221 |
Chelates and methods of making the same |
US53552055 |
1955-09-20 |
US2933475A |
1960-04-19 |
HOOVER FRED W; MILLER HENRY C |
|
222 |
Arsonosiloxanes and their preparation |
US63784557 |
1957-02-01 |
US2863893A |
1958-12-09 |
KARY ROLAND M; FRISCH KURT C |
|
223 |
Aminoplasts modified with titanium polymers |
US14334950 |
1950-02-09 |
US2643984A |
1953-06-30 |
THOMAS BOYD |
|
224 |
Composition of matter and method of producing the same |
US66693033 |
1933-04-19 |
US1992180A |
1935-02-26 |
HENRY BOWEN ALBERT; WILLIAMS DIKE THEODORE |
|
225 |
CRYSTALLINE COPPER-BASED COORDINATION POLYMERS AND THEIR USE |
US15600957 |
2017-05-22 |
US20180334713A1 |
2018-11-22 |
Jin-Xiang Chen; Bao-Ping Xie; Gui-Hua Qiu; Pei-Pei Hu; Zhen Liang; Ye-Mei Liang; Bin Sun; Li-Ping Bai; Zhi-Hong Jiang |
A method of preparing a crystalline copper-based coordination polymer comprises preparing a mixture of copper ions and a first quaternized carboxylate pyridyl ligand; adding a second polypyridyl ligand; and forming crystals of a copper-based coordination polymer therefrom. The crystalline copper-based coordination polymer is suitable for providing a sensing platform for detecting the presence of one or more target nucleic acid sequences such as viral RNA, in particular Dengue virus and/or Zika virus RNA with high selectivity and high specificity. A method of detecting at least a first target nucleic acid sequence, in particular from a viral RNA, in particular it is Flavivirus RNA, in a sample is also provided. Further provided is a kit including the crystalline copper-based coordination polymer and an oligonucleotide probe. |
226 |
POLYMETALLOXANE, METHOD FOR PRODUCING SAME, COMPOSITION THEREOF, CURED FILM AND METHOD FOR PRODUCING SAME, AND MEMBERS AND ELECTRONIC COMPONENTS PROVIDED WITH SAME |
US15772881 |
2016-11-17 |
US20180327275A1 |
2018-11-15 |
Masao Kamogawa; Mitsuhito Suwa; Hiroko Mitsui; Miki Nakamichi |
Disclosed is a polymetalloxane including a constituent unit represented by the following general formula (1), which stably exists in a transparent and uniform state in a solution and can form a homogeneous cured film: wherein R1 is an organic group and at least one of R1 is an (R33SiO—) group, R3 is optionally selected from specific groups, R2 is optionally selected from specific groups, when plural R1, R2, and R3 exist, they may be the same or different, M represents a specific metal atom, m is an integer indicating a valence of a metal atom M, and a is an integer of 1 to (m−2). |
227 |
BLACK-TO-TRANSMISSIVE ELECTROCHROMIC DEVICE |
US15744262 |
2016-08-23 |
US20180201830A1 |
2018-07-19 |
Masayoshi HIGUCHI; Sheng-Yuan KAO; Kuo-Chuan HO |
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. |
228 |
POROUS COORDINATION POLYMER AND GAS STORAGE USING THE SAME |
US15662635 |
2017-07-28 |
US20180093251A1 |
2018-04-05 |
TAKAIKI NOMURA; HIDEKI HATA; MOTOMASA YONEZUMI; KAZUHITO HATO; ATSUO OKAICHI |
The present invention provides a porous coordination polymer having high ability of storing a gas. The porous coordination polymer according to the present invention comprises zinc cluster ions and one kind of tricarboxylic acid ions selected from the group consisting of the following chemical formula (I), the following chemical formula (II), and the following chemical formula (III); where X represents a natural number of not less than 1 and not more than 3, wherein the tricarboxylic acid ions are bound to the zinc cluster ions as terdentate ligands. |
229 |
Methods of preparing self-decontaminating surfaces using quaternary silanes and titanium anatase sol |
US15432334 |
2017-02-14 |
US09855584B2 |
2018-01-02 |
Craig Grossman; Mai Ngo; Ronald Wysocki |
A method to prepare a self-decontaminating surface, where that method includes disposing a first coating on a surface, where that first coating comprises an organosilane, and disposing a second coating over the first coating, where the second coating comprises TiO2. |
230 |
Composition and method to form a self decontaminating surface |
US13448325 |
2012-04-16 |
US09757769B2 |
2017-09-12 |
Craig Grossman; Mai Ngo; Ronald Wysocki |
A method to prepare a self-decontaminating surface, where that method includes disposing a first coating on a surface, where that first coating comprises an organosilane, and disposing a second coating over the first coating, where the second coating comprises TiO2. |
231 |
REVERSIBLE METALLOPOLYMER NETWORK |
US15368232 |
2016-12-02 |
US20170158824A1 |
2017-06-08 |
William Scott Compel; Christopher J. Ackerson; O. Andrea Wong |
The invention provides a metallopolymer coordination network comprising one or more coinage or similar metals and a glyme or glyme-equivalent. The composition has an amorphous polymer network that is significantly stronger than previously reported supramolecular hydrogels synthesized without glyme. Glyme chain length and water content strongly influence the mechanical, electronic, and optical behavior of the network. |
232 |
Porous polymer metal complex, gas adsorbent, and gas separation device and gas storage device using same |
US14440014 |
2013-10-31 |
US09630164B2 |
2017-04-25 |
Hiroshi Kajiro; Koichi Nose; Susumu Kitagawa; Ryotaro Matsuda; Hiroshi Sato |
An object of the present invention is to provide a porous polymer metal complex which can be used as a gas adsorbent and contains two or more types of similar ligands. A porous polymer metal complex is provided expressed by [CuX]n(1) (in the Formula, X represents two or more types of isophthalic acid ions selected from the group consisting of isophthalic acid ions and isophthalic acid ions having a substituent at position 5, at least an amount of one type of X is 5 mol % to 95 mol % of the total number of moles of X, and n represents an assembly number of constituent units expressed by CuX and is not particularly limited). |
233 |
Organic/Heterometallic Hybrid Polymer, Process for Producing Same, Film of Organic/Heterometallic Hybrid Polymer, Organic/Multimetallic Hybrid Polymer, Process for Producing Same, and Film of Organic/Multimetallic Hybrid Polymer |
US15307037 |
2015-05-01 |
US20170044325A1 |
2017-02-16 |
Masayoshi Higuchi; Takashi Sato |
The present invention relates to an organic/heterometallic hybrid polymer including a plurality of organic metal complexes and a plurality of transition metals, the organic/heterometallic hybrid polymer, whereinthe plurality of organic metal complexes are linked in a linear manner by sandwiching each of the plurality of transition metals therebetween,the organic metal complexes include two ligands each having a terpyridyl group and one connector having Ru(dppe)2 and two ethynylene groups, and the two ligands are linked by the connector, so that a nitrogen atom at position 1′ of the terpyridyl group is directed toward the terminal side of the molecule of the organic metal complex, andthe terpyridyl groups of at least two different organic metal complexes of the plurality of organic metal complexes are bound to one of the transition metals through a coordinate bond, thereby linking the plurality of organic metal complexes while sandwiching the plurality of transition metals alternately therebetween. |
234 |
Hardmask |
US14925147 |
2015-10-28 |
US09563126B2 |
2017-02-07 |
Shintaro Yamada; Deyan Wang; Sabrina Wong; Cong Liu; Cheng-Bai Xu |
This invention provides a composition containing an organometallic compound having a chromophore moiety in the metal polymer backbone which allows a wider range of n/k values such that substrate reflectivity can be controlled under various conditions. |
235 |
Quantum Dots Stabilized With A Metal Thiol Polymer |
US15061753 |
2016-03-04 |
US20160289552A1 |
2016-10-06 |
Matthew Werner; Benjamin Peek; Abu Mohammad Imroz Ali; Shahin Salma; Steven Daniels; James Harris |
A composition of matter comprises a plurality of quantum dots and a metal thiol polymer that acts to stabilize the quantum dots. In certain embodiments, the metal thiol polymer is a zinc thiol polymer. The zinc thiol polymer may be a zinc alkanethiolate. The zinc alkanethiolate may be zinc dodecanethiolate (Zn-DDT). A composition comprising a plurality of quantum dots and a metal thiol polymer may be formulated with one or more additional polymers as a quantum dot-containing bead or as a quantum dot-containing composite material—e.g., a multilayer film. |
236 |
Solution for formation of organic thin film, and method for production thereof |
US12866899 |
2009-02-23 |
US09303124B2 |
2016-04-05 |
Tomoya Hidaka; Toshiaki Takahashi; Kazuhisa Kumazawa |
It is to provide a solution for forming an organic metal thin film that can form rapidly a dense monomolecular film with less impurity. A solution for forming an organic thin film comprising (A) at least one organic metal compound shown by the following formula (I) (provided that at least one organic metal compound contains a hydroxyl group); and (B) at least one organic metal compound shown by the following formula (II), R3mM2X54-m (II) wherein the solution is 40≦[(A)/{(A)+(B)}]×100≦100 (mass %), and 0≦[(B)/{(A)+(B)}]×100≦60 (mass %); or a solution for forming an organic thin film comprising an organic metal compound having at least one hydroxyl group and at least one hydrolysable group among the organic metal compounds shown by the following formula (I); or a solution for forming an organic thin film wherein the mass ratio of trimer with respect to dimer is greater than 0.5 among the metal organic compound shown by formula (I). |
237 |
HARDMASK |
US14925147 |
2015-10-28 |
US20160048077A1 |
2016-02-18 |
Shintaro YAMADA; Deyan WANG; Sabrina WONG; Cong LIU; Cheng-Bai XU |
This invention provides a composition containing an organometallic compound having a chromophore moiety in the metal polymer backbone which allows a wider range of n/k values such that substrate reflectivity can be controlled under various conditions. |
238 |
Heteroelement siloxane compounds and polymers |
US12526521 |
2008-02-04 |
US09187602B2 |
2015-11-17 |
Dimitris Elias Katsoulis; Mark Jon Loboda; Elizabeth McQuiston; Luisel Rodriguez |
Heteroelement siloxane polymers are described. The heteroelement siloxane polymers can have linear structure, cyclic structure, branched structure, and three-dimensional network structure and combinations thereof. The heterosiloxane polymers can be cured using curing chemistry derived from thermoset organosilicon polymers, and gels, coatings, plaques, parts and other useful articles can be prepared. |
239 |
POROUS POLYMER METAL COMPLEX, GAS ADSORBENT, AND GAS SEPARATION DEVICE AND GAS STORAGE DEVICE USING SAME |
US14440014 |
2013-10-31 |
US20150290618A1 |
2015-10-15 |
Hiroshi Kajiro; Koichi Nose; Susumu Kitagawa; Ryotaro Matsuda; Hiroshi Sato |
An object of the present invention is to provide a porous polymer metal complex which can be used as a gas adsorbent and contains two or more types of similar ligands. A porous polymer metal complex is provided expressed by [CuX]n(1) (in the Formula, X represents two or more types of isophthalic acid ions selected from the group consisting of isophthalic acid ions and isophthalic acid ions having a substituent at position 5, at least an amount of one type of X is 5 mol % to 95 mol % of the total number of moles of X, and n represents an assembly number of constituent units expressed by CuX and is not particularly limited). |
240 |
Conductive polymers from precursor polymers, method of making, and use thereof |
US13489905 |
2012-06-06 |
US09127121B2 |
2015-09-08 |
Gregory A. Sotzing |
Disclosed herein are precursor polymers containing units of heteroaryls and units of Si, Sn, Ge, or Pb, methods of producing the precursor polymers, and applications utilizing these precursor polymers to prepare conductive polymers. |