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 of forming a gluten-derived flame retardant material includes forming an amine-functionalized flame retardant molecule that includes an aryl halide group and a phosphorus moiety. The process also includes chemically reacting the amine-functionalized flame retardant molecule with a gluten protein under transamidation conditions to bind the phosphorus moiety to a first portion of the gluten protein. The process further includes initiating a cross-coupling reaction between the aryl halide group and amine group of a second portion of the gluten protein to form a gluten-derived flame retardant material.

Abstract: An organic semiconducting donor-acceptor (D-A) small molecule, as well as a semiconductor device that can incorporate the D-A small molecule, are disclosed. The D-A small molecule can have electron deficient substituents and R group substituents that can be C1-C20 linear alkyl chains, C2-C24 branched alkyl chains, hydrogen atoms, etc. The D-A small molecule can be can be synthesized in a reaction between a dithienofuran (DTF) core monomer and an electron deficient monomer. Additionally, the D-A small molecule can be part of an organic semiconducting copolymer. A semiconductor device that can incorporate the D-A small molecule in a photoactive layer is also disclosed herein. Additionally, 3,4-dibrominated furan compound that can, in some embodiments, be a precursor for the D-A small molecule is disclosed. The 3,4-dibrominated furan compound can be synthesized in a reaction involving a furan-2,5-dicarboxylic dimethyl ester (FDME), which can have a bio-renewable precursor.

Abstract: An encapsulated sunscreen composition that includes a polymeric shell material having a substantially spherical geometry. The shell material is a polymeric composition that includes a photosensitizer chemically bound to the polymeric composition. The polymeric shell material has a minimum diameter of 100 nm.

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: 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 apparatus is provided with a component configured to be operatively coupled to an interface. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to a thermal event that meets or exceeds a first temperature the resilient material is subject to undergo a state change to a second state. The state change includes a physical transformation of the interface, and includes a position change of the component.

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: A process of manufacturing a multiple-layer printed circuit board includes selectively applying a dielectric resin to a region of a circuitized core layer. The process also includes partially curing the dielectric resin prior to performing a lamination cycle to form the multiple-layer printed circuit board that includes the circuitized core layer.

Abstract: A photo-absorbing composition having a structure from the group consisting of wherein DASM is a small molecule comprising one or more electron donor portions and one or more electron acceptor portions and NG is a nanographene structure, and m, n, and o are integers greater than or equal to 1.

Abstract: A process of manufacturing a layup for multiple-layer printed circuit board manufacturing is formed according to a process that includes selectively applying a dielectric resin to a high resin demand region of a circuitized core layer without applying the dielectric resin to another region of the circuitized core layer. The process also includes partially curing the dielectric resin prior to performing a lamination cycle to form the multiple layer printed circuit board that includes the circuitized core layer within the high resin demand region. The process further includes forming a layup that includes a layer of pre-impregnated (prepreg) material adjacent to the partially cured dielectric resin within the high resin demand region of the circuitized core layer.

Abstract: A stubless via in printed wiring board may comprise one or more core layers. At least one core layer may be circuitized by including a copper trace and at least two other core layers may include copper laminations. The stubless via may further comprise one or more prepreg layers. The prepreg layers may be alternatively stacked between the core layers. the stubless via may further comprise a via. the via may be drilled through each of the alternatively stacked prepreg layers and core layers, exposing internal portions of the prepreg layers and core layers drilled through.

Abstract: A PWB may be drilled forming a via. The via may expose one or more internal portions of a core layer, a prepreg layer, and an anti-plate coating. A seed material may then be applied from a top portion of the PWB to the via, forming a seed layer in the via, the seed material not adhering to the anti-plate coating. Electroless metal may then be applied from the top portion of the PWB to the via, forming an electroless plate layer that adheres to the seed layer. Electrolytic copper may then be applied from the top portion of the PWB to the via, forming a copper layer that adheres to the electroless plate layer. A bottom portion of the electroless plate layer may then be removed.

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: 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. 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 organic semiconducting donor-acceptor (D-A) small molecule, as well as a semiconductor device that can incorporate the D-A small molecule, are disclosed. The D-A small molecule can have electron deficient substituents and R group substituents that can be C1-C20 linear alkyl chains, C2-C24 branched alkyl chains, hydrogen atoms, etc. The D-A small molecule can be can be synthesized in a reaction between a dithienofuran (DTF) core monomer and an electron deficient monomer. Additionally, the D-A small molecule can be part of an organic semiconducting copolymer. A semiconductor device that can incorporate the D-A small molecule in a photoactive layer is also disclosed herein. Additionally, 3,4-dibrominated furan compound that can, in some embodiments, be a precursor for the D-A small molecule is disclosed. The 3,4-dibrominated furan compound can be synthesized in a reaction involving a furan-2,5-dicarboxylic dimethyl ester (FDME), which can have a bio-renewable precursor.

Abstract: A process of forming a non-halogenated flame retardant hindered amine light stabilizer (HALS) impact modifier is disclosed. The process includes co-polymerizing a mixture of monomers that includes an acryloyl-functionalized 2,2,6,6-tetramethylpiperidine (TMP) monomer, a styrene monomer, a butadiene monomer, and a phosphorus-functionalized monomer to form a co-polymer. The process also includes forming a non-halogenated flame retardant HALS impact modifier by converting a piperidine amide bridge of the co-polymer to a nitroxyl radical. The process further includes utilizing the nitroxyl radical to directly bond the non-halogenated flame retardant HALS impact modifier to a polymeric material to form an impact resistant, flame retardant, light-stabilized polymeric material.

Abstract: A flame retardant sugar-derived molecule, a process for forming a flame retardant sugar-derived molecule, and an article of manufacture comprising a flame retardant sugar-derived molecule are disclosed. The flame retardant sugar-derived molecule can be synthesized from arabitol, xylitol, arabic acid, or xylonic 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-derived molecule can include reacting arabitol, xylitol, arabic acid, or xylonic acid and a flame retardant phosphorus-based molecule to form the flame retardant sugar-derived molecule.

Abstract: A levoglucosan-based flame retardant compound, a process for forming a flame retardant polymer, and an article of manufacture comprising a material that contains a levoglucosan-based flame retardant polymer are disclosed. The levoglucosan-based flame retardant compound has phosphorus-based flame retardant functional groups. The process for forming the flame retardant polymer includes providing a phosphorus-based flame retardant molecule, providing levoglucosan, chemically reacting the phosphorus-based flame retardant molecule and the levoglucosan derivative to form a levoglucosan-based flame retardant compound, and incorporating the levoglucosan-based flame retardant compound into a polymer to form the levoglucosan-based flame retardant polymer.