公开(公告)号：US11746014B2

公开(公告)日：2023-09-05

申请号：US17414451

申请日：2020-11-20

申请人： IDEMITSU KOSAN CO., LTD.

发明人： Yusuke Iseki ,  Nobuhito Nakaya

IPC分类号： H01M10/0525 ,  H01M10/0562 ,  C01B17/20 ,  H01B1/10

CPC分类号： C01B17/20 ,  H01B1/10 ,  H01M10/0525 ,  H01M10/0562 ,  C01P2006/40 ,  H01M2300/0068

摘要： Disclosed is a method for producing a sulfide solid electrolyte including a step of processing a slurry by at least one treatment selected from drying and heating, wherein a solid electrolyte raw material containing a lithium element, a sulfur element, a phosphorus element and a halogen element, and a complexing agent are mixed in a reactor to give a complex slurry containing a complex formed of the solid electrolyte raw material and the complexing agent, and the complex slurry is transferred into an intermediate tank equipped with a cooling device and cooled therein.

公开(公告)号：US20190085238A1

公开(公告)日：2019-03-21

申请号：US15711180

申请日：2017-09-21

申请人： Raytheon Company

发明人： Stephanie J. Lin ,  James R. Chow ,  Kalin Spariosu

IPC分类号： C09K11/66 ,  H01L33/50 ,  F21K9/64 ,  F21V7/22 ,  C09K11/54

CPC分类号： C09K11/662 ,  B82Y20/00 ,  B82Y40/00 ,  C01B17/20 ,  C01B19/007 ,  C01G21/21 ,  C01P2002/84 ,  C01P2004/64 ,  C01P2004/84 ,  C01P2006/60 ,  C09K11/025 ,  C09K11/54 ,  C09K11/565 ,  C09K11/883 ,  F21K9/64 ,  F21V7/22 ,  F21Y2115/10 ,  H01L31/035218 ,  H01L33/502 ,  H01L2933/0041 ,  Y10S977/774 ,  Y10S977/825 ,  Y10S977/892 ,  Y10S977/95

摘要： In certain embodiments, a first semiconductor material is vaporized to generate a vapor phase condensate. The vapor phase condensate is allowed to form nanoparticles. The nanoparticles are annealed to yield nanoparticles or cores. The cores are overcoated by introducing a solution containing second semiconductor material precursors in a coordinating solvent into a suspension of cores at a desired elevated temperature and mixing for a period of time sufficient to cause diffusion of the shell into the core. The diffusion of the shell into the core causes the quantum dots to exhibit a broadened optical emission. The produced quantum dots may be incorporated into a quantum dot based radiation source.

公开(公告)号：US20170158976A1

公开(公告)日：2017-06-08

申请号：US14961969

申请日：2015-12-08

申请人： Chevron U.S.A. Inc.

发明人： Dennis John O'Rear ,  Joshua Allen Thompson ,  Cedrick Mahieux

IPC分类号： C10L3/10 ,  E21B43/34 ,  B01D11/04 ,  C10G29/12 ,  C10G29/16

CPC分类号： C10L3/101 ,  B01D11/0492 ,  C01B17/20 ,  C01B19/005 ,  C01G1/12 ,  C01G3/12 ,  C01G19/00 ,  C01G39/06 ,  C01G49/12 ,  C09K8/52 ,  C09K2208/22 ,  C10G29/12 ,  C10G29/16 ,  C10L3/107 ,  C10L2230/02 ,  C10L2230/14 ,  C10L2290/141 ,  C10L2290/542 ,  E21B21/068 ,  E21B43/34

摘要： A sulfidic complexing agent is disclosed that includes a suspension or a solution formed by a reaction between a water-soluble metal compound and a water-soluble sulfidic compound. The sulfidic complexing agent has a pH of from about 5 to about 11 and a molar ratio of metal to sulfur of from about 0.1 to about 1,000. The sulfidic complexing agent is useful for removing elemental mercury from a hydrocarbon fluid by contacting the hydrocarbon fluid with the sulfidic complexing agent. The molar ratio of sulfur in the sulfidic complexing agent to mercury in the hydrocarbon fluid is from about 50 to about 2,500. Also disclosed is a method for concurrently transporting and removing a trace amount of volatile mercury in a CO2-containing natural gas stream extracted from a subterranean formation. The natural gas stream is transported in a pipeline into which the sulfidic complexing agent is injected. Also disclosed is a method for capturing gas phase elemental mercury from a gas stream in the overhead section of a crude oil distillation unit by contacting the gas stream with the sulfidic complexing agent in the overhead section of the distillation unit to form a treated gas stream.

公开(公告)号：US09620813B2

公开(公告)日：2017-04-11

申请号：US14209611

申请日：2014-03-13

申请人： KABUSHIKI KAISHA TOSHIBA

发明人： Keigo Hoshina ,  Hiroki Inagaki ,  Norio Takami

IPC分类号： H01M10/0562 ,  H01M10/052 ,  H01B1/10 ,  C01B17/20 ,  C01B17/22 ,  C01B25/14 ,  H01M4/131

CPC分类号： H01M10/0562 ,  C01B17/20 ,  C01B17/22 ,  C01B25/14 ,  C01G23/005 ,  C01G51/42 ,  C01P2002/50 ,  C01P2002/54 ,  C01P2006/40 ,  H01B1/10 ,  H01M2/1077 ,  H01M4/131 ,  H01M4/485 ,  H01M4/525 ,  H01M10/052 ,  H01M10/0525 ,  H01M10/0561 ,  H01M10/425 ,  H01M2220/20 ,  H01M2300/0065 ,  H01M2300/0068 ,  Y02T10/7011

摘要： According to one embodiment, a solid electrolyte secondary battery includes a positive electrode containing an active material, a negative electrode containing an active material, and a solid electrolyte layer. The solid electrolyte layer includes a lithium-ion conductive sulfide containing at least one element selected from a group consisting of Al, Si, Fe, Ni, and Zr, the total content of the element in the lithium-ion conductive sulfide is 0.03% by mass or more and 0.3% by mass or less.

公开(公告)号：US09441156B2

公开(公告)日：2016-09-13

申请号：US14472453

申请日：2014-08-29

申请人： Massachusetts Institute of Technology

发明人： Moungi G. Bawendi ,  Klavs F. Jensen ,  Bashir O. Dabbousi ,  Javier Rodriguez-Viejo ,  Frederic Victor Mikulec

IPC分类号： H01L21/00 ,  C09K11/88 ,  B82Y30/00 ,  C01B17/20 ,  C01B19/00 ,  C07F9/22 ,  C07F9/53 ,  C09K11/02 ,  C09K11/56 ,  C09K11/89 ,  C30B7/00 ,  C30B7/14 ,  C30B29/46 ,  C30B29/48 ,  C30B29/60 ,  B82Y20/00

CPC分类号： C09K11/883 ,  B82Y20/00 ,  B82Y30/00 ,  C01B17/20 ,  C01B19/007 ,  C01P2002/72 ,  C01P2002/84 ,  C01P2004/04 ,  C01P2004/52 ,  C01P2004/64 ,  C01P2004/80 ,  C01P2004/86 ,  C01P2006/60 ,  C07F9/224 ,  C07F9/5304 ,  C09K11/02 ,  C09K11/565 ,  C09K11/885 ,  C09K11/892 ,  C30B7/00 ,  C30B7/14 ,  C30B29/46 ,  C30B29/48 ,  C30B29/60 ,  C30B29/605 ,  Y10S977/773 ,  Y10S977/774 ,  Y10S977/777 ,  Y10S977/813 ,  Y10S977/824 ,  Y10S977/832 ,  Y10T428/12035 ,  Y10T428/12049 ,  Y10T428/12181 ,  Y10T428/12986 ,  Y10T428/2982 ,  Y10T428/2991 ,  Y10T428/2993

摘要： A nanocrystal capable of light emission includes a nanoparticle having photoluminescence having quantum yields of greater than 30%.

公开(公告)号：US09263763B2

公开(公告)日：2016-02-16

申请号：US14365950

申请日：2012-12-21

申请人： TOYOTA JIDOSHA KABUSHIKI KAISHA ,  TOKYO INSTITUTE OF TECHNOLOGY

发明人： Masaaki Hirayama ,  Ryoji Kanno ,  Yuki Kato ,  Koji Kawamoto ,  Takamasa Otomo

IPC分类号： H01M10/0562 ,  H01M4/13 ,  H01M10/052 ,  H01B1/10 ,  C01B17/20 ,  C01G17/00

CPC分类号： H01M10/0562 ,  C01B17/20 ,  C01G17/006 ,  C01P2002/72 ,  C01P2002/74 ,  C01P2002/77 ,  H01B1/10 ,  H01M4/13 ,  H01M10/052 ,  H01M2300/0068 ,  Y02E60/122 ,  Y02P70/54 ,  Y02T10/7011

摘要： The object of the present invention is to provide a sulfide solid electrolyte material with favorable ion conductivity. The present invention attains the object by providing a sulfide solid electrolyte material including an M1 element (such as a Li element), an M2 element (such as a Ge element and a P element), a S element and an O element, and having a peak at a position of 2θ=29.58°±0.50° in an X-ray diffraction measurement using a CuKα ray, characterized in that when a diffraction intensity at the peak of 2θ=29.58°±0.50° is regarded as IA and a diffraction intensity at a peak of 2θ=27.33°±0.50° is regarded as IB, a value of IB/IA is less than 0.50.

摘要翻译： 本发明的目的是提供一种具有良好的离子传导性的硫化物固体电解质材料。 本发明的目的是提供一种含有M1元素（如Li元素），M2元素（如Ge元素和P元素），S元素和O元素的硫化物固体电解质材料，并具有 在使用CuKα射线的X射线衍射测定中，在2θ的位置处的峰值= 29.58°±0.50°，其特征在于当峰2处的衍射强度= 29.58°±0.50°被认为是IA， 在2峰处的衍射强度= 27.33°±0.50°被认为是IB，IB / IA的值小于0.50。

公开(公告)号：US09090468B2

公开(公告)日：2015-07-28

申请号：US12743989

申请日：2008-11-20

申请人： Zhigang Shen ,  Meng Tack Ng ,  Sung Lai Jimmy Yun ,  Jianfeng Chen ,  Yit Wooi Goh ,  Wei Kian Soh

发明人： Zhigang Shen ,  Meng Tack Ng ,  Sung Lai Jimmy Yun ,  Jianfeng Chen ,  Yit Wooi Goh ,  Wei Kian Soh

IPC分类号： C01B19/00 ,  C01B17/20 ,  B82Y30/00 ,  C01F17/00 ,  C01G3/02 ,  C01G9/02 ,  C01G49/08 ,  C09C3/08 ,  C09C3/12 ,  C09C1/04 ,  C09C1/24

CPC分类号： C01B17/20 ,  B82Y30/00 ,  C01F17/0043 ,  C01G3/02 ,  C01G9/02 ,  C01G49/08 ,  C01P2002/72 ,  C01P2004/04 ,  C01P2004/52 ,  C01P2004/64 ,  C01P2006/22 ,  C09C1/043 ,  C09C1/24 ,  C09C3/08 ,  C09C3/12

摘要： There is disclosed a process of making metal chalcogenide particles. The process comprises the steps of reacting a metal salt solution with a precipitant solution under conditions to form metal chalcogenide particles and by-product thereof, coating the metal chalcogenide particles with a surfactant; and separating the surfactant coated chalcogenide particles from the by-product to obtain metal chalcogenide particles substantially free of by-product.

摘要翻译： 公开了制备金属硫族化物颗粒的方法。 该方法包括在形成金属硫族化物颗粒及其副产物的条件下使金属盐溶液与沉淀剂溶液反应的步骤，用表面活性剂涂覆金属硫族化物颗粒; 并从副产物中分离表面活性剂涂覆的硫族化物颗粒，得到基本上不含副产物的金属硫族化物颗粒。

公开(公告)号：US08951446B2

公开(公告)日：2015-02-10

申请号：US13365800

申请日：2012-02-03

申请人： Robert V. Fox ,  Rene Rodriguez ,  Joshua J. Pak ,  Chivin Sun

发明人： Robert V. Fox ,  Rene Rodriguez ,  Joshua J. Pak ,  Chivin Sun

IPC分类号： H01B1/02

CPC分类号： C01B17/20 ,  B82Y30/00 ,  C01B19/002 ,  C01P2002/30 ,  C01P2004/62 ,  C01P2004/64 ,  C01P2004/80 ,  C01P2006/80

摘要： Hybrid particles that comprise a coating surrounding a chalcopyrite material, the coating comprising a metal, a semiconductive material, or a polymer; a core comprising a chalcopyrite material and a shell comprising a functionalized chalcopyrite material, the shell enveloping the core; or a reaction product of a chalcopyrite material and at least one of a reagent, heat, and radiation. Methods of forming the hybrid particles are also disclosed.

摘要翻译： 包含围绕黄铜矿材料的涂层的混合颗粒，所述涂层包含金属，半导体材料或聚合物; 包含黄铜矿材料的核心和包含官能化黄铜矿材料的壳体，所述壳体包围所述核心; 或黄铜矿材料与试剂，热和辐射中的至少一种的反应产物。 还公开了形成杂化颗粒的方法。

公开(公告)号：US20140363745A1

公开(公告)日：2014-12-11

申请号：US14365950

申请日：2012-12-21

申请人： TOYOTA JIDOSHA KABUSHIKI KAISHA ,  TOKYO INSTITUTE OF TECHNOLOGY

发明人： Masaaki Hirayama ,  Ryoji Kanno ,  Yuki Kato ,  Koji Kawamoto ,  Takamasa Otomo

IPC分类号： H01M10/0562 ,  H01M10/052

CPC分类号： H01M10/0562 ,  C01B17/20 ,  C01G17/006 ,  C01P2002/72 ,  C01P2002/74 ,  C01P2002/77 ,  H01B1/10 ,  H01M4/13 ,  H01M10/052 ,  H01M2300/0068 ,  Y02E60/122 ,  Y02P70/54 ,  Y02T10/7011

摘要： The object of the present invention is to provide a sulfide solid electrolyte material with favorable ion conductivity. The present invention attains the object by providing a sulfide solid electrolyte material including an M1 element (such as a Li element), an M2 element (such as a Ge element and a P element), a S element and an O element, and having a peak at a position of 2θ=29.58°±0.50° in an X-ray diffraction measurement using a CuKα ray, characterized in that when a diffraction intensity at the peak of 2θ=29.58°±0.50° is regarded as IA and a diffraction intensity at a peak of 2θ=27.33°±0.50° is regarded as IB, a value of IB/IA is less than 0.50.

摘要翻译： 本发明的目的是提供一种具有良好的离子传导性的硫化物固体电解质材料。 本发明的目的是提供一种含有M1元素（如Li元素），M2元素（如Ge元素和P元素），S元素和O元素的硫化物固体电解质材料，并具有 在使用CuKα射线的X射线衍射测定中，在2θ的位置处的峰值= 29.58°±0.50°，其特征在于当峰2处的衍射强度= 29.58°±0.50°被认为是IA， 峰2处的衍射强度= 27.33°±0.50°被认为是IB，IB / IA的值小于0.50。

公开(公告)号：US20140322898A1

公开(公告)日：2014-10-30

申请号：US14261329

申请日：2014-04-24

申请人： Ravisubhash Tangirala ,  Delia J. Milliron ,  Anna Llordes

发明人： Ravisubhash Tangirala ,  Delia J. Milliron ,  Anna Llordes

IPC分类号： H01L21/02

CPC分类号： H01L21/02587 ,  B82Y30/00 ,  B82Y40/00 ,  C01B17/20 ,  C01B19/002 ,  C01B19/007 ,  C01G3/12 ,  C01G33/00 ,  C01P2002/72 ,  C01P2004/03 ,  C01P2004/04 ,  C01P2004/16 ,  C01P2004/32 ,  C04B35/62272 ,  C04B35/6264 ,  C04B35/632 ,  C04B2235/3284 ,  C04B2235/526 ,  C04B2235/5264 ,  H01B1/08 ,  H01B1/14 ,  H01L31/035227 ,  H01L31/0749 ,  Y02E10/541

摘要： An embodiment of an inorganic nanocomposite includes a nanoparticle phase and a matrix phase. The nanoparticle phase includes nanoparticles that are arranged in a repeating structure. In an embodiment, the nanoparticles have a spherical or pseudo-spherical shape and are incompatible with hydrazine. In another embodiment, the nanoparticles have neither a spherical nor pseudo-spherical shape. The matrix phase lies between the nanoparticles of the nanoparticle phase. An embodiment of a method of making an inorganic nanocomposite of the present invention includes forming a nanoparticle superlattice on a substrate. The nanoparticle superlattice includes nanoparticles. Each nanoparticle has organic ligands attached to a surface of the nanoparticle. The organic ligands separate adjacent nanoparticles within the nanoparticle superlattice. The method also includes forming a solution that includes an inorganic precursor. The nanoparticle superlattice is placed in the solution for a sufficient time for the inorganic precursor to replace the organic ligands.

摘要翻译： 无机纳米复合材料的一个实施方案包括纳米颗粒相和基质相。 纳米颗粒相包括以重复结构排列的纳米颗粒。 在一个实施方案中，纳米颗粒具有球形或假球形并且与肼不相容。 在另一个实施方案中，纳米颗粒既不具球形，也不具有假球形。 基质相位位于纳米颗粒相的纳米颗粒之间。 制备本发明的无机纳米复合材料的方法的一个实施方案包括在基材上形成纳米颗粒超晶格。 纳米颗粒超晶格包括纳米颗粒。 每个纳米颗粒具有连接到纳米颗粒表面的有机配体。 有机配体将纳米颗粒超晶格内的相邻纳米颗粒分开。 该方法还包括形成包含无机前体的溶液。 将纳米颗粒超晶格放置在溶液中足够的时间以使无机前体代替有机配体。