Abstract: Embodiments of the present disclosure generally provide compositions and methods related to articles that display reversible photoresponsive behavior.

Abstract: A method and a system for detecting defects in plated-through hole by partially submerging a printed circuit board in a fluid bath. The method includes partially submerging a printed circuit board on a first side and measuring a capillary height difference within a plated-through hole and the surrounding fluid bath. The method further includes partially submerging the printed circuit board on a second side and measuring a second capillary height difference within the plated-through hole and the surrounding fluid bath. The method also includes comparing the measured values with predetermined values to determine the quality of the plated-through hole.

Abstract: Methods and compositions related to subsurface modified silica materials are described. The silica materials include silicon- and carbon-containing groups covalently bonded to the silicon-oxygen matrix. The silica materials have tunable permeability, modulus, hardness, flexibility, and elongation. The silica materials are suitable for use as polymer fillers and as functional coatings.

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 polybrominated flame-retardant compound, a process for forming a flame-retardant material, and an article of manufacture are disclosed. The polybrominated flame-retardant compound includes a cyclododecane moiety, at least two bromo groups, and at least one substituent having a reactive functional group. The process includes forming a polybromocyclododecane (PBCD) compound having at least one reactive functional group and incorporating the PBCD compound into a polymer in a process that includes covalent binding of the PBCD compound. The article of manufacture includes a flame-retardant material that comprises a polymer with a covalently-bound PBCD compound.

Abstract: A method for forming a photosensitizer product that is resistant to absorption by living tissue that may include binding a photosensitizer compound with an oxide-containing particle to provide the photosensitizer derivative having a microscale size, and mixing the photosensitizer derivative into a lotion. The microscale size of the photosensitizer derivative obstructs absorption by cell tissue.

Abstract: A flame retardant composition and a method of making a flame retardant composition is provided. In an embodiment, the method includes reacting a phosphazene material with an acrylamide monomer material to form a functionalized phosphazene material; initiating a polymerization reaction on a reaction mixture comprising a functionalized phosphazene material and one or more monomers to form a first impact-modified phosphazene material; and reacting the first impact-modified phosphazene material with a poly(dichlorophosphazene) monomer material, and a reactant selected from the group consisting of R1OH, HNR2R3, or a combination thereof, to form a second impact-modified phosphazene material.

Abstract: A flame-retardant compound, a process for forming a flame-retardant polymer, and an article of manufacture are disclosed. The flame-retardant compound includes at least one muconic acid moiety and at least one phosphorus-based moiety. The process for forming the flame-retardant polymer includes obtaining a muconic acid compound, obtaining a muconic acid compound, reacting the muconic acid compound with the phosphorus compound to form a flame-retardant compound, and incorporating the flame-retardant compound into a polymer. The article of manufacture comprises a material that contains a flame-retardant compound derived from muconic acid.

Abstract: A limonene-based flame-retardant compound, a method of making a flame-retardant polymer, and an article of manufacture comprising a material that includes a limonene-based flame-retardant compound are provided. In an embodiment, the method includes forming a limonene-based derivative; forming a phosphorus-based flame-retardant molecule; reacting the limonene-based derivative with the phosphorus-based flame-retardant molecule to form a limonene-based flame-retardant compound; and forming a flame-retardant polymer from the limonene-based flame-retardant compound. In some embodiments, the limonene-based flame-retardant compound has variable functionality including vinyl, epoxide, methylene bridges, and thioethers.

Abstract: An apparatus, method, and article of manufacture for transferring fluid contained in a syringe. The apparatus includes an airlock component having a cylindrical body with a first end, a second end, and a hollow tube disposed between the first end and the second end. An annular opening is located at the first end of the cylindrical body. The hollow tube includes a gas inlet aperture and a gas outlet aperture. The hollow tube also includes an inwardly-facing airtight material coupled to the interior surface of the hollow tube, and a septum coupled to the second end of the cylindrical body. The method includes transferring fluid from one container to a second container using the apparatus. The article of manufacture includes the apparatus, a syringe, and a needle.

Abstract: A microcapsule, a method, and an article of manufacture. The microcapsule includes a degradable shell and a polymerizing agent encapsulated by the degradable shell. The method includes selecting a polymerizing agent, encapsulating the polymerizing agent in a degradable shell, and rupturing the degradable shell by exposure to an energy source, such as a laser, a UV radiation source, and/or a heat source. The article of manufacture includes a microcapsule having a degradable shell and a polymerizing agent encapsulated by the degradable shell.

Abstract: A process of forming a flame retardant material is disclosed. The process includes forming a functionalized polybrominated diphenyl-based flame retardant compound having the following structural formula: In the structural formula, X corresponds to a functional group. The process also includes forming a flame retardant material by covalently bonding the functionalized polybrominated diphenyl-based flame retardant compound into a material using the functional group.

Abstract: A microcapsule encapsulates a payload agent, the microcapsule having a microcapsule shell material that is rupturable (e.g., to release the encapsulated payload agent) via a retro-dimerization reaction.

Abstract: An impact resistant polyhexahydrotriazine polymer, processes of forming an impact resistant polyhexahydrotriazine polymer, and an article of manufacture comprising an impact resistant polyhexahydrotriazine polymer are disclosed. The impact resistant polyhexahydrotriazine polymer includes at least one hexahydrotriazine group and at least one chain comprising an allylic portion and a styrenic portion. Variations in the chain control properties of the impact resistant polymer. The process of forming the impact resistant polyhexahydrotriazine polymer includes reactions between formaldehyde and at least two classes of monomer that form hexahydrotriazine groups and impact resistant chains. Adjusting relative monomer concentrations controls properties of the impact resistant polyhexahydrotriazine polymer. The article of manufacture contains a material that has an impact resistant polymer.

Abstract: A flame retardant levulinic acid-based compound, a process for forming a levulinic acid-based flame retardant polymer, and an article of manufacture comprising a material that contains a flame retardant levulinic acid-based polymer are disclosed. The flame retardant levulinic acid-based compound has variable moieties, which include phenyl-substituted and/or R functionalized flame retardant groups. The process for forming the flame retardant polymer includes forming a phosphorus-based flame retardant molecule, forming a levulinic acid derivative, chemically reacting the phosphorus-based flame retardant molecule and the levulinic acid derivative to form a flame retardant levulinic acid-based compound, and incorporating the levulinic acid-based flame retardant compound into a polymer to form the flame retardant polymer.

Abstract: A ladder tetrazine polymer is disclosed.

Abstract: An article of manufacture includes a three-dimensional (3D) printed object for chemical reaction control. The 3D printed object includes a chemical reactant to be released to control a chemical reaction according to a chemical reactant release profile. The chemical reactant release profile is determined based on a shape of the 3D printed object.

Abstract: A process a process of forming a non-halogenated flame retardant (FR) hindered amine light stabilizer (HALS) cross-linker is disclosed. The process includes forming a mixture that includes a first molecule having a hindered amine group. The first molecule corresponds to a functionalized 2,2,6,6-tetramethylpiperidine (TMP) molecule. The process also includes forming the non-halogenated FR HALS cross-linker via a chemical reaction of the first molecule a second molecule. The second molecule includes a phosphoryl group, a chloride group, and at least one cross-linkable (CL) moiety.

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 flame-retardant sugar derivative, a process for forming a flame-retardant sugar derivative, and an article of manufacture comprising a flame-retardant sugar derivative are disclosed. The flame-retardant sugar derivative can be synthesized from sorbitol, gluconic acid, or glucaric acid obtained from a bio-based source, and can have at least one phosphoryl or phosphonyl moiety. The process for forming the flame-retardant sugar derivative can include reacting sorbitol, gluconic acid, or glucaric acid and a flame-retardant phosphorus-based molecule to form the flame-retardant sugar derivative.