illustrated in below figure.
References
http://www.kannangroup.com/nanoco
mposites.html
http://infohouse.p2ric.org/ref/26/japan
/Waste-187.html
http://www3.imperial.ac.uk/vibrational
spectroscopyandchemicalimaging/res
earch/intermolecular/polymerprocessi
ng
https://workspace.imperial.ac.uk/.../pu
blic/reviewscf.pdf
eckert.chbe.gatech.edu/pdf/polymer.pdf
Journal on supercritical Carbon-
Dioxide for Sustainable Polymer
Processes - Maartje Kemmere
Polymer Processing with Supercritical
Fluids-S. G. Kazarian
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