The present invention relates to disintegratable mesoporous silica materials, a method for producing the same, and uses thereof.

The present application relates to a modified graphene oxide or modified carbon nanotube and an antistatic composition including the same. The antistatic composition of the present application has advantages of an excellent adhesive property, improved surface roughness, mechanical strength, and improved electrical proper.

The present application relates to a conductive structure formed by connecting a modified graphene oxide or modified carbon nanotube with a conductive polymer, and an antistatic composition including the same. The antistatic composition of the present application has advantages of an excellent adhesive property, improved surface roughness, mechanical strength, and improved electrical properties.

Described herein is the preparation of solid acid fuel cell (SAFC) electrode materials suitable for intermediate temperature (200? C.-300? C.) oxygen reduction reaction (ORR) catalysis via anaerobic, in vacuo pyrolysis of metal-organic coordination polymer precursor materials with divalent metals (e.g. Pt or Pd) as nodes to form small, catalytically active nanoparticles inside a porous, electrically conductive carbonized framework.

The disclosure relates to an organic-inorganic hybrid (OIH) polymeric composition and related methods for forming the same. The disclosure also relates to a polymeric composition as disclosed herein and related methods for forming the same. The OIH polymeric composition and the polymeric composition can be formed by UV-irradiating a corresponding composition including a Michael-addition (MA) acceptor compound, a Michael-addition (MA) donor compound, a silane compound, when present, and a photo-latent base initiator to form a corresponding base catalyst and catalyze the reactions forming the networked polymer. The OIH polymeric composition and the polymeric composition can be used as a coating on any of a variety of substrates or as an interlayer in an additive manufacturing process.

The present disclosure relates to a hybrid nanoparticle comprising: (a) a metallic core or a metal oxide core, and (b) at least one dendron attached to the surface of the metallic core or metal oxide core, wherein the at least one dendron is derived from a compound complying with formula (I) or (II), which is described herein, as well as films containing such hybrid nanoparticles. Also described are compounds complying with formula (I) or (II) and their use in forming the hybrid nanoparticles of the present disclosure.

Provided is a molded article comprising a resin, wherein the resin comprises a methacrylic resin comprising a structural unit derived from a methacrylic acid ester and a structural unit derived from a silica particle having an average primary particle diameter of 1 nm or more and 50 nm or less and comprising at least one polymerizable functional group, and the molded article has an absolute value of degree of orientation in the thickness direction of 0.02 or more and satisfies the requirement (I): (I) When the free induction decay curve (X) obtained by measuring the molded article by a solid echo method at 150 C. using a pulse nuclear magnetic resonance measurement apparatus is approximated by the least square method using the formula (F1), the sum (B+C) of the component fractions of two components having different spin-spin relaxation times in the free induction decay curve (X) is 4% or more.

According to the present disclosure, a method of forming a pattern may include forming guide patterns on a substrate, wherein a trench is provided between the guide patterns, forming an organic-inorganic pattern including organic supramolecular structures in the trench, and annealing the organic-inorganic pattern, thereby aligning the dendrimer structures in parallel with one direction.

The present invention relates to a composite having exceptional heat resistance and durability that exhibits quick response characteristics when used in an electrochromic device; an electrochromic device in which the composite is used; and a method for producing said composite and device. This composite contains an organic/metallic hybrid polymer that contains an organic ligand and a metal ion coordinated to the organic ligand, and an ionic liquid. The organic/metallic hybrid polymer forms ionic bonds with the ionic liquid. This electrochromic device comprises a first electrode, an electrochromic layer containing the composite, an electrolyte layer, and a second electrode.

Apparatus, systems, and methods for communicating data between a controller and a multiplicity of field devices operating in a process plant are provided. The system includes distributed marshaling modules coupled by a head-end unit to I/O cards in communication with the controller. The distributed marshaling modules communicate with the field devices via respective electronic marshaling components converting signals between the field devices and the I/O cards. The distributed marshaling modules are coupled to the head-end unit by a ring communication architecture, such that the distributed marshaling modules may each be located relatively proximate to the field devices to which they are coupled.