子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 241 | BARRIER COATING COMPOSITIONS, COMPOSITES PREPARED THEREFROM, AND QUANTUM DOT POLYMER COMPOSITE ARTICLES INCLUDING THE SAME | US14920189 | 2015-10-22 | US20160160060A1 | 2016-06-09 | Tomoyuki KIKUCHI; EunJoo JANG; Hyun A KANG; Nayoun WON; Oul CHO; Haeng Deog KOH |
| A barrier coating composition including: a monomer combination including a first monomer having at least two thiol groups at its terminal end and a second monomer having at least two carbon-carbon unsaturated bond-containing groups at its terminal end; and a plurality of organo-modified clay particles dispersed in the monomer combination, wherein the organo-modified clay particles include a compound having a hydrocarbyl group linked to a heteroatom, and wherein the compound is a primary, secondary, or tertiary amine, a quaternary organoammonium salt, a primary, secondary, or tertiary phosphine, a quaternary organophosphonium salt, a thiol including an amine group, or a combination thereof. | ||||||
| 242 | Stimulus-responsive gel material | US14618291 | 2015-02-10 | US09353228B2 | 2016-05-31 | Satomi Yoshioka; Hiroshi Yagi |
| A stimulus-responsive gel material includes: a first polymer having an OH group; a second polymer having a phenylboronic acid structure; fine particles having an average particle diameter of 10 nm or more and 1000 nm or less; and a solvent, wherein the material is capable of being put into a first state in which the OH group of the first polymer and the phenylboronic acid structure of the second polymer are bonded to each other, and a second state in which the bond between the OH group of the first polymer and the phenylboronic acid structure of the second polymer is dissociated, and the wavelength of a reflected light from the material is different between the first state and the second state. | ||||||
| 243 | Fluorine-based surface treating agent for vapor deposition and article finished with the surface treating agent by vapor deposition | US13684289 | 2012-11-23 | US09340705B2 | 2016-05-17 | Yuji Yamane; Noriyuki Koike |
| There is disclosed a fluorine-based surface treating agent for vapor deposition comprising (A) a hydrolyzable group-containing silane modified with a polymer containing a fluorooxyalkylene group and/or a partial hydrolytic condensate, and (B) a polymer containing a fluorooxyalkylene group having a higher weight average molecular weight than component (A), wherein components (A) and (B) are mixed in a weight ratio of from 6:4 to 9:1. | ||||||
| 244 | PROCESSES FOR RECOVERING RUBBER FROM AGED BRIQUETTES AND AGED BRIQUETTES CONTAINING PLANT MATTER FROM NON-HEVEA PLANTS | US14383380 | 2013-03-06 | US20150018459A1 | 2015-01-15 | Yingyi Huang; Mark Smale; Robert White; Hiroshi Mouri; William Cole |
| Provided herein are organic solvent-based processes for the removal of rubber from aged briquettes made from compressed plant matter (briquettes) of non-Hevea plants. Also provided are aged briquettes made from the compressed plant matter of non-Hevea plants where the briquettes have been aged for either various time period after formation and the rubber within the briquette has retained its a molecular weight to within a specified range. | ||||||
| 245 | Substrate-independent layer-by-layer assembly using catechol-functionalized polymers | US14017844 | 2013-09-04 | US08829154B2 | 2014-09-09 | Phillip B. Messersmith; Haeshin Lee; Yuhan Lee; Zhongqiang Liu; Lesley Hamming |
| The present invention provides a simple, non-destructive and versatile method that enables layer-by-layer (LbL) assembly to be performed on virtually any substrate. A novel catechol-functionalized polymer which adsorbs to virtually all surfaces and can serve as a platform for LbL assembly in a surface-independent fashion is also provided. | ||||||
| 246 | Multifunctional stellate prepolymer mixtures, production and use and coatings made thereof | US12709559 | 2010-02-22 | US08816000B2 | 2014-08-26 | Haitao Rong; Peter Greiwe; Jürgen Groll; Christine Mohr; Marina Glesius; Martin Möller |
| The invention relates to coatings having a contact angle hysteresis with water measured by the sessile drop method of at most 20°. The coatings can be produced from a mixture of at least two different stellate prepolymers and/or stellate prepolymer/nanoparticle complexes which may cross-link to each other and to the surface of the substrate coated, wherein the stellate prepolymers and/or stellate prepolymer/nanoparticle complex have at least three hydrophilic polymer branches before cross-linking which are themselves soluble in water with on all or a part of the free ends thereof, silyl end groups R1 of general formula (I): R1=—CRa2—Si(ORb)r(Rc)3−r, where Ra=H or straight or branched chain 1-6C alkyl, ORb=a hydrolysable group, Rc=linear or branched chain 1-6C alkyl and r=a number from 1 to 3 and the optionally non silyl end group carrying ends have reactive end groups which a reactive with each other, with the substrate to be coated optional entities included in the coating and/or with the silyl end groups with the proviso the mixture (a) has at least one stellate prepolymer with 3-5 hydrophilic polymer branches and (b) at least one stellate prepolymer and/or a stellate prepolymer/nanoparticle complex with a least 6 hydrophilic polymer branches. The invention further relates to a method for production for said coatings and stellate prepolymers as used in the coatings. The invention furthermore relates to the use of the stellate prepolymers as additives in various materials for temporary or permanent anti-soiling treatment of surfaces. | ||||||
| 247 | Substrate-independent layer-by-layer assembly using catechol-functionalized polymers | US13622136 | 2012-09-18 | US08551568B2 | 2013-10-08 | Phillip B. Messersmith; Haeshin Lee; Yuhan Lee; Zhongqiang Liu; Lesley Hamming |
| The present invention provides a simple, non-destructive and versatile method that enables layer-by-layer (LbL) assembly to be performed on virtually any substrate. A novel catechol-functionalized polymer which adsorbs to virtually all surfaces and can serve as a platform for LbL assembly in a surface-independent fashion is also provided. | ||||||
| 248 | Method for preparing a material formed from arborescent-branched molecules comprising associative groups | US12810179 | 2008-12-19 | US08530671B2 | 2013-09-10 | François-Genes Tournilhac; Manuel Hidalgo; Ludwik Leibler |
| The present invention relates to a method of preparing a material formed from arborescent-branched molecules comprising associative groups that includes the following successive steps: (a) the reaction of at least one at least trifunctional compound (A) bearing first and second functional groups with at least one bifunctional compound (B), the functional groups of which are capable of reacting with the first functional groups of the compound (A); and (b) the reaction of the compound(s) obtained in step (a) with at least one compound (C) bearing, on the one hand, at least one reactive group capable of reacting with the second functional groups of (A) and, on the other hand, at least one given associative group. | ||||||
| 249 | Copolymer coordination compound comprising heterogeneous complexes and gel using the same | US12071178 | 2008-02-15 | US08304502B2 | 2012-11-06 | Sung Ho Yoon |
| Disclosed is a copolymer coordination compound including two or more kinds of complexes, and a method of preparing the same. Herein, each of the complexes includes an organic ligand and a metal ion, and the two or more kinds of complexes are arranged in a line in a regular or irregular order, and are coordinated to each other. Also, the disclosed copolymer coordination compound functions as a gelator in a solvent, and is formed into a gel. | ||||||
| 250 | Polymerizable Higher Diamondoid Derivatives | US12973513 | 2010-12-20 | US20110112258A1 | 2011-05-12 | Jeremy E. Dahl; Robert M. Carlson; Shenggao Liu |
| Higher diamondoid derivatives capable of taking part in polymerization reactions are disclosed as well as intermediates to these derivatives, polymers formed from these derivatives and methods for preparing the polymers. | ||||||
| 251 | NOVEL MACROMOLECULAR COMPOUNDS HAVING A CORE-SHELL STRUCTURE FOR USE AS SEMICONDUCTORS | US12922591 | 2009-02-10 | US20110101318A1 | 2011-05-05 | Timo Meyer-Friedrichsen; Stephan Kirchmeyer; Andreas Elschner; Sergei Ponomarenko |
| The invention relates to novel macromolecular compounds having a core-shell structure and also their use in electronic components. | ||||||
| 252 | Polymer Complex | US12224805 | 2007-03-02 | US20110098414A1 | 2011-04-28 | Makoto Fujita; Masaki Kawano; Takehide Chou; Takahiro Kojima |
| The invention provides a polymer complex having two or more kinds of channel groups through which specific compounds ranging from gaseous small molecules to large molecules such as proteins and other biomolecules can be selectively incorporated and/or released and/or transported. The polymer complex comprises an aromatic compound having two or more coordinating sites as a ligand, a metal ion as a central metal, and an uncoordinating aromatic compound, wherein the polymer complex has a three-dimensional lattice-like structure containing a stack structure comprising the uncoordinating aromatic compound intercalated between aromatic compound ligands in a three-dimensional coordination network formed by coordinating the aromatic compound ligands to the central metal ion, the three-dimensional lattice-like structure is provided with two or more kinds of channel groups each composed of channels identical with one another and having inherent affinity for guest components, the uncoordinating aromatic compound has a specific substituent A at a specific position on the aromatic ring thereof, and the uncoordinating aromatic compound is arranged regularly such that the substituent A is directed to the inside of a specific channel group B out of the two or more kinds of channel groups. | ||||||
| 253 | Polymerizable higher diamondoid derivatives | US11013638 | 2004-12-17 | US07884256B2 | 2011-02-08 | Shenggao Liu; Robert M. Carlson; Jeremy E. Dahl |
| Higher diamondoid derivatives capable of taking part in polymerization reactions are disclosed as well as intermediates to these derivatives, polymers formed from these derivatives and methods for preparing the polymers. | ||||||
| 254 | Block Coordination Copolymers | US12478018 | 2009-06-04 | US20100222509A1 | 2010-09-02 | Kyoung Moo Koh; Antek G. Wong-Foy; Adam J. Matzger; Annabelle I. Benin; Richard R. Willis |
| The present invention provides compositions of crystalline coordination copolymers wherein multiple organic molecules are assembled to produce porous framework materials with layered or core-shell structures. These materials are synthesized by sequential growth techniques such as the seed growth technique. In addition, the invention provides a simple procedure for controlling functionality. | ||||||
| 255 | MULTIFUNCTIONAL STELLATE PREPOLYMER MIXTURES, PRODUCTION AND USE AND COATINGS MADE THEREOF | US12709559 | 2010-02-22 | US20100209613A1 | 2010-08-19 | Haitao Rong; Peter Grejwe; Jürgen Groll; Christine Mohr; Marina Glesius; Martin Möller |
| The invention relates to coatings having a contact angle hysteresis with water measured by the sessile drop method of at most 20°. The coatings can be produced from a mixture of at least two different stellate prepolymers and/or stellate prepolymer/nanoparticle complexes which may cross-link to each other and to the surface of the substrate coated, wherein the stellate prepolymers and/or stellate prepolymer/nanoparticle complex have at least three hydrophilic polymer branches before cross-linking which are themselves soluble in water with on all or a part of the free ends thereof, silyl end groups R1 of general formula (I): R1=—CRa2—Si(ORb)r(Rc)3-r, where Ra=H or straight or branched chain 1-6C alkyl, ORb=a hydrolysable group, Rc=linear or branched chain 1-6C alkyl and r=a number from 1 to 3 and the optionally non silyl end group carrying ends have reactive end groups which a reactive with each other, with the substrate to be coated optional entities included in the coating and/or with the silyl end groups with the proviso the mixture (a) has at least one stellate prepolymer with 3-5 hydrophilic polymer branches and (b) at least one stellate prepolymer and/or a stellate prepolymer/nanoparticle complex with a least 6 hydrophilic polymer branches. The invention further relates to a method for production for said coatings and stellate prepolymers as used in the coatings. The invention furthermore relates to the use of the stellate prepolymers as additives in various materials for temporary or permanent anti-soiling treatment of surfaces. | ||||||
| 256 | Polymeric Salts and Poly-NHC-Metal Complexes | US12295716 | 2006-07-05 | US20090227740A1 | 2009-09-10 | Jackie Y. Ying; Yugen Zhang; Dingyu Hu; Pranab K. Patra |
| The invention provides a polymeric salt, wherein the monomer unit of the polymeric salt comprises two nitrogen containing heterocyclic groups joined by a rigid linker group. The nitrogen atoms of the heterocyclic groups are disposed so as to enable a polymeric carbene formed by from the polymeric salt to complex with a metal atom. The invention also provides a polymeric metal complex which may be made from the polymeric salt, and which may be used in a Suzuki coupling reaction. The polymeric salt may be used as a heterogeneous organic catalyst for cyanation reaction. | ||||||
| 257 | REVERSIBLE SELF-ASSEMBLY OF IMBEDDED METALLOMACROCYCLES WITHIN A MACROMOLECULAR SUPERSTRUCTURE | US11720088 | 2005-11-23 | US20090171088A1 | 2009-07-02 | George R. Newkome; Charles N. Moorefield; Pingshan Wang |
| In accordance with the present invention, there is provided a method for preparing a reversible, self-assembly of an imbedded hexameric metallomacrocycle within a macromolecular superstructure. The method occurs by an intramolecular mechanism in which a macromolecular skeleton possesses multiple ligands capable of reversible assembly-disassembly triggered by the presence of metal ions. | ||||||
| 258 | Synthesis of oligo/poly(catechins) and methods of use | US11978540 | 2007-10-29 | US20090170928A1 | 2009-07-02 | Ferdinando F. Bruno; Jayant Kumar; Subhalakshmi Nagarajan; Susan J. Braunhut; Ramaswamy Nagarajan; Lynne A. Samuelson; Donna McIntosh; Klaudia Foley |
| A method for synthesizing a biocompatible, water-soluble oligo/polyflavanoid, includes polymerizing an optionally substituted flavanoid with a polymerization agent in the presence of a biocompatible polymerization solubilizer, thereby producing the biocompatible, soluble oligo/polyflavanoid. Also included is a biocompatible, soluble, oligo/polyflavanoid or a pharmaceutically acceptable salt, solvate, or complex thereof. Also included are methods of treating a subject for cancer, cardiac damage, viral infection, and obesity. | ||||||
| 259 | Materials having crosslinked polyrotaxane and process for producing the same | US11579842 | 2005-05-06 | US20090011933A1 | 2009-01-08 | Kohzo Ito; Jun Araki |
| A material having crosslinked polyrotaxane which has further improved swelling properties, especially one having a crosslinked polyrotaxane which changes in swelling property with change in pH; and a material having a crosslinked polyrotaxane which is responsive especially at a high speed to a change of the surrounding electric field. The materials have a crosslinked polyrotaxane comprising at least two polyrotaxane molecules which each comprises cyclic molecules, a linear molecule which includes the cyclic molecules in cavities of cyclic molecules in a skewered manner, and capping groups, each of which locates at each end of the linear molecule in order to prevent the dissociation of the cyclic molecules, the least two polyrotaxane molecules having been bound to each other through a chemical bonding between the cyclic molecules thereof, wherein the cyclic molecules have hydroxy groups (—OHs) and part of the hydroxy groups are substituted with a group having an ionic group. | ||||||
| 260 | Copolymer coordination compound comprising heterogeneous complexes and gel using the same | US12071178 | 2008-02-15 | US20080200618A1 | 2008-08-21 | Sung Ho Yoon |
| Disclosed is a copolymer coordination compound including two or more kinds of complexes, and a method of preparing the same. Herein, each of the complexes includes an organic ligand and a metal ion, and the two or more kinds of complexes are arranged in a line in a regular or irregular order, and are coordinated to each other. Also, the disclosed copolymer coordination compound functions as a gelator in a solvent, and is formed into a gel. | ||||||
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