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Interfacial polymerization is a type of step-growth polymerization in which
polymerization In polymer chemistry, polymerization (American English), or polymerisation (British English), is a process of reacting monomer molecules together in a chemical reaction to form polymer chains or three-dimensional networks. There are many fo ...
occurs at the interface between two immiscible phases (generally two liquids), resulting in a polymer that is constrained to the interface. There are several variations of interfacial polymerization, which result in several types of polymer topologies, such as ultra-
thin film A thin film is a layer of material ranging from fractions of a nanometer ( monolayer) to several micrometers in thickness. The controlled synthesis of materials as thin films (a process referred to as deposition) is a fundamental step in many ...
s,
nanocapsule A nanocapsule is a nanoscale shell made from a nontoxic polymer. They are vesicular systems made of a polymeric membrane which encapsulates an inner liquid core at the nanoscale. Nanocapsules have many uses, including promising medical applications ...
s, and
nanofiber Nanofibers are fibers with diameters in the nanometer range (typically, between 1 nm and 1 μm). Nanofibers can be generated from different polymers and hence have different physical properties and application potentials. Examples of natural polyme ...
s, to name just a few.


History

Interfacial polymerization (then termed "interfacial polycondensation") was first discovered by Emerson L. Wittbecker and Paul W. Morgan in 1959 as an alternative to the typically high-temperature and low-pressure melt polymerization technique. As opposed to melt polymerization, interfacial polymerization reactions can be accomplished using standard laboratory equipment and under atmospheric conditions. This first interfacial polymerization was accomplished using the Schotten–Baumann reaction, a method to synthesize
amide In organic chemistry, an amide, also known as an organic amide or a carboxamide, is a compound with the general formula , where R, R', and R″ represent organic groups or hydrogen atoms. The amide group is called a peptide bond when it i ...
s from
amine In chemistry, amines (, ) are compounds and functional groups that contain a basic nitrogen atom with a lone pair. Amines are formally derivatives of ammonia (), wherein one or more hydrogen Hydrogen is the chemical element wi ...
s and
acid chloride In organic chemistry, an acyl chloride (or acid chloride) is an organic compound with the functional group . Their formula is usually written , where R is a side chain. They are reactive derivatives of carboxylic acids (). A specific example o ...
s. In this case, a
polyamide A polyamide is a polymer with repeating units linked by amide bonds. Polyamides occur both naturally and artificially. Examples of naturally occurring polyamides are proteins, such as wool and silk. Artificially made polyamides can be made through ...
, usually synthesized via melt polymerization, was synthesized from diamine and diacid chloride monomers. The diacid chloride monomers were placed in an organic solvent (benzene) and the diamene monomers in a water phase, such that when the monomers reached the interface they would polymerize. Since 1959, interfacial polymerization has been extensively researched and used to prepare not only polyamides but also
polyaniline Polyaniline (PANI) is a conducting polymer and organic semiconductor of the semi-flexible rod polymer family. The compound has been of interest since the 1980s because of its electrical conductivity and mechanical properties. Polyaniline is one of ...
s, polyimides,
polyurethane Polyurethane (; often abbreviated PUR and PU) refers to a class of polymers composed of organic units joined by carbamate (urethane) links. In contrast to other common polymers such as polyethylene and polystyrene, polyurethane is produced from ...
s,
polyurea Polyurea is a type of elastomer that is derived from the reaction product of an isocyanate component and a synthetic resin blend component through step-growth polymerization. The isocyanate can be aromatic or aliphatic in nature. It can be mon ...
s,
polypyrrole Polypyrrole (PPy) is an organic polymer obtained by oxidative polymerization of pyrrole. It is a solid with the formula H(C4H2NH)nH. It is an intrinsically conducting polymer, used in electronics, optical, biological and medical fields. History ...
s, polyesters, polysulfonamides, polyphenyl esters and polycarbonates. In recent years, polymers synthesized by interfacial polymerization have been used in applications where a particular topological or physical property is desired, such as conducting polymers for electronics, water purification membranes, and cargo-loading microcapsules.


Mechanism

The most commonly used interfacial polymerization methods fall into 3 broad types of interfaces: liquid-solid interfaces, liquid-liquid interfaces, and liquid-in-liquid emulsion interfaces. In the liquid-liquid and liquid-in-liquid emulsion interfaces, either one or both liquid phases may contain monomers. There are also other interface categories, rarely used, including liquid-gas, solid-gas, and solid-solid. In a liquid-solid interface, polymerization begins at the interface, and results in a polymer attached to the surface of the solid phase. In a liquid-liquid interface with monomer dissolved in one phase, polymerization occurs on only one side of the interface, whereas in liquid-liquid interfaces with monomer dissolved in both phases, polymerization occurs on both sides. An interfacial polymerization reaction may proceed either stirred or unstirred. In a stirred reaction, the two phases are combined using vigorous agitation, resulting in a higher interfacial surface area and a higher polymer yield. In the case of capsule synthesis, the size of the capsule is directly determined by the stirring rate of the emulsion. Although interfacial polymerization appears to be a relatively straightforward process, there are several experimental variables that can be modified in order to design specific polymers or modify polymer characteristics. Some of the more notable variables include the identity of the organic solvent, monomer concentration, reactivity, solubility, the stability of the interface, and the number of functional groups present on the monomers. The identity of the organic solvent is of utmost importance, as it affects several other factors such as monomer diffusion, reaction rate, and polymer solubility and permeability. The number of
functional group In organic chemistry, a functional group is a substituent or moiety in a molecule that causes the molecule's characteristic chemical reactions. The same functional group will undergo the same or similar chemical reactions regardless of the re ...
s present on the monomer is also important, as it affects the polymer topology: a di-substituted monomer will form linear chains whereas a tri- or tetra-substituted monomer forms branched polymers. Most interfacial polymerizations are synthesized on a porous support in order to provide additional mechanical strength, allowing delicate nano films to be used in industrial applications. In this case, a good support would consist of pores ranging from 1 to 100 nm. Free-standing films, by contrast, do not use a support, and are often used to synthesize unique topologies such as micro- or nanocapsules. In the case of polyurethanes and polyamides especially, the film can be pulled continuously from the interface in an unstirred reaction, forming "ropes" of polymeric film. As the polymer precipitates, it can be withdrawn continuously. It is interesting to note that the molecular weight distribution of polymers synthesized by interfacial polymerization is broader than the Flory–Schulz distribution due to the high concentration of monomers near the interfacial site. Because the two solutions used in this reaction are immiscible and the rate of reaction is high, this reaction mechanism tends to produce a small number of long polymer chains of high
molecular weight A molecule is a group of two or more atoms held together by attractive forces known as chemical bonds; depending on context, the term may or may not include ions which satisfy this criterion. In quantum physics, organic chemistry, and bioch ...
.


Mathematical Models

Interfacial polymerization has proven difficult to model accurately due to its nature as a nonequilibrium process. These models provide either analytical or numerical solutions. The wide range of variables involved in interfacial polymerization has led to several different approaches and several different models. One of the more general models of interfacial polymerization, summarized by Berezkin and co-workers, involves treating interfacial polymerization as a heterogenous mass transfer combined with a second-order chemical reaction. In order to take into account different variables, this interfacial polymerization model is divided into three scales, yielding three different models: the kinetic model, the local model, and the macrokinetic model. The kinetic model is based on the principles of kinetics, assumes uniform chemical distribution, and describes the system at a molecular level. This model takes into account thermodynamic qualities such as mechanisms, activation energies, rate constants, and equilibrium constants. The kinetic model is typically incorporated into either the local or the macrokinetic model in order to provide greater accuracy. The local model is used to determine the characteristics of polymerization at a section around the interface, termed the diffusion boundary layer. This model can be used to describe a system in which the monomer distribution and concentration are inhomogeneous, and is restricted to a small volume. Parameters determined using the local model include the mass transfer weight, the degree of polymerization, topology near the interface, and the molecular weight distribution of the polymer. Using local modeling, the dependence of monomer mass transfer characteristics and polymer characteristics as a function of kinetic, diffusion, and concentration factors can be analyzed. One approach to calculating a local model can be represented by the following differential equation: = (D_i) + J_i in which ''ci'' is the molar concentration of functional groups in the ''i''th component of a monomer or polymer, ''t'' is the elapsed time, ''y'' is a coordinate normal to the surface/interface, ''Di'' is the molecular diffusion coefficient of the functional groups of interest, and ''Ji'' is the thermodynamic rate of reaction. Although precise, no analytical solution exists for this differential equation, and as such solutions must be found using approximate or numerical techniques. In the macrokinetic model, the progression of an entire system is predicted. One important assumption of the macrokinetic model is that each mass transfer process is independent, and can therefore be described by a local model. The macrokinetic model may be the most important, as it can provide feedback on the efficiency of the reaction process, important in both laboratory and industrial applications. More specific approaches to modeling interfacial polymerization are described by Ji and co-workers, and include modeling of thin-film composite (TFC) membranes, tubular fibers, hollow membranes, and capsules. These models take into account both reaction- and diffusion-controlled interfacial polymerization under non-steady-state conditions. One model is for thin film composite (TFC) membranes, and describes the thickness of the composite film as a function of time: t = -( + + ) \ln(1-)-X^2 - (+)X Where ''A0'', ''B0'', ''C0'', ''D0'', and ''E0'' are constants determined by the system, ''X'' is the film thickness, and ''Xmax'' is the maximum value of film thickness, which can be determined experimentally. Another model for interfacial polymerization of capsules, or encapsulation, is also described: t = A_0^5E_0I_4 + B_0^4E_0I_3 + C_0^2E_0I_2 + D_0E_0I_1 Where ''A0'', ''B0'', ''C0'', ''D0'', ''E0'', ''I1'', ''I2'', ''I3'', and ''I4'' are constants determined by the system and Rmin is the minimum value of the inside diameter of the polymeric capsule wall. There are several assumptions made by these and similar models, including but not limited to uniformity of monomer concentration, temperature, and film density, and second-order reaction kinetics.


Applications

Interfacial polymerization has found much use in industrial applications, especially as a route to synthesize conducting polymers for electronics. Conductive polymers synthesized by interfacial polymerization such as polyaniline (PANI), Polypyrrole (PPy), poly(3,4-ethylenedioxythiophene), and polythiophene (PTh) have found applications as chemical sensors, fuel cells, supercapacitors, and nanoswitches.


Sensors

PANI nanofibers are the most commonly used for sensing applications. These nanofibers have been shown to detect various gaseous chemicals, such as
hydrogen chloride The compound hydrogen chloride has the chemical formula and as such is a hydrogen halide. At room temperature, it is a colourless gas, which forms white fumes of hydrochloric acid upon contact with atmospheric water vapor. Hydrogen chloride ga ...
(HCl),
ammonia Ammonia is an inorganic compound of nitrogen and hydrogen with the formula . A stable binary hydride, and the simplest pnictogen hydride, ammonia is a colourless gas with a distinct pungent smell. Biologically, it is a common nitrogenous wa ...
(NH3), Hydrazine (N2H4), chloroform (CHCl3), and methanol (CH3OH). PANI nanofibers can be further fined-tuned by doping and modifying the polymer chain conformation, among other methods, to increase selectivity to certain gases. A typical PANI chemical sensor consists of a substrate, an electrode, and a selective polymer layer. PANI nanofibers, like other
chemiresistor A chemiresistor is a material that changes its electrical resistance in response to changes in the nearby chemical environment. Chemiresistors are a class of chemical sensors that rely on the direct chemical interaction between the sensing material ...
s, detect by a change in electrical resistance/conductivity in response to the chemical environment.


Fuel Cells

PPy-coated ordered
mesoporous A mesoporous material (or super nanoporous ) is a nanoporous material containing pores with diameters between 2 and 50 nm, according to IUPAC nomenclature. For comparison, IUPAC defines microporous material as a material having pores smaller ...
carbon (OMC) composites can be used in
direct methanol fuel cell Direct-methanol fuel cells or DMFCs are a subcategory of proton-exchange fuel cells in which methanol is used as the fuel. Their main advantage is the ease of transport of methanol, an energy-dense yet reasonably stable liquid at all environmental ...
applications. The polymerization of PPy onto the OMC reduces interfacial electrical resistances without altering the open mesopore structure, making PPy-coated OMC composites a more ideal material for fuel cells than plain OMCs.


Separation/Purification Membranes

Composite polymer films synthesized via a liquid-solid interface are the most commonly used to synthesize membranes for reverse osmosis and other applications. One added benefits of using polymers prepared by interfacial polymerization is that several properties, such as pore size and interconnectivity, can be fined-tuned to create a more ideal product for specific applications. For example, synthesizing a polymer with a pore size somewhere between the molecular size of hydrogen gas () and carbon dioxide () results in a membrane selectively-permeable to , but not to , effectively separating the compounds.


Cargo-loading Micro- and Nanocapsules

Compared to previous methods of capsule synthesis, interfacial polymerization is an easily modified synthesis that results in capsules with a wide range of properties and functionalities. Once synthesized, the capsules can enclose drugs, quantum dots, and other nanoparticles, to list a few examples. Further fine-tuning of the chemical and topological properties of these polymer capsules could prove an effective route to create drug-delivery systems.


See also

*
Polymerization In polymer chemistry, polymerization (American English), or polymerisation (British English), is a process of reacting monomer molecules together in a chemical reaction to form polymer chains or three-dimensional networks. There are many fo ...
* Interfacial polycondensation


References

{{Reflist Polymerization reactions Polymers