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Prepolymer

A prepolymer is a polymer or oligomer whose molecules are capable of entering further polymerization through reactive groups, thereby contributing more than one structural unit to at least one type of chain in the final polymer.^[1] In polymer chemistry, prepolymers function as stable, low molecular weight intermediates that are partially polymerized from monomers, often via polycondensation or ring-opening reactions, and can be converted into high molecular weight polymers through subsequent curing or chain extension processes.^[2] These intermediates typically exhibit viscosities suitable for handling and processing, such as in liquid form for epoxy resins or isocyanate-terminated variants, and are designed to remain reactive until intentionally polymerized, enabling controlled synthesis of diverse polymer networks.^[3] Prepolymers play a critical role in industrial applications, particularly in the formulation of polyurethanes, epoxies, and siloxane-based materials, where they serve as building blocks for products like adhesives, sealants, coatings, foams, and elastomers used in construction, automotive, and biomedical sectors.^[3] For instance, isocyanate-terminated polyurethane prepolymers, with NCO contents ranging from 5-25 wt%, react with polyols or amines to form flexible or rigid structures, while epoxy prepolymers like diglycidyl ether of bisphenol A (DGEBA) enable durable thermosets for structural composites.^[3] Their versatility also extends to advanced uses, such as moisture-curing systems in sealants and photopolymerizable formulations for microfabrication, highlighting their importance in tailoring material properties like mechanical strength, thermal stability, and adhesion.^[2]

Definition and Characteristics

Definition

A prepolymer is a low-molecular-weight polymer or oligomer formed by the partial reaction of monomers, serving as a stable intermediate that can undergo additional polymerization to form higher-molecular-weight polymers.^[1]^[3] This intermediate typically exhibits a degree of polymerization ranging from 2 to 20 monomer units, allowing it to remain processable while retaining the capacity for chain extension.^[4] The term "prepolymer" originated in polymer chemistry during the mid-20th century, with its first documented use in 1948, amid rapid advancements in both step-growth polymerization (pioneered by Wallace Carothers in the 1930s) and chain-growth processes that enabled controlled synthesis of macromolecules.^[5] These developments facilitated the creation of versatile intermediates for industrial applications, distinguishing prepolymers as key building blocks in modern polymer production.^[6] Prepolymers differ from monomers, which are single molecular units capable of initiating polymerization, by consisting of short oligomeric chains with multiple repeating units.^[7] Unlike fully polymerized materials, which have high molecular weights and minimal reactive sites, prepolymers preserve functional end-groups that enable further reactions, such as chain extension or cross-linking.^[1] Common examples of these reactive end-groups include isocyanate (-NCO), hydroxyl (-OH), epoxy, and carboxylic acid functionalities, which allow precise control over final polymer properties.^[8]^[9] For instance, isocyanate-terminated prepolymers play a crucial role in polyurethane formation by reacting with polyols to build extended networks.^[10]

Key Properties

Prepolymers are characterized by a molecular weight range typically between 500 and 5000 g/mol, which enables their use as low-viscosity intermediates in polymer synthesis and processing.^[11] This range ensures that prepolymers remain manageable in fluid form without excessive chain entanglement, facilitating efficient mixing and reaction control during subsequent curing steps. Their viscosity is generally low, often resulting in a liquid or semi-liquid state at room temperature, with values ranging from hundreds to several thousand centipoise depending on the specific formulation.^[12] For instance, isocyanate-terminated polyurethane prepolymers exhibit viscosities around 1200–2600 cps at ambient conditions, allowing for straightforward blending with curatives and additives.^[13] This rheological behavior is crucial for applications requiring pourability and homogeneity prior to final polymerization.^[14] The reactivity of prepolymers stems from their functional end-groups, such as isocyanate (-NCO) moieties, which enable controlled curing through reactions with active hydrogens in polyols, amines, or water.^[15] Thermal stability varies by type; for example, isocyanate-based prepolymers are particularly sensitive to moisture, where exposure leads to rapid hydrolysis and urea formation, potentially causing premature gelation if not managed.^[16] This end-group functionality, briefly tied to synthesis methods, allows precise tuning of curing kinetics for desired material performance.^[17] Prepolymers often display good solubility and compatibility with polar solvents, resins, and polyols due to the presence of polar groups like urethane linkages or ester functionalities, which promote intermolecular interactions.^[18] However, during final polymerization, these polar segments can drive phase separation, contributing to microphase morphology in the cured polymer.^[19] This dual behavior enhances processability in solution-based systems while influencing the ultimate material's domain structure.^[20] Storage stability is a designed feature of prepolymers, with shelf lives extending from several months to years when kept under inert conditions to minimize unwanted reactions at end-groups.^[21] For polyurethane prepolymers, unopened containers stored away from moisture and at controlled temperatures can maintain integrity for up to 12 months or more, preserving reactivity for later use.^[22] Proper inert atmosphere handling prevents degradation, ensuring consistent performance in industrial settings.^[14]

Synthesis Methods

General Approaches

Prepolymers are commonly synthesized through step-growth polymerization, which involves condensation reactions between bifunctional or multifunctional monomers, such as diols and diacids, where the reaction is intentionally halted at low conversions, typically 80-90%, to produce end-capped oligomers with controlled molecular weights rather than high polymers.^[23] This partial reaction yields species with reactive end groups suitable for subsequent curing or chain extension.^[3] In chain-growth polymerization, prepolymers are formed via radical or ionic initiation mechanisms that propagate short chains from monomers like vinyl compounds, with chain length regulated by limiting monomer feed rates or introducing terminators to quench growth early, resulting in oligomeric species with functional termini.^[23] For instance, radical polymerization of butadiene can produce hydroxyl-terminated oligomers when initiators and chain-transfer agents are employed to cap the ends.^[24] Oligomerization techniques further enable prepolymer formation by incorporating excess monofunctional agents during the reaction, which preferentially react with growing chain ends to cap them and prevent indefinite extension, thereby yielding stable, low-molecular-weight products with precise end-group functionality.^[25] This approach is particularly useful for creating telechelic prepolymers that maintain reactivity for later polymerization steps.^[3] The degree of polymerization in these processes is influenced by key factors including reaction time, temperature, and stoichiometry, such as deviations in monomer ratios that limit the extent of reaction.^[26] For step-growth mechanisms, shorter reaction times or lower temperatures slow the condensation, while non-stoichiometric ratios favor end-capping and reduce average chain length.^[3] A fundamental relation governing step-growth prepolymer synthesis is the number-average degree of polymerization, given by:

\bar{DP}_n = \frac{1}{1 - p}

where p represents the extent of reaction, maintained at low values (e.g., p < 0.9) to ensure the formation of oligomers rather than high polymers.^[26] This equation, derived from statistical considerations of random condensation, underscores the need for precise control to achieve desired prepolymer characteristics.^[26]

Specific Techniques

Controlled polycondensation is a key technique for synthesizing prepolymers, involving the heating of monomers under vacuum to facilitate the removal of byproducts such as water or alcohols, thereby driving the reaction toward oligomer formation without excessive chain extension.^[27] This method is particularly applied in the production of polyester prepolymers like poly(glycerol sebacate), where temperatures around 120-180°C are maintained to control the degree of polymerization.^[27] Reaction progress is monitored using gel permeation chromatography (GPC) to determine the molecular weight cutoff, ensuring the prepolymer remains at a targeted low molecular weight (typically 1,000-5,000 g/mol) suitable for subsequent curing.^[28] Ring-opening polymerization (ROP) is another important technique for prepolymer synthesis, particularly for producing telechelic oligomers from cyclic monomers. For example, tin(II) 2-ethylhexanoate (Sn(Oct)₂)-catalyzed ROP of ε-caprolactone at 100-150°C yields hydroxyl-terminated polycaprolactone prepolymers with molecular weights of 1,000-5,000 g/mol, suitable for further chain extension in polyurethane or biomedical applications.^[29] The reaction is controlled by initiator concentration and time to achieve desired chain lengths, often monitored by NMR or GPC. The blocked isocyanate approach enables the temporary inactivation of reactive isocyanate groups in prepolymers, allowing stable storage and controlled activation for later polymerization. In this method, isocyanate end-groups are reacted with blocking agents such as phenols or caprolactam to form a blocked adduct that halts further reaction at ambient conditions.^[30] Upon heating to 150-200°C, the blocking agent is released, regenerating the isocyanate for chain extension or crosslinking, which is commonly used in polyurethane prepolymer formulations to prevent premature curing during handling.^[30] This technique has been demonstrated effective in lignin-based polyurethane synthesis, where blocked prepolymers exhibit improved processability without compromising final material properties.^[30] Catalyst-mediated oligomerization is widely employed for polyurethane prepolymers, utilizing organotin compounds like dibutyltin dilaurate or amine catalysts such as triethylenediamine to accelerate the reaction between polyols and diisocyanates while maintaining precise control over chain length. These catalysts promote the formation of urethane linkages at moderate temperatures, typically 80-120°C, to form isocyanate-terminated oligomers with controlled functionality.^[31] The choice of catalyst influences reaction kinetics; for instance, tin catalysts favor gelling reactions, while amines balance foaming and curing in prepolymer stages.^[31] Temperature regulation is critical to avoid side reactions, ensuring the prepolymer viscosity remains manageable for downstream applications.^[32] Photopolymerizable prepolymers are designed for UV-curable systems by incorporating photoinitiators into acrylated oligomers, enabling rapid solidification upon exposure to ultraviolet light. These prepolymers are synthesized by functionalizing urethane or polyester backbones with acrylate end-groups, followed by the addition of photoinitiators like benzophenone or Irgacure series compounds that generate free radicals under UV irradiation (typically 200-400 nm).^[33] This approach forms oligomers with molecular weights around 1,000-10,000 g/mol, offering high reactivity and low volatility for coatings and adhesives.^[34] The technique allows for controlled curing depths and speeds, with conversion rates exceeding 90% in seconds, depending on initiator concentration and light intensity.^[33] A representative example of epoxy prepolymer synthesis involves the reaction of bisphenol A with epichlorohydrin under basic conditions, which is halted at the diglycidyl ether stage to yield a low-molecular-weight oligomer. This process typically occurs at 50-100°C with sodium hydroxide as a catalyst, forming the bisphenol A diglycidyl ether (DGEBA) prepolymer with epoxy equivalent weights of 170-190 g/eq.^[35] The reaction is controlled by monitoring epoxide content via titration, stopping at the desired oligomer length to prevent full polymerization into a high-molecular-weight resin.^[35] This prepolymer serves as a versatile intermediate for epoxy systems, with the glycidyl groups available for subsequent curing.^[36]

Types of Prepolymers

Isocyanate-Based Prepolymers

Isocyanate-based prepolymers are formed through the step-growth polymerization of polyols, such as polyether or polyester types, with diisocyanates like methylene diphenyl diisocyanate (MDI) or toluene diisocyanate (TDI), using an excess of the isocyanate to produce NCO-terminated oligomers.^[37]^[38] This reaction proceeds under anhydrous conditions to avoid side reactions with moisture, yielding prepolymers with free isocyanate end groups that enable subsequent chain extension or crosslinking.^[39] The excess isocyanate ensures the formation of urethane linkages while maintaining terminal NCO functionality for further reactivity.^[40] In polyurethane prepolymers, the NCO end-capping results in oligomers typically with molecular weights ranging from 1000 to 3000 g/mol, which are commonly employed in two-component (2K) systems for controlled curing.^[41] These prepolymers provide the foundational structure for polyurethane networks, where the NCO groups react with polyols or amines in the second component to form durable elastomers or coatings.^[42] Polyurea prepolymers follow a similar synthesis but incorporate amine chain extenders, such as diamines, which react rapidly with the NCO termini to yield urea linkages and enable faster curing rates compared to polyurethane systems.^[43] This enhanced reactivity stems from the higher nucleophilicity of amines versus alcohols, allowing for high-speed applications like spray coatings.^[44] Branching in these prepolymers can occur through secondary reactions forming allophanate or biuret linkages, where residual NCO groups react with existing urethane or urea bonds under catalytic conditions.^[45] The key reaction schematic is represented as:

\ce{HO-R-OH + 2 O=C=N-R'-N=C=O -> O=C=N-R'-NH-C(=O)-O-R-O-C(=O)-NH-R'-N=C=O}

with allophanate formation providing trifunctional nodes for improved mechanical properties.^[46] Variations include blocked prepolymers, where NCO groups are temporarily masked with blocking agents like caprolactam to create stable one-component (1K) systems that unblock upon heating for curing.^[47] Hydrophilized versions incorporate polyethylene oxide or ionic groups to render the prepolymers water-dispersible, facilitating eco-friendly aqueous formulations without compromising performance.^[48]^[49] The historical development of isocyanate-based prepolymers traces back to the 1930s, with Otto Bayer's invention of the polyaddition process in 1937 at IG Farben, but commercialization accelerated in the 1950s by Bayer (now Covestro) for flexible foams and coatings, marking the onset of widespread industrial adoption.^[50]^[41] This period saw the scaling of MDI and TDI production, enabling diverse applications in materials science.^[51]

Acid-Based Prepolymers

Acid-based prepolymers are formed through polycondensation reactions involving diacids, hydroxyacids, or their combinations with diols, resulting in oligomers typically terminated with carboxylic acid (COOH) or hydroxyl (OH) groups.^[52] These low-molecular-weight species (often 400–2000 g/mol) serve as intermediates for further polymerization, with the reaction proceeding via esterification under controlled conditions such as heating to 130–150°C in the presence of catalysts or under vacuum to remove byproducts like water.^[53] For instance, equimolar mixtures of diols like glycerol and diacids such as sebacic acid undergo melt polycondensation to yield viscous, bio-based oligomers suitable for subsequent curing.^[53] Lactic acid serves as a prominent hydroxyacid precursor for acid-based prepolymers, where it undergoes dimerization or controlled oligomerization to produce low-molecular-weight poly(lactic acid) (PLA) species, which are then used in ring-opening polymerization to form high-molecular-weight polymers.^[54] The key reaction involves the esterification of L-lactic acid monomers:

\ce{HO-CH(CH3)-COOH ->[polycondensation] [-O-CH(CH3)-CO-]_n -OH}

with the degree of polymerization (n) typically controlled to 5–10 units to maintain processability and avoid excessive viscosity.^[54] This step occurs at around 130°C, followed by depolymerization to lactide if needed, ensuring the prepolymers retain the stereochemistry of the starting L-lactic acid.^[54] Unique to acid-based prepolymers derived from such bio-sources are their inherent biodegradability, as ester linkages hydrolyze under aqueous conditions to yield non-toxic byproducts like water and CO₂, and the retention of chirality from L-lactic acid, which imparts specific crystallinity and mechanical properties to the final materials.^[54] Representative examples include poly(glycerol-co-sebacic acid), synthesized by polycondensation of glycerol and sebacic acid at 150°C to form OH- and COOH-terminated oligomers with molecular weights around 400–800 g/mol, valued for their elastomeric potential.^[53] Similarly, succinic acid-based prepolymers, derived from bio-sourced diacids, are prepared via polycondensation with diols like 1,3-propanediol, yielding linear polyester oligomers that enhance sustainability in polymer networks.^[55] These prepolymers offer advantages in renewable sourcing, as monomers like lactic and succinic acids are produced via microbial fermentation of biomass (e.g., corn starch or sugarcane), significantly reducing petroleum dependence and associated greenhouse gas emissions by up to 68% compared to fossil-based alternatives.^[54] This bio-based approach facilitates scalable, eco-friendly production while maintaining compatibility with condensation techniques for diverse applications.^[52]

Other Notable Types

Epoxy prepolymers, such as diglycidyl ethers of bisphenol A (DGEBA), are characterized by epoxide end-groups that facilitate crosslinking through ring-opening reactions with amines or other nucleophiles, forming robust thermoset networks.^[56] These materials are widely used in adhesives and composites due to their high thermal stability and mechanical strength post-curing.^[57] Acrylate prepolymers, including UV-curable oligomers like urethane acrylates, are synthesized via acrylation of polyols, typically involving the reaction of hydroxyl groups with acrylic derivatives to introduce polymerizable double bonds.^[58] A representative acrylation reaction is the esterification of an alcohol with acryloyl chloride:

R-OH + CH_2=CH-COCl \rightarrow R-O-CO-CH=CH_2 + HCl

This process yields oligomers that rapidly cure under ultraviolet light through free-radical polymerization, enabling applications in coatings and inks.^[59] Siloxane-modified prepolymers incorporate polydimethylsiloxane (PDMS) segments to impart enhanced flexibility and low-temperature performance, particularly in formulations for sealants where elasticity and weather resistance are critical.^[60] The siloxane backbone provides rotational freedom and hydrophobicity, improving durability in demanding environments.^[61] A key example among these prepolymers is polybutadiene-based variants, often featuring vinyl or hydroxyl end-groups, which serve as reactive modifiers for rubber toughening in thermoset matrices like epoxies.^[62] Hydroxyl-terminated polybutadiene (HTPB), for instance, integrates via chain extension or copolymerization, dispersing rubber particles that absorb energy during fracture to enhance impact resistance.^[63] Emerging types include bio-based prepolymers derived from renewable sources, such as epoxidized vegetable oils like soybean oil, which provide epoxy functionalities for sustainable thermosets with comparable mechanical properties to petroleum-derived analogs.^[64] Lignin-derived prepolymers, epoxidized to introduce reactive groups, offer additional biomass valorization pathways for high-performance resins.^[65] Recent advances as of 2025 include lignin-carbonate prepolymers for formaldehyde-free wood adhesives and self-healing polyurea prepolymers with improved mechanical robustness.^[66]^[44]

Applications

Industrial Applications

Prepolymers, particularly isocyanate-based polyurethane variants, are extensively utilized in industrial coatings and paints, where two-component (2K) systems provide enhanced durability, gloss, and weather resistance for automotive refinish and wood finishes.^[67] These formulations involve mixing the prepolymer with a polyol or hardener shortly before application, resulting in high-performance finishes that withstand abrasion and UV exposure in demanding environments like vehicle exteriors and furniture surfaces.^[68] In adhesives and sealants, one-component moisture-cure polyurethane prepolymers enable strong bonding of metals, plastics, and other substrates without the need for on-site mixing, curing through reaction with ambient humidity to form flexible, gap-filling seals.^[69] These systems are prized for their high initial tack and final bond strength, making them suitable for applications in construction joints, automotive assembly, and industrial sealing where vibration and temperature fluctuations are common.^[70] Polyurethane prepolymers also serve as key building blocks for rigid and flexible foams, where they react with water or blowing agents to produce expanded structures for thermal insulation in building panels and cushioning in upholstery or automotive seating.^[71] Rigid foams, derived from high-functionality prepolymers, offer superior compressive strength and low thermal conductivity for energy-efficient insulation, while flexible variants provide resilience and comfort in high-volume manufacturing.^[72] The global market for polyurethane prepolymers reached approximately USD 2.5 billion as of 2024, with significant growth driven by demand in the construction sector for insulation and sealing materials, reflecting their role in sustainable building practices.^[73] Processing typically involves on-site mixing of prepolymers with curatives such as polyols or amines, followed by ambient-temperature curing that allows for straightforward application in field conditions without specialized equipment.^[74] This approach contrasts with handling raw monomers by minimizing risks associated with reactive isocyanates. Key advantages include ease of handling due to lower reactivity and viscosity compared to pure monomers, alongside reduced volatile organic compound (VOC) emissions, which supports compliance with environmental regulations and improves worker safety in industrial settings.^[75]^[76]

Specialized Applications

Prepolymers play a pivotal role in advanced composite materials, particularly epoxy-based formulations integrated with carbon fiber reinforcements to enhance mechanical strength and durability in aerospace and automotive sectors. For instance, self-catalytic epoxy prepolymers have been developed to produce recyclable carbon fiber reinforced epoxy vitrimers, enabling degradation under mild conditions for fiber recovery.^[77] Similarly, bio-based epoxy prepolymers, such as those from Sperlu, allow for up to 80% renewable content in carbon fiber composites without compromising high-performance properties like tensile strength.^[78] In self-healing materials, microcapsule-embedded polyurethane (PU) prepolymers are employed to create anticorrosion coatings that autonomously repair damage. These systems incorporate microcapsules containing healing agents like isophorone diisocyanate, which release upon mechanical breach to reform the polymer network, significantly extending coating lifespan in harsh environments; for example, PU coatings with 5-10 wt% microcapsules demonstrate improved corrosion resistance via electrochemical impedance spectroscopy.^[79] Such innovations reduce maintenance needs in marine and industrial settings by providing barrier properties and active healing mechanisms.^[80] Biomedical applications leverage acid-based prepolymers, notably lactic acid-derived oligomers, to form polylactic acid (PLA) structures for drug delivery scaffolds and biodegradable implants. PLA scaffolds fabricated from these prepolymers enable controlled release of therapeutics over weeks to months, supporting tissue regeneration due to their tunable degradation rates matching biological healing timelines.^[81] In implants, PLA's biocompatibility facilitates applications like orthopedic fixation devices, where hydrolytic breakdown into non-toxic byproducts like lactic acid minimizes long-term surgical interventions.^[82] These prepolymers' biodegradability, as detailed in acid-based formulations, ensures resorption without residue, though integration with bioactive agents enhances cellular adhesion.^[83] In electronics, siloxane prepolymers contribute to flexible encapsulants and thermal interface materials by providing low-modulus, high-thermal-conductivity networks. Epoxy-modified siloxane prepolymers yield composites ideal for protecting flexible circuits against thermal stress and moisture while maintaining electrical insulation.^[84] For thermal management, siloxane-based pads with alumina fillers achieve up to 36% higher conductivity than pure matrices, supporting heat dissipation in wearable and power electronics without rigidity.^[85] These materials' elasticity accommodates substrate deformation, enhancing device reliability in dynamic applications.^[86] Photopolymerizable acrylate prepolymers serve as core components in 3D printing resins for rapid prototyping, enabling high-resolution structures via vat photopolymerization techniques like stereolithography. These prepolymers, often oligomers with acrylate end-groups, cure under UV light to form mechanically tunable parts with flexural strengths adjustable up to approximately 45 MPa by varying formulations, facilitating custom prototypes in engineering and biomedical prototyping.^[87] Their low viscosity and fast curing rates support layer-by-layer fabrication of complex geometries, such as microfluidic devices, with minimal post-processing shrinkage.^[88] Sustainability efforts incorporate bio-based prepolymers from lignin to develop eco-friendly coatings that reduce reliance on fossil fuels. Lignin-derived polyurethane prepolymers enable coatings with over 90% biomass content, offering UV resistance and antimicrobial properties while lowering volatile organic compound emissions compared to petroleum-based alternatives.^[89] These formulations, such as lignin-alkyd or epoxy resins, provide durable barriers for wood and metal substrates, with fire-retardant enhancements from lignin's aromatic structure, promoting circular economy principles in surface protection.^[90] Despite these advances, specialized applications face challenges in ensuring biocompatibility and recyclability. In biomedical contexts, prepolymers must undergo rigorous testing to mitigate inflammatory responses, as incomplete degradation can lead to cytotoxicity, necessitating surface modifications for enhanced cell integration.^[91] For electronics and composites, recyclability hurdles include separating reinforcements from cured networks, though vitrimer-based prepolymers address this by enabling reprocessing at elevated temperatures without mechanical loss.^[92] Overall, scaling bio-based variants while maintaining performance remains key to overcoming environmental and regulatory barriers.^[93]

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A hydrophilic, water-soluble or water-dispersible polyisocyanate, comprising 4% to 27% by weight of isocyanate groups, said groups being aliphatically ...
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Bayhydur® water-dispersible aliphatic hydrophilically modified polyisocyanate crosslinkers from Covestro are extremely versatile.
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Polyurethanes: An Introduction | ACS Symposium Series
Aug 8, 2025 · 1.1 Historical Development. Otto Bayer created the first PU around eighty-seven years ago, in 1937. To compete with nylon fibers, Bayer set ...
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Mar 17, 2017 · Bayer (1902 - 1982) developed the novel polyisocyanate-polyaddition process. The basic idea which he documents from March 26, 1937, relates ...
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Synthesis, Properties and Applications of Biodegradable Polymers ...
Most of these polymers can be prepared from biobased diols and dicarboxylic acids such as 1,4-butanediol, succinic acid and carbohydrates.
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Synthesis of Prepolymers of Poly(glycerol-co-diacids) Based on ...
Apr 26, 2023 · In this study, poly(glycerol-co-diacids) prepolymers were produced using different ratios of glycerol (G), sebacic acid (S), and succinic acid (Su).
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Poly(lactic Acid): A Versatile Biobased Polymer for the Future with ...
This review summarizes monomer synthesis of lactic acid and lactide, new synthesizing methods (melt polycondensation and ring opening polymerization) in PLA ...
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Fully bio-based poly(propylene succinate) synthesis and ...
In this work, linear bio-based polyester polyols were prepared with the use of succinic acid and 1.3-propanediol (both with natural origin).
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Network Formation and Physical Properties of Epoxy Resins for ...
Jun 9, 2022 · Two epoxy polymers were prepd. by curing the diglycidyl ether of bisphenol A (DGEBA) epoxy resin with two hardeners: the ethylenediamine ...
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Sep 17, 2020 · The most prominent epoxy resin is the diglycidyl ether of BPA (DGEBA), which is ... epoxide group, and thus facilitating crosslinking [27, 28].
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Synthesis and Properties of UV-Curable Polyfunctional ...
Jul 23, 2019 · A novel UV-curable polyurethane acrylate (PUA) oligomer was synthesized by modifying cardanol with a polyfunctional acrylate precursor.
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[PDF] Synthesis, Characterization and Surface Modification of ...
Second,. Page 9. viii permanently hydrophilic silicones are obtained by grafting PEO-PDMS copolymers to cross-linked silicones via siloxane equilibration.
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Well-Architectured Poly(dimethylsiloxane)-Containing Copolymers ...
The incorporation of a polysiloxane block in another polymer is also utilized to modify the properties of the other polymer, making its surface more hydrophobic ...
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Synthesis and Properties of Epoxy Resin Modified with Novel ...
An epoxy terminated polybutadiene (ETPB) was synthesized and utilized to enhance the toughening of an epoxy system, in both bulk and coating states. In the ...
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Effect of Solvent and Functionality on the Physical Properties of ...
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Rigid-and-Flexible, Degradable, Fully Biobased Thermosets from ...
Feb 14, 2023 · Fully biobased epoxy thermosets were prepared from MGL, citric acid (CA), and epoxidized soybean oil (ESO) with the assistance of ethanol.
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Epoxidized lignin derivatives as bio-based cross-linkers used in the ...
Feb 8, 2018 · Epoxidized linseed, soybean, and castor oils are among the most exploited oils in resin formulations (Park et al. 2004; Supanchaiyamat et al.
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[PDF] Polyisocyanates and Prepolymers - Covestro Solution Center
Sep 7, 2021 · Prepolymers based on aliphatic diisocyanates display good weather stability and are color-stable. These unique properties are important for ...
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Recent developments in aqueous two-component polyurethane (2K ...
In the field of aqueous 2K-PUR systems, Bayer is working to develop raw materials for use in automotive finishing, industrial metal coating and wood finishing.
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One-Component Polyurethane Adhesives and Sealants - Bostik
One-component polyurethanes are elastic adhesives/sealants that don't need pre-mixing, reacting with moisture, and used for bonding and sealing.
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May 22, 2025 · Moisture-cure polyurethane adhesives cure with humidity, are single-component, perform well in extreme conditions, and bond dissimilar ...
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Huntsman Polyurethanes :: Huntsman Corporation (HUN)
Nov 3, 2025 · Polyurethane (PU) is one of the most versatile polymers available and can be used to create rigid and flexible foams, thermoplastic urethanes ( ...
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Polyurethane Prepolymer (PPU) Market Size, Competitive Trends ...
Rating 4.4 (62) Polyurethane Prepolymer (PPU) Market size is estimated to be USD 2.5 Billion in 2024 and is expected to reach USD 4.1 Billion by 2033 at a CAGR of 6.5% from ...
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[PDF] Role of Moisture in Processing, Application, and Cure of 2K ...
Such products are usually applied with two component mixing equipment, wherein the polyol component and polyisocyanate hardener component are fed separately ...
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[PDF] New Polyurethane Prepolymers for Ultra-Low VOC Plural ...
These prepolymers offer the advantages of a narrow molecular weight distribution, rapid viscosity reduction with increasing temperature or solvent level, very ...
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Oct 24, 2023 · They are non-toxic and do not emit volatile organic compounds (VOCs). Furthermore, they can be used to produce products that have a low chemical ...
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[PDF] Carbon Fiber Reinforced Epoxy Vitrimer - OSTI.GOV
In this work, we introduced a viable method to develop a readily recyclable CFRP based on epoxy vitrimer. First, we designed a self-catalytic epoxy prepolymer ...
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Sperlu prepolymers enable high-performance epoxy resins with up ...
Aug 29, 2023 · Sperlu prepolymers enable high-performance epoxy resins with up to 80% bio-based content. Spero Renewables has received funding to further scale ...
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Autonomous-healing and smart anti-corrosion mechanism of ...
May 11, 2022 · The self-healing and smart anti-corrosion behavior of a polyurethane coating enhanced with micro-sized capsules have been investigated.
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Improving self-healing performance of polyurethane coatings using ...
The best healing and corrosion performance was achieved for the coating with 1 wt % nanoclay and 5 or 10 wt % microcapsules as a result of barrier properties of ...
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Promising Role of Polylactic Acid as an Ingenious Biomaterial ... - NIH
Jan 4, 2023 · Polylactic acid has a notable reputation in many biomedical applications due to its bioresorbability and biocompatibility with human tissues.Missing: prepolymers | Show results with:prepolymers
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Review Medical applications and prospects of polylactic acid materials
Dec 20, 2024 · This review summarizes current applications of the PLA-based biomaterials in drug delivery systems, orthopedic treatment, tissue regenerative engineering, and ...Missing: prepolymers | Show results with:prepolymers
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PLGA Implants for Controlled Drug Delivery and Regenerative ...
PLGA is a leading biodegradable polymer for implantable systems due to its tunable degradation rate and drug release profile. These properties can be tailored ...
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Epoxy-based siloxane composites for electronic packaging: Effect of ...
Jun 16, 2022 · Epoxy-based siloxane composites improve thermal, mechanical, and insulating properties. Branch siloxane is hard and low insulating, while ...Missing: prepolymers | Show results with:prepolymers
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Siloxane Composite Thermal Pads for Thermal Interface Materials
Feb 16, 2024 · This study provides guidelines for fabricating Al 2 O 3 –siloxane composite thermal pads with high thermal conductivity in the field of thermal interface ...Missing: prepolymers | Show results with:prepolymers
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Functional PDMS Elastomers: Bulk Composites, Surface ...
Oct 9, 2023 · PDMS-based composites are promising candidates for thermal interface materials due to the high mechanical flexibility, electrical insulation, ...
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Mechanically tunable resins based on acrylate-based resin for ...
Nov 21, 2022 · This study investigates a newly formulated resins as an alternative 3D printing materials with tunable mechanical properties to expand the potential ...
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Photopolymerization in 3D Printing | ACS Applied Polymer Materials
1. (Meth)acrylate-Based Photocurable Systems. (Meth)acrylate monomers/oligomers are frequently used for 3D photopolymerization processes which proceed via a ...
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Tuning the Properties of Biobased PU Coatings via Selective Lignin ...
Apr 21, 2023 · This study provides a powerful strategy for the production of PU coatings with tailored properties and high (>90%) biomass content.Missing: prepolymers | Show results with:prepolymers
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LIGNICOAT project: Sustainable COATings based on LIGNIn resins ...
May 10, 2021 · LIGNICOAT aims to provide new synthetic routes to obtain bioresins 'à la carte' (PUD, ALKYD and EPOXY) based on lignin intermediates.
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Biomedical Polymers in Flexible Electronics for Healthcare
Oct 24, 2025 · Biocompatibility remains a primary concern, as long-term implantation of polymer-based devices can trigger foreign body responses, inflammation, ...Missing: prepolymers | Show results with:prepolymers
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Recent advances and challenges in recycling and reusing ...
Sep 6, 2022 · In this article, we will review the recent advances in recycling and reusing biomedical materials, discuss challenges associated with each practice, and ...Missing: prepolymers biocompatibility electronics
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Recycling Technologies for Biopolymers: Current Challenges and ...
Sep 30, 2024 · In this article, we review recycling as a viable solution to improve the sustainability of biopolymers, emphasizing the current types and technologies employed ...