| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | MAKING NANOCHANNELS AND NANOTUNNELS | US15442952 | 2017-02-27 | US20170253479A1 | 2017-09-07 | BABAK NIKOOBAKHT, IV |
| A process for making a nanoduct includes: disposing an etchant catalyst on a semiconductor substrate including a single crystal structure; heating the semiconductor substrate to an etching temperature; introducing an oxidant; contacting the semiconductor substrate with the oxidant in a presence of the etchant catalyst; anisotropically etching the semiconductor substrate by the etchant catalyst in a presence of the oxidant in an etch direction that is coincident along a crystallographic axis of the semiconductor substrate; and forming the nanoduct as the etchant catalyst propagates along a surface of the semiconductor substrate during anisotropically etching the semiconductor substrate, the nanoduct being crystallographically aligned with the crystallographic axis of the semiconductor substrate. | ||||||
| 22 | NANOTUBE PARTICLE DEVICE AND METHOD FOR USING THE SAME | US14493041 | 2014-09-22 | US20160082617A1 | 2016-03-24 | Wayne R. Howe; Jeffrey H. Hunt; Angela W. Li; Dennis L. Coad |
| A nanotube particle device for two dimensional and three dimensional printing or additive/subtractive manufacturing. The nanotube particle device comprising a nanotube, a particle shooter, a positioning mechanism, and a detection sensor. The particle shooter shoots a particle down the nanotube towards a target, the detection sensor senses the collision of the particle with the target, and the positioning mechanism re-adjusts the positioning of the nanotube based on the results of the collision. A method for aiming the particle shooter and additive/subtractive manufacturing are also disclosed and described. | ||||||
| 23 | Assembly comprising J-aggregates | US13941578 | 2013-07-15 | US09238582B2 | 2016-01-19 | Bernard Wenger; Emmanuel Scolan; Raphael Pugin; Rolf Steiger |
| The assembly is made up of: a) a support including a mesoporous coating whose pores have an average diameter dimensioned so as to enable molecules from the family of cyanines to penetrate them, and b) a layer of molecules from the family of cyanines and organized into J-aggregates within the pores of the coating. The assembly moreover includes Quantum Dots located within the same pores as those containing the J-aggregates, the Quantum Dots maintaining J-aggregates structure. A method for producing such an assembly is also described. | ||||||
| 24 | ASSEMBLY COMPRISING J-AGGREGATES | US13941578 | 2013-07-15 | US20140017485A1 | 2014-01-16 | Bernard WENGER; Emmanuel SCOLAN; Raphael PUGIN; Rolf STEIGER |
| The assembly is made up of: a) a support including a mesoporous coating whose pores have an average diameter dimensioned so as to enable molecules from the family of cyanines to penetrate them, and b) a layer of molecules from the family of cyanines and organized into J-aggregates within the pores of the coating. The assembly moreover includes Quantum Dots located within the same pores as those containing the J-aggregates, the Quantum Dots maintaining J-aggregates structure. A method for producing such an assembly is also described. | ||||||
| 25 | 生体分子構造解析用デバイスおよび生体分子構造解析用デバイスの形成方法 | JP2016547319 | 2014-09-11 | JP6285040B2 | 2018-02-28 | 柳 至; 武田 健一 |
| 26 | カーボンナノ構造体の新規な二次構造物、この集合体及びこれを含む複合材 | JP2014548674 | 2012-12-21 | JP2015507597A | 2015-03-12 | キム、ソンジン; キム、ジンド; カン、ギョンヨン; ユン、ジェグン |
| 本発明は、新たな形態のカーボンナノ構造体の二次構造物、この集合体及びこれらを含む複合材に関するものであって、本発明による二次構造粒は、複数個のカーボンナノ構造体(carbon nanostructures,CNS)が全体又は部分的にチューブ状をなすように集合して形成されたことを特徴とする。本発明による新規二次構造物、この集合体及びこれを含む複合材は、エネルギー素材、機能性複合材、電池、半導体の分野等への活用度が高い。【選択図】図3 | ||||||
| 27 | 高表面積炭素オパールとそこから得られる逆オパール | JP2013125696 | 2013-06-14 | JP6367527B2 | 2018-08-01 | カズヒサ ヤノ; マシュー デイブ グッドマン; ポール バネスト ブラウン |
| 28 | 色素増感型太陽電池用対向電極、色素増感型太陽電池および太陽電池モジュール | JP2016527647 | 2015-06-11 | JPWO2015190108A1 | 2017-04-20 | 明彦 吉原 |
| 本発明は、触媒活性に優れ、さらに量産化に適した色素増感型太陽電池用対向電極、この対向電極を備える色素増感型太陽電池、および、この色素増感型太陽電池を用いた太陽電池モジュールを提供することを目的とする。本発明の色素増感型太陽電池用対向電極は、支持体と、前記支持体上に形成された、特定のカーボンナノチューブを含む触媒層とを有する。また、本発明の色素増感型太陽電池は、上記対向電極を備え、本発明の太陽電池モジュールは、上記色素増感型太陽電池を用いる。 | ||||||
| 29 | NANOTUBE PARTICLE DEVICE AND METHOD FOR USING THE SAME | EP15186303.2 | 2015-09-22 | EP3000782A1 | 2016-03-30 | Howe, Wayne R.; Hunt, Jeffrey H.; Li, Angela W.; Coad, Dennis L. |
A nanotube particle device for two dimensional and three dimensional printing or additive/subtractive manufacturing. The nanotube particle device comprising a nanotube, a particle shooter, a positioning mechanism, and a detection sensor. The particle shooter shoots a particle down the nanotube towards a target, the detection sensor senses the collision of the particle with the target, and the positioning mechanism re-adjusts the positioning of the nanotube based on the results of the collision. A method for aiming the particle shooter and additive/subtractive manufacturing are also disclosed and described. |
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| 30 | NOVEL SECONDARY STRUCTURE OF CARBON NANOSTRUCTURES, ASSEMBLY THEREOF, AND COMPOSITE COMPRISING SAME | EP12860897.3 | 2012-12-21 | EP2796408A1 | 2014-10-29 | KIM, SungJin; KIM, Jindo; KANG, KyungYeon; YOON, JaeKeun |
The present invention relates to a novel secondary structure of carbon nanostructures, a bundle thereof and a composite comprising the same. The secondary structure according to the present invention is characterized that it is formed by a plurality of carbon nanostructures (CNSs) assembled to have a tube form in whole or in part. The novel secondary structure according to the present invention, the bundle thereof and the composite comprising the same are highly applicable in fields of energy materials, functional composites, batteries, semiconductors and the like. |
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| 31 | Mesoporous layer comprising J-aggregates | EP13176195.9 | 2013-07-11 | EP2708492A1 | 2014-03-19 | Wenger, Bernard; Scolan, Emmanuel; Pugin, Raphaël; Steiger, Rolf |
The invention concerns an assembly made up of Said assembly moreover comprises Quantum Dots located within the same pores as those containing the J-aggregates, said Quantum Dots maintaining J-aggregates structure. The invention also concerns a method for producing such an assembly.
|
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| 32 | NANO-FLUIDIC DEVICE AND CHEMICAL ANALYSIS APPARATUS | US15764529 | 2016-10-21 | US20180280974A1 | 2018-10-04 | Yutaka KAZOE; Yuriy PIHOSH; Takehiko KITAMORI |
| A nano-fluidic device includes: a first substrate that has a nanoscale groove on one surface; and a second substrate that is integrally provided with the first substrate by bonding one surface of the second substrate to the one surface of the first substrate and forms a nanochannel with the groove of the first substrate, in which either the first substrate or the second substrate includes at least a thin portion in a part of a position overlapping the nanochannel in plan view, and the thin portion is deformed by pressing to open and close the nanochannel. | ||||||
| 33 | SYSTEMS AND METHODS FOR GENOME MAPPING | US15883183 | 2018-01-30 | US20180217122A1 | 2018-08-02 | Huaiyu Meng; Rajeev Ram |
| A system for molecular mapping includes a semiconductor substrate defining a reservoir to receive a sample of molecules and a nanofluidic channel in fluid communication with the reservoir. The system also includes a plurality of electrodes, in electrical communication with the nanofluidic channel, to electrophoretically trap the sample of molecules in the nanofluidic channel. At least one avalanche photodiode is fabricated in the semiconductor substrate and disposed within an optical near-field of the nanofluidic channel to detect fluorescence emission from at least one molecule in the sample of molecules. | ||||||
| 34 | HIGH SURFACE AREA CARBON OPALS AND INVERSE OPALS OBTAINED THEREFROM | US15477983 | 2017-04-03 | US20170260106A1 | 2017-09-14 | Kazuhisa Yano; Matthew Goodman; Paul Vannest Braun |
| Carbon opals, a form of colloidal crystal, are composed of ordered two-dimensional or three-dimensional arrays of Monodispersed Starburst Carbon Spheres (MSCS). Methods for producing such carbon opals include oxidizing as-synthesized MSCS, for example by heating in air, to increase surface charge. Such oxidation is believed to decrease settling rates of a colloidal suspension, enabling formation of an ordered colloidal crystal. Inverse opals, composed of any of a wide variety of materials, and based on a carbon opal template, have a reciprocal structure to a carbon opal. Inverse opals are formed by methods including: forming a carbon opal as described, impregnating a desired material into pores in the carbon opal to produce a hybrid structure, and removing the carbon portion from the hybrid structure. | ||||||
| 35 | COUNTER ELECTRODE FOR DYE-SENSITIZED SOLAR CELL, DYE-SENSITIZED SOLAR CELL, AND SOLAR CELL MODULE | US15316536 | 2015-06-11 | US20170140878A1 | 2017-05-18 | Akihiko YOSHIWARA |
| Provided is a counter electrode for dye-sensitized solar cell which is superior in catalytic activity and is also suitable for mass production, a dye-sensitized solar cell including the counter electrode, and a solar cell module obtained using the dye-sensitized solar cell. The counter electrode includes a support and a catalyst layer formed on or over the support, the catalyst layer containing specific carbon nanotubes. The dye-sensitized solar cell includes the counter electrode, and the solar cell module includes the dye-sensitized solar cell. | ||||||
| 36 | High surface area carbon opals and inverse opals obtained therefrom | US13526395 | 2012-06-18 | US09643894B2 | 2017-05-09 | Kazuhisa Yano; Matthew Dave Goodman; Paul Vannest Braun |
| A self-assembled carbon structure such as a carbon opal is disclosed herein. The structure is composed of hydrophilic carbon spheres oriented in a periodic colloidal crystal structure, wherein the carbon spheres have a porous surface, wherein the carbons spheres have an average particle diameter less than 3000 nm. Also disclosed is an inverse opal structure that includes a plurality of voids in the structural material. The voids are regularly arranged in an ordered periodic structure, the voids having a spherical shape. The inverse opal structure has a specific surface area greater than 100 m2/g and method for making the same together with materials that employ the same. | ||||||
| 37 | Secondary structure of carbon nanostructure, bundle thereof and composite comprising same | US13824925 | 2012-12-21 | US09512006B2 | 2016-12-06 | SungJin Kim; Jindo Kim; KyungYeon Kang; JaeKeun Yoon |
| The present invention relates to a novel secondary structure of carbon nanostructures, a bundle thereof and a composite comprising the same. The secondary structure according to the present invention is characterized that it is formed by a plurality of carbon nanostructures (CNSs) assembled to have a tube form in whole or in part.The novel secondary structure according to the present invention, the bundle thereof and the composite comprising the same are highly applicable in fields of energy materials, functional composites, batteries, semiconductors and the like. | ||||||
| 38 | NOVEL SECONDARY STRUCTURE OF CARBON NANOSTRUCTURE, BUNDLE THEREOF AND COMPOSITE COMPRISING SAME | US13824925 | 2012-12-21 | US20140329085A1 | 2014-11-06 | SungJin Kim; Jindo Kim; KyungYeon Kang; JaeKeun Yoon |
| The present invention relates to a novel secondary structure of carbon nanostructures, a bundle thereof and a composite comprising the same. The secondary structure according to the present invention is characterized that it is formed by a plurality of carbon nanostructures (CNSs) assembled to have a tube form in whole or in part.The novel secondary structure according to the present invention, the bundle thereof and the composite comprising the same are highly applicable in fields of energy materials, functional composites, batteries, semiconductors and the like. | ||||||
| 39 | HIGH SURFACE AREA CARBON OPALS AND INVERSE OPALS OBTAINED THEREFROM | US13526395 | 2012-06-18 | US20130337257A1 | 2013-12-19 | KAZUHISA YANO; MATTHEW DAVE GOODMAN; PAUL VANNEST BRAUN |
| A self-assembled carbon structure such as a carbon opal is disclosed herein. The structure is composed of hydrophilic carbon spheres oriented in a periodic colloidal crystal structure, wherein the carbon spheres have a porous surface, wherein the carbons spheres have an average particle diameter less than 3000 nm. Also disclosed is an inverse opal structure that includes a plurality of voids in the structural material. The voids are regularly arranged in an ordered periodic structure, the voids having a spherical shape. The inverse opal structure has a specific surface area greater than 100 m2/g and method for making the same together with materials that employ the same. | ||||||
| 40 | METHOD FOR PRODUCING NANOPARTICLE SOLUTIONS BASED ON PULSED LASER ABLATION FOR FABRICATION OF THIN FILM SOLAR CELLS | US12951585 | 2010-11-22 | US20110192450A1 | 2011-08-11 | Bing LIU; Yong Che |
| A method of producing nanoparticles of solar light absorbing compound materials based on pulsed laser ablation is disclosed. The method uses irradiation of a target material of solar light absorbing compound material with a pulsed laser beam having a pulse duration of from 10 femtoseconds to 500 picoseconds to ablate the target thereby producing nanoparticles of the target. The nanoparticles are collected and a solution of the nanoparticles is applied to a substrate to produce a thin film solar cell. The method preserves the composition and structural crystalline phase of the starting target. The method is a much lower cost fabrication method for thin film solar cells. | ||||||
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