Abstract: The present specification provides a di-polycyclic compound, and a polymer chain consisting of alternating electron donor compounds and electron acceptor compounds, which include the di-polycyclic compound.

Abstract: A process includes receiving information associated with a target molecule to be synthesized via a synthetic pathway engine user interface. The process also includes determining, using a synthetic pathway engine, synthetic pathway data for synthesis of the target molecule. In some cases, the process further includes generating a synthetic pathway report user interface that includes information associated with the synthetic pathway data. In other cases, the process further includes initiating automated synthesis of the target molecule using automated chemical synthesis equipment according to the synthetic pathway data.

Abstract: A multifunctionalized polycaprolactone polymer, a process for forming a multifunctionalized polycaprolactone polymer, and an article of manufacture comprising a material containing a multifunctionalized polycaprolactone polymer are disclosed. The multifunctionalized polycaprolactone polymer includes at least two functional groups. The process of forming the multifunctionalized polycaprolactone polymer includes forming a caprolactone monomer having at least two functional groups, and polymerizing the caprolactone monomer. Further, the article of manufacture includes a polycaprolactone polymer having at least two functional groups.

Abstract: A flame-retardant compound, a process for forming a flame-retardant compound, and an article of manufacture are disclosed. The flame-retardant compound includes a tetrazine moiety and at least one organophosphorus moiety. The process includes obtaining starting materials, which include a benzonitrile compound, a phosphorus-based compound, and hydrazine. The process also includes reacting the starting materials to form a tetrazine flame retardant. The article of manufacture includes a polymer and a flame-retardant compound having a tetrazine moiety and at least one organophosphorus moiety.

Abstract: A process of forming a resveratrol-based flame retardant small molecule with a phosphonate/phosphinate molecule that includes a chloride group and a terminal functional group.

Abstract: A bio-renewable flame-retardant compound is disclosed. The bio-renewable flame-retardant compound includes a cyclic structure formed in a reaction with a bio-renewable diene.

Abstract: Phosphate-based polyallyl isocyanurate cross-linker compounds, polyalkenyl isocyanurate cross-linker compounds, and a flame-retardant resin are disclosed. The phosphate-based polyallyl isocyanurate compound can have allyl phosphate substituents with variable functional groups. The phosphate-based polyallyl isocyanurate compound can have three or six allyl phosphate substituents. The brominated polyalkenyl isocyanurate compound can have brominated alkene-terminated substituents. The brominated alkene-terminated substituents can have variable functional groups and variable chain lengths. Both the phosphate-based polyallyl isocyanurate compounds and the brominated polyalkenyl isocyanurate compounds can be cross-linkers for epoxide polymers, acrylate polymers, vinylbenzene-terminated poly(phenyleneoxide) polymers, etc. The phosphate-based polyallyl isocyanurate compounds and the brominated polyalkenyl isocyanurate compounds can also be flame-retardant.

Abstract: A process for forming a flame retardant polymer, as well as the flame retardant polymer, are disclosed. A flame retardant polymer is a polymer that can be resistant to thermal degradation and/or thermal oxidation. A flame retardant polymer can be mixed or otherwise incorporated into a standard polymer to give flame retardancy to the standard polymer. The flame retardant polymers can include polycaprolactone functionalized with flame retardant substituents. The flame retardant substituents can include halides, substituted phosphoryl, and substituted phosphonyl.

Abstract: A flame retardant ultraviolet (UV) light stabilizing molecule includes a phosphorus-containing flame retardant moiety and a hydroxyphenyl-benzotriazole (HPB) moiety.

Abstract: A flame retardant lysine-based derivative, a process for forming a flame retardant lysine-based derivative, and an article of manufacture comprising a flame retardant lysine-based derivative are disclosed. The flame retardant lysine-derived molecule can be synthesized from a bio-based source, and can have at least one phosphoryl or phosphonyl moiety. A flame retardant proline-based derivative, a process for forming a flame retardant proline-based derivative, and an article of manufacture comprising a flame retardant proline-based derivative are also disclosed. The flame retardant proline-derived molecule can be synthesized from a bio-based source and can have at least one phosphoryl or phosphonyl moiety.

Abstract: An ultraviolet (UV) light stabilizing polymeric filler material includes a particle that is surface modified to include a hydroxyphenyl-benzotriazole (HPB) derivative functionality.

Abstract: A flame-retardant vanillin-derived small molecule, a process for forming a flame-retardant polymer, and an article of manufacture comprising a material that contains the flame-retardant vanillin-derived small molecule are disclosed. The flame-retardant vanillin-derived small molecule can be synthesized from vanillin obtained from a bio-based source, and can have at least one phosphoryl or phosphonyl moiety with phenyl, allyl, or thioether substituents. The process for forming the flame-retardant polymer can include reacting a diol vanillin derivative and a flame-retardant phosphorus-based molecule to form the flame-retardant vanillin-derived small molecule, and binding the flame-retardant vanillin-derived small molecule to a polymer. The material in the article of manufacture can be flame-retardant, and contain the flame-retardant vanillin-derived small molecules. Examples of materials that can be in the article of manufacture can include resins, plastics, adhesives, polymers, etc.

Abstract: A flame-retardant vanillin-derived cross-linker, a process for forming a flame-retardant polymer, and an article of manufacture comprising a material that contains the flame-retardant vanillin-derived cross-linker are disclosed. The flame-retardant vanillin-derived cross-linker can be synthesized from vanillin obtained from a bio-based source, and can have at least one phosphoryl or phosphonyl moiety with phenyl, allyl, epoxide, propylene carbonate, or thioether substituents. The process for forming the flame-retardant polymer can include reacting a diol vanillin derivative and a flame-retardant phosphorus-based molecule to form the flame-retardant vanillin-derived cross-linker, and binding the flame-retardant vanillin-derived cross-linker to a polymer. The material in the article of manufacture can be flame-retardant, and contain flame-retardant vanillin-derived cross-linkers. Examples of materials that can be in the article of manufacture can include resins, plastics, adhesives, polymers, etc.

Abstract: A flame-retardant vanillin-derived molecule, a process for forming a flame-retardant resin, and an article of manufacture comprising a material that contains the flame-retardant vanillin-derived molecule are disclosed. The flame-retardant vanillin-derived molecule can be synthesized from vanillin obtained from a bio-based source, and can have at least one phosphoryl or phosphonyl moiety with phenyl, allyl, epoxide, propylene carbonate, or thioether substituents. The process for forming the flame-retardant resin can include reacting a vanillin derivative and a flame-retardant phosphorus-based molecule to form the flame-retardant vanillin-derived molecule, and binding the flame-retardant vanillin-derived molecule to a resin. The flame-retardant vanillin-derived molecules can also be bound to polymers. The material in the article of manufacture can be flame-retardant, and contain the flame-retardant vanillin-derived molecules.

Abstract: A flame-retardant vanillin-derived monomer, a process for forming a flame-retardant polymer, and an article of manufacture comprising a material that contains flame-retardant vanillin-derived monomer are disclosed. The flame-retardant vanillin-derived monomer can be synthesized from vanillin obtained from a bio-based source, and can have at least one phosphoryl or phosphonyl moiety with phenyl, allyl, epoxide, or propylene carbonate substituents. The process for forming the flame-retardant polymer can include reacting a vanillin derivative and a flame-retardant phosphorus-based molecule to form the flame-retardant vanillin-derived monomer, and then polymerizing the flame-retardant vanillin-derived monomer. The material in the article of manufacture can be flame-retardant, and contain the flame-retardant vanillin-derived monomer. Examples of materials that can be in the article of manufacture can include resins, plastics, adhesives, polymers, etc.

Abstract: In an embodiment, a composition is provided that includes an indenofluorene moiety; an alkyl radical, an aryl radical, or a heteroaryl radical chemically bound to the indenofluorene moiety; and an electron donor moiety bound to the indenofluorene moiety. In another embodiment, a device is provided that includes compositions described herein. In another embodiment, a method of forming a donor-acceptor small molecule or a donor-acceptor copolymer is provided that includes forming an indenofluorene moiety; forming an electron donor moiety; and reacting the indenofluorene moiety with the electron donor moiety in a cross-coupling reaction.

Abstract: A process includes providing furan-2,5-dicarboxylic dimethyl ester (FDME), reacting the FDME with a Grignard reagent to form a bis-alkylketone furan having R groups selected from the group consisting of a C1-C20 linear alkyl chain, a C2-C24 branched alkyl chain, and a hydrogen atom. An additional process includes mixing a 3,4-dibrominated bis-alkylketone furan with potassium carbonate, and adding ethyl-mercaptoacetate to the mixture. This process also includes stirring the mixture to form a bis-alkyl-DTF diester fused ring structure, which is then brominated to form a dibromo-DTF compound.

Abstract: A thermo-gravimetric analysis system includes a chamber having an interior; and a sample crucible connected to and inside of the chamber, the sample crucible configured to hold a sample material. The system further includes a reference crucible connected to and inside of the chamber; and a metal organic framework (MOF) crucible connected to and inside of the chamber, separate from the sample crucible, the MOF crucible including an MOF material.

Abstract: A flame-retardant compound, a process for forming a flame-retardant compound, and an article of manufacture comprising a material containing a flame-retardant polyetheretherketone based polymer are disclosed. The flame-retardant compound includes two or more polyetheretherketone polymer chains and at least one flame-retardant aryl diamine cross-linker moiety, wherein the flame-retardant aryl diamine cross-linker moiety contains at least one flame-retardant functional group. The process includes selecting a flame-retardant aryl diamine, wherein the flame-retardant aryl diamine contains at least one flame-retardant functional group, selecting a polyetheretherketone polymer, and reacting the flame-retardant aryl diamine with the polyetheretherketone polymer to form a flame-retardant polyetheretherketone based polymer having flame-retardant aryl diamine cross-linkers, wherein the flame-retardant aryl diamine cross-linkers contain the at least one flame-retardant functional group.

Abstract: An article of manufacture. The article of manufacture includes a ring-opened lactide copolymer. The ring-opened lactide copolymer is formed in a process that includes reacting a functionalized lactide monomer with a BPA-derived monomer. The reaction forms a lactide copolymer, which is reacted to form the ring-opened lactide copolymer.