公开(公告)号：US20180223182A1

公开(公告)日：2018-08-09

申请号：US15885309

申请日：2018-01-31

Applicant: NANOSYS, INC.

Inventor： James Kundrat ,  David Olmeijer

IPC: C09K11/02 ,  C09K11/70 ,  C09K11/88 ,  C09D5/22 ,  C09D183/08

CPC classification number: C09K11/025 ,  B82Y20/00 ,  B82Y40/00 ,  C08K3/30 ,  C08K3/32 ,  C08K2201/011 ,  C09D5/22 ,  C09D183/08 ,  C09K11/02 ,  C09K11/70 ,  C09K11/883 ,  Y10S977/774 ,  Y10S977/783 ,  Y10S977/892 ,  Y10S977/95

Abstract: The present invention provides nanostructure compositions and methods of producing nanostructure compositions. The nanostructure compositions comprise a population of nanostructures, an aminosilicone polymer, an organic resin, and a cation. The present invention also provides nanostructure films comprising a nanostructure layer and methods of making nanostructure films.

公开(公告)号：US20180223107A1

公开(公告)日：2018-08-09

申请号：US15749237

申请日：2016-07-27

Applicant: PIXELLIGENT TECHNOLOGIES LLC

Inventor： Selina MONICKAM ,  Darryl PETERS ,  Gregory COOPER ,  Zhiyun CHEN

IPC: C09D5/33 ,  C09D135/02 ,  H01L51/52 ,  H01L51/00 ,  C09D7/40 ,  C09C3/08

CPC classification number: C09D5/004 ,  C08K3/22 ,  C08K9/04 ,  C08K9/06 ,  C08K2003/2244 ,  C08K2201/005 ,  C08K2201/011 ,  C09C3/08 ,  C09D4/00 ,  C09D5/00 ,  C09D7/62 ,  C09D7/67 ,  C09D7/68 ,  C09D7/69 ,  C09D135/02 ,  H01L51/004 ,  H01L51/0043 ,  H01L51/5268 ,  H01L2251/303

Abstract: The present disclosure provides a high refractive index acrylic formulation embedded with sub-10 nm metal oxide nanocrystals. The formulation is ideal for high refractive index, high transparency coating for a variety of optical applications including OLED lighting.

公开(公告)号：US10043598B2

公开(公告)日：2018-08-07

申请号：US14236142

申请日：2012-07-27

Applicant: Jin Kawakita ,  Toyohiro Chikyo

Inventor： Jin Kawakita ,  Toyohiro Chikyo

IPC: H01B1/12 ,  C08G61/12 ,  C08G73/02 ,  H01L51/00 ,  H05K1/09 ,  H05K3/10 ,  C08K3/08 ,  H01L51/42

CPC classification number: H01B1/124 ,  C08G61/124 ,  C08G61/126 ,  C08G73/0266 ,  C08G2261/3221 ,  C08G2261/3223 ,  C08K3/08 ,  C08K2003/0806 ,  C08K2201/011 ,  H01B1/127 ,  H01B1/128 ,  H01L51/0027 ,  H01L51/0036 ,  H01L51/0091 ,  H01L51/4213 ,  H05K1/092 ,  H05K3/106 ,  H05K2201/0329 ,  H05K2201/10143 ,  H05K2203/1157 ,  Y10T428/2927 ,  Y10T428/2958 ,  C08L65/00

Abstract: A process of producing a conducting material suitable for being filled in TSVs for LSI chip 3D package, etc. includes that a solution containing a monomer that provides a conducting polymer, anions, and metal ions such as Ag+ or Cu2+ is irradiated with ultraviolet radiation or light having the energy necessary for exciting electrons up to an energy level capable of reducing the metal ions to precipitate a conducting polymer/metal composite. This enables an electrical conductor of high electrical conductivity to be precipitated faster than could be achieved by conventional processes.

公开(公告)号：US20180215940A1

公开(公告)日：2018-08-02

申请号：US15746244

申请日：2016-07-22

Applicant: CAMBRIDGE ENTERPRISE LIMITED ,  NOVALIA LIMITED

Inventor： Guohua HU ,  Richard Colin Thomson HOWE ,  Zongyin YANG ,  Leonard NG WEI TAT ,  Christopher Gareth JONES ,  Kate Jessie STONE ,  Tawfique HASAN

IPC: C09D11/52 ,  C01B32/194 ,  C09D11/037 ,  C09D11/033 ,  C09D11/106 ,  C08K3/04 ,  C08K7/00 ,  C01G39/06 ,  C01B21/064 ,  C09J129/04

CPC classification number: C09D11/52 ,  B82Y30/00 ,  B82Y40/00 ,  C01B19/007 ,  C01B21/0648 ,  C01B32/194 ,  C01G39/06 ,  C01P2006/40 ,  C08K3/042 ,  C08K7/00 ,  C08K2201/001 ,  C08K2201/011 ,  C09C1/44 ,  C09D11/033 ,  C09D11/037 ,  C09D11/106 ,  C09J129/04 ,  Y10S977/734 ,  Y10S977/753 ,  Y10S977/755 ,  Y10S977/816 ,  Y10S977/824 ,  Y10S977/842 ,  Y10S977/892 ,  Y10S977/932

Abstract: A dispersion of nanoplatelets or particles suspended in a carrier liquid is disclosed. The nanoplatelets or particles, e.g. graphene nanoplatelets, are derived from a layered material. The loading amount of nanoplatelets or particles in the dispersion is at least 20 mg nanoplatelets or particles per 1 ml of dispersion. The dispersion optionally further including a dispersant, the volume ratio of dispersant to the nanoplatelets or particles being less than 1:1. A process for manufacturing the dispersion includes mixing the carrier liquid and the nanoplatelets or particles under high shear conditions. The dispersion can be used as an ink system, as a functional additive within an ink, coating or adhesive formulation, and/or in the manufacture of a nanoplatelet-polymer composite or a particle-polymer composite.

公开(公告)号：US20180208820A1

公开(公告)日：2018-07-26

申请号：US15746089

申请日：2016-07-20

Applicant: SUMITOMO BAKELITE CO., LTD.

Inventor： Mika Tsuda ,  Haruyuki Hatano ,  Kazuya Kitagawa ,  Keita Nagahashi

IPC: C09K5/14 ,  C08L79/04 ,  C08J5/18 ,  H01L23/373 ,  H01L23/495

CPC classification number: C09K5/14 ,  C08J5/18 ,  C08J2379/04 ,  C08J2463/00 ,  C08J2463/02 ,  C08J2463/08 ,  C08K3/36 ,  C08K3/38 ,  C08K2003/2227 ,  C08K2003/385 ,  C08K2201/011 ,  C08L61/14 ,  C08L63/00 ,  C08L79/04 ,  C08L2203/20 ,  C08L2205/025 ,  C08L2205/035 ,  H01L23/3107 ,  H01L23/3121 ,  H01L23/3733 ,  H01L23/3737 ,  H01L23/4334 ,  H01L23/49568 ,  H01L23/49575 ,  H01L23/49586 ,  H01L24/32 ,  H01L24/48 ,  H01L24/73 ,  H01L2224/29139 ,  H01L2224/32245 ,  H01L2224/451 ,  H01L2224/48091 ,  H01L2224/48137 ,  H01L2224/48247 ,  H01L2224/73265 ,  H01L2924/13055 ,  H01L2924/181 ,  H01L2924/00012 ,  H01L2924/00014 ,  H01L2924/00 ,  C08L61/06 ,  C08K3/22 ,  C08K2003/382

Abstract: The thermal conductive resin composition of first embodiment includes an epoxy resin, a cyanate resin, and thermal conductive filler. It has a thermal conductivity at 25° C., and cracking does not occur when a specific flex resistance test is carried out. The thermal conductive resin composition of a second embodiment includes an epoxy resin, a thermal conductive filler, and silica nanoparticles. An average particle diameter D50 of the silica nanoparticles is equal to or more than 1 nm and equal to or less than 100 nm, a content of the silica nanoparticles is equal to or more than 0.3% by mass and equal to or less than 2.5% by mass with respect to 100% by mass of a total solid content of the thermal conductive resin composition. The thermal conductive filler includes secondary agglomerated particles constituted of primary particles of scale-like boron nitride.

公开(公告)号：US20180201830A1

公开(公告)日：2018-07-19

申请号：US15744262

申请日：2016-08-23

Applicant: NATIONAL INSTITUTE FOR MATERIALS SCIENCE ,  National Taiwan University

Inventor： Masayoshi HIGUCHI ,  Sheng-Yuan KAO ,  Kuo-Chuan HO

IPC: C09K9/02 ,  C08G83/00 ,  C08K3/04 ,  C08G79/00 ,  G02F1/155 ,  G02F1/15

CPC classification number: C09K9/02 ,  B82Y20/00 ,  B82Y30/00 ,  C08G79/00 ,  C08G83/008 ,  C08K3/041 ,  C08K2201/011 ,  C09K2211/1466 ,  C09K2211/187 ,  G02F1/15 ,  G02F1/1503 ,  G02F1/15165 ,  G02F1/155 ,  G02F1/163 ,  G02F2202/36 ,  Y10S977/742 ,  Y10S977/952

Abstract: Disclosed is a redox-complementary electrochromic device exhibiting black-to-transmissive switching, wherein the device comprises an electrochromic layer and a redox-active material layer sandwiched between a transparent first electrode and a transparent secondary electrode, the electrochromic layer comprising an electrochromic Co-based metallo-supramolecular polymer represented by the formula (I), and the redox active material being capable of reacting with the electrochromic material to change the electrochromic material from black state into colorless transmissive state, where in the formula (I), X represents a counter anion, R represents a single bond or a spacer comprising a carbon atom and a hydrogen atom, each of R1 to R4 independently represents a hydrogen atom or a substituent group, and n represents an integer of from 2 to 5000, which indicates a degree of polymerization.

公开(公告)号：US20180194966A1

公开(公告)日：2018-07-12

申请号：US15403315

申请日：2017-01-11

Applicant: Hamilton Sundstrand Corporation

Inventor： Steven Poteet ,  Marc E. Gage ,  David J. Grulke

IPC: C09D183/00 ,  C08J3/20 ,  B05D1/02 ,  B05D1/18

CPC classification number: C09D183/00 ,  B05D1/02 ,  B05D1/18 ,  C08J3/203 ,  C08J2383/00 ,  C08K3/346 ,  C08K2201/003 ,  C08K2201/011 ,  C09D183/04

Abstract: A high temperature coating includes a silicone resin, a mass of nanoclay particles dispersed in the silicone resin, a surfactant and water.

公开(公告)号：US20180192906A1

公开(公告)日：2018-07-12

申请号：US15742078

申请日：2016-07-07

Applicant: RYTHM

Inventor： Quentin SOULET DE BRUGIERE ,  Hugo MERCIER

IPC: A61B5/0478 ,  A61B5/00 ,  C08K7/24 ,  C08K3/04 ,  A61L31/12 ,  A61L31/04

CPC classification number: A61B5/0478 ,  A61B5/04 ,  A61B5/6803 ,  A61L31/041 ,  A61L31/126 ,  C08K3/04 ,  C08K3/041 ,  C08K3/042 ,  C08K3/046 ,  C08K7/24 ,  C08K2201/001 ,  C08K2201/006 ,  C08K2201/011

Abstract: The invention relates to polymer compositions including a polymer matrix in which are dispersed carbon nanotubes and adsorbent elements selected from activated carbon particles and graphene nanoplatelets, as well as electrodes including such compositions and electrical circuits and devices including the electrodes.

公开(公告)号：US10020119B2

公开(公告)日：2018-07-10

申请号：US15388465

申请日：2016-12-22

Applicant: INDUSTRIAL TECHNOLOGY RESEARCH INSTITUTE

Inventor： Yi-Chang Du ,  Li-Duan Tsai ,  Kan-Hsuan Lin

IPC: H01G9/15 ,  C08K3/22 ,  H01G9/07 ,  H01G9/025 ,  H01G9/042 ,  H01G9/055 ,  H01G9/02

CPC classification number: H01G9/15 ,  C08K3/22 ,  C08K2003/2227 ,  C08K2003/2296 ,  C08K2201/001 ,  C08K2201/003 ,  C08K2201/011 ,  H01G9/02 ,  H01G9/025 ,  H01G9/042 ,  H01G9/055 ,  H01G9/07 ,  C08L39/06

Abstract: A capacitor structure is provided, which includes a positive electrode, a dielectric layer on the positive electrode, and an organic-inorganic composite layer on the dielectric layer. The capacitor structure also includes a negative electrode, and a conductive conjugated polymer electrolyte disposed between the organic-inorganic composite layer and the negative electrode.

公开(公告)号：US20180179060A1

公开(公告)日：2018-06-28

申请号：US15759309

申请日：2016-06-03

Applicant: M. TECHNIQUE CO., LTD.

Inventor： Masakazu ENOMURA ,  Daisuke HONDA

IPC: C01B13/36 ,  C01G49/06 ,  C01G9/02 ,  C09D7/40

CPC classification number: A61K8/0245 ,  A61K8/04 ,  A61K8/19 ,  A61K8/25 ,  A61K8/4926 ,  A61K2800/413 ,  A61K2800/43 ,  A61K2800/621 ,  A61K2800/651 ,  A61Q1/02 ,  A61Q17/04 ,  B82Y30/00 ,  C01B13/36 ,  C01B33/12 ,  C01G9/02 ,  C01G49/06 ,  C01P2002/72 ,  C01P2002/82 ,  C01P2004/04 ,  C01P2004/32 ,  C01P2004/64 ,  C01P2004/84 ,  C08K3/34 ,  C08K9/02 ,  C08K2003/2265 ,  C08K2201/003 ,  C08K2201/011 ,  C09C1/043 ,  C09C1/24 ,  C09C3/063 ,  C09C3/08 ,  C09D1/00 ,  C09D5/004 ,  C09D5/32 ,  C09D7/61 ,  C09D7/67

Abstract: A method of producing efficiently and stably core-shell type oxide particles, wherein the entire surface of the core oxide particles is uniformly coated with the shell oxide, includes at least two steps of: Step 1 of precipitating the core oxide particles in a mixed fluid prepared by mixing an oxide raw material liquid for core and an oxide precipitation solvent and Step 2 of coating the entire surface of the core oxide particles uniformly with the shell oxide by mixing the mixed fluid and an oxide raw material liquid for shell. (A) At least Steps 1 and 2 are performed continuously between at least two processing surfaces 1 and 2 which are capable of approaching to and separating from each other, at least one of which rotates relatively to the other; (B) after Step 1, Step 2 is completed within a prescribed time during which the core oxide particles do not aggregate in the mixed fluid; or (C) Step 1 and Step 2 are controlled so that the primary particle diameter of the core-shell type oxide particles is 190% or less relative to the primary particle diameter of the core oxide particles.