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MAH가 폴리머에 접목되어 폴리머 복합체를 형성하는 메커니즘은 무엇인가요?

Because polymer composites have better mechanical, thermal, and electrical qualities than pure polymers, they are employed extensively in many different industries. Grafting maleic anhydride (MAH) onto the polymer matrix is a popular technique for enhancing the characteristics of polymer composites. The objective of this article is to present a comprehensive account of the process of grafting MAH onto polymers, encompassing the reaction mechanism, important variables affecting the grafting procedure, and the consequent impacts on the characteristics of polymer composites.

An overview of MAH grafting is as follows

Maleic anhydride (MAH) is a reactive substance that may graft, or create covalent connections, with polymers. MAH attaches itself to the polymer chains during the grafting procedure, creating new chemical bonds and functional groups. By adding new functions to the polymer matrix, this alteration boosts the composite’s overall performance and improves its compatibility with other materials.

Grafting technique: Generally, a two-step technique is used to graft MAH onto polymers.

a. Initiation: A radical initiator, such as peroxide or an azo chemical, produces free radicals during the initiation step of the grafting process. By removing hydrogen atoms from the polymer chains, these free radicals start the process and provide active sites for additional reactions.

b. Propagation: The produced polymer radicals interact with MAH molecules during the propagation process. The polymer radicals’ reactive sites react with the resultant maleic acid groups when the double bonds in MAH open. Grafting sites, where MAH units are covalently attached, are created on the polymer chains as a result of this process.
Based on the particular polymers used and the reaction circumstances used, there are a few different ways that the grafting reaction might happen: coordination grafting, ionic grafting, and free radical grafting.

 

Elements Affecting Grafting

A number of elements affect the grafting of MAH onto polymers, such as:

a. Polymer Type: An important factor in the grafting process is the polymer matrix type. Base polymers for grafting are frequently polymers containing reactive functional groups, such as polyethylene (PE), polypropylene (PP), or polystyrene (PS). The polymer backbone contains unsaturated bonds that act as attachment sites for MAH.

b. Reaction Conditions: The grafting efficiency is influenced by the reaction conditions, which include temperature, reaction duration, pressure, and solvent presence. Longer reaction periods and higher temperatures often encourage grafting, although extreme circumstances can cause the polymer matrix to degrade. The grafting reaction is also influenced by the solvent selection and how well it mixes with the polymers and reactants.

c. MAH Concentration: The amount of grafting is greatly influenced by the concentration of MAH in the reaction mixture. Greater grafting may occur from higher MAH concentrations, but excessive doses may cause cross-linking or agglomeration of the polymer chains.

d. Initiator Selection: The grafting reaction’s initiation stage is influenced by the radical initiator that is selected. The grafting efficiency and reaction control can be impacted by the varied reactivity of initiators and the varying lifetimes of the radicals they produce.

e. Reaction method: Depending on the particular polymers and reaction circumstances, the grafting method can change. For instance, in ionic grafting, the reaction is triggered by electrophilic or nucleophilic assaults, whereas in free radical grafting, the radical species removes hydrogen atoms from the polymer chains.

Impact on Polymer Composites

The subsequent polymer composites benefit from the grafting of MAH onto polymers in a number of ways.

a. Better Compatibility: MAH grafting makes the polymer matrix and additional components, including fillers or reinforcing agents, more compatible. As coupling agents, the grafted MAH molecules create robust chemical connections with the fillers or reinforcing agents. Better mechanical qualities, such as greater tensile strength, stiffness, and impact resistance, are the result of this better interfacial adhesion.

b. Improved heat Stability: By grafting MAH onto polymers, the resultant composites have better heat stability. By acting as heat stabilizers, the grafted MAH units lessen the polymer matrix’s deterioration at high temperatures. The polymer composites’ greater thermal stability increases their service life in a variety of applications and enables them to tolerate higher processing temperatures.

c. Modified Surface Properties: The surface characteristics of the resultant composites can be changed by grafting MAH onto polymers. Maleic acid groups offer more polar functionalities to the composite materials, which can enhance their adhesion, surface energy, and wetting behavior. Better bonding with coatings, adhesives, or other materials in multi-component systems is made possible by this alteration.

d. Tailored Properties: The properties of polymer composites can be customized to meet specific needs by adjusting the grafting parameters, such as the degree of grafting, the kind of polymer matrix, and the choice of fillers or reinforcing agents. The addition of MAH by grafting enables the composites’ mechanical, thermal, electrical, and even chemical properties to be customized, which makes them appropriate for a variety of uses.

One often used method to enhance the characteristics of polymer composites is the grafting of MAH onto polymers. MAH molecules are covalently attached to the polymer matrix by means of a two-step procedure that involves initiation and propagation. This process leads to improved compatibility, thermal stability, altered surface properties, and customized features in the composites. Numerous variables affect the grafting process: polymer type, reaction conditions, MAH concentration, initiator choice, and reaction mechanism. Comprehending the mechanism and contributing components of MAH grafting is crucial for the creation of sophisticated polymer composites that exhibit enhanced performance in a range of industrial settings.

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