公开(公告)号：US11952303B2

公开(公告)日：2024-04-09

申请号：US16062387

申请日：2016-12-16

Applicant: Heraeus Quarzglas GmbH & Co. KG

Inventor： Nigel Robert Whippey ,  Marcus Constantin Göbel ,  Boris Gromann ,  Gerrit Scheich

IPC: C03B20/00 ,  B01J2/04 ,  C03B5/08 ,  C03B17/04 ,  C03B19/10 ,  C03B37/012 ,  C03B37/027 ,  C03C3/06 ,  G02B6/02 ,  H01J61/30

CPC classification number: C03B20/00 ,  B01J2/04 ,  C03B5/08 ,  C03B17/04 ,  C03B19/106 ,  C03B19/108 ,  C03B19/1095 ,  C03B37/01211 ,  C03B37/01282 ,  C03B37/027 ,  C03C3/06 ,  G02B6/02042 ,  H01J61/302 ,  C03B2201/58

Abstract: A quartz glass body and a process for the preparation of a quartz glass body is disclosed. One process includes providing a silicon dioxide granulate from a pyrogenic silicon dioxide powder, making a glass melt out of the silicon dioxide granulate and making a quartz glass body out of at least part of the glass melt. In at least one process a silicon component different from silicon dioxide is added. A quartz glass body is obtainable by this process. A light guide, an illuminant and a formed body, are each obtainable by further processing of the quartz glass body.

公开(公告)号：US09650287B2

公开(公告)日：2017-05-16

申请号：US14564788

申请日：2014-12-09

Applicant: Platinum Optics Technology Inc.

Inventor： Chih-Chun Chiang

IPC: C03C3/078 ,  C03C4/02 ,  C03C3/089 ,  C03C4/10 ,  C03B19/02 ,  C03B25/02

CPC classification number: C03C4/02 ,  C03B19/02 ,  C03B25/02 ,  C03B2201/10 ,  C03B2201/30 ,  C03B2201/50 ,  C03B2201/54 ,  C03B2201/58 ,  C03C3/078 ,  C03C3/089 ,  C03C4/10 ,  C03C2204/00

Abstract: The present disclosure illustrates a composition of a visible light and infrared light transmitting optical colored glass. The chalcogenide semiconductor compound Cu2ZnSnS4 or Cu2ZnSnSe4 is added in the silicate glass system composition, to adjust color and the optical property of the glass. The glass made of this composition has a characteristic of the visible light and infrared light transmitting in a wavelength of range 400 nm to 1200 nm.

公开(公告)号：US20160060157A1

公开(公告)日：2016-03-03

申请号：US14564788

申请日：2014-12-09

Applicant: Platinum Optics Technology Inc.

Inventor： Chih-Chun CHIANG

IPC: C03C4/02 ,  C03B25/02 ,  C03B19/02 ,  C03C3/089 ,  C03C4/10

CPC classification number: C03C4/02 ,  C03B19/02 ,  C03B25/02 ,  C03B2201/10 ,  C03B2201/30 ,  C03B2201/50 ,  C03B2201/54 ,  C03B2201/58 ,  C03C3/078 ,  C03C3/089 ,  C03C4/10 ,  C03C2204/00

Abstract: The present disclosure illustrates a composition of a visible light and infrared light transmitting optical colored glass. The chalcogenide semiconductor compound Cu2ZnSnS4 or Cu2ZnSnSe4 is added in the silicate glass system composition, to adjust color and the optical property of the glass. The glass made of this composition has a characteristic of the visible light and infrared light transmitting in a wavelength of range 400 nm to 1200 nm.

Abstract translation: 本公开示出了可见光和红外光透射光学着色玻璃的组成。 在硅酸盐玻璃体系组合物中加入硫族化物半导体化合物Cu2ZnSnS4或Cu2ZnSnSe4，以调节玻璃的颜色和光学性质。 由该组合物制成的玻璃具有在400nm至1200nm的波长范围内透射的可见光和红外光的特性。

公开(公告)号：US20110158595A1

公开(公告)日：2011-06-30

申请号：US12735569

申请日：2009-01-27

Applicant: Ekaterina Burov ,  Alain Pastouret ,  Christian Simonneau ,  Laurent Gasca ,  Christine Collet

Inventor： Ekaterina Burov ,  Alain Pastouret ,  Christian Simonneau ,  Laurent Gasca ,  Christine Collet

IPC: G02B6/02 ,  H01S3/067 ,  B82Y20/00

CPC classification number: G02B6/0229 ,  B82Y20/00 ,  B82Y30/00 ,  C03B37/01838 ,  C03B2201/34 ,  C03B2201/36 ,  C03B2201/58 ,  C03C3/06 ,  C03C4/0071 ,  C03C4/10 ,  C03C4/12 ,  C03C13/045 ,  C03C14/004 ,  C03C14/006 ,  C03C2201/30 ,  C03C2201/34 ,  C03C2201/3476 ,  C03C2201/36 ,  C03C2203/40 ,  H01S3/06716 ,  H01S3/06754 ,  H01S3/0933 ,  H01S3/094003 ,  H01S3/1608 ,  H01S3/169

Abstract: The invention relates to an optical waveguide, in particular an optical fibre comprising a core, formed from a material based on rare-earth-ion-doped silica, covered by an optical cladding. Nanoparticles, at least some of which are metal nanoparticles, are dispersed in the material of the core. The optical devices, such as especially optical amplifiers, comprise an optical fibre having a core formed, from a material based on rare-earth-ion-doped silica covered with an optical cladding, nanoparticles, at least some of which are metal nanoparticles, being dispersed in the material of the core, and a pumping source delivering electromagnetic excitation radiation, which propagates in the core.

Abstract translation: 本发明涉及光波导，特别是包括由由光电覆层覆盖的基于稀土离子掺杂的二氧化硅的材料形成的芯的光纤。 其中至少一些是金属纳米颗粒的纳米颗粒分散在芯的材料中。 诸如特别是光学放大器的光学器件包括具有由基于覆盖有光学包层的稀土离子掺杂的二氧化硅的材料形成的芯的光纤，纳米颗粒中的至少一些是金属纳米颗粒， 分散在芯的材料中，以及泵送源，其输送在芯中传播的电磁激发辐射。

公开(公告)号：US07799663B2

公开(公告)日：2010-09-21

申请号：US10595321

申请日：2004-10-08

Applicant: Pier John Anthony Sazio ,  John Victor Badding ,  Dan William Hewak

Inventor： Pier John Anthony Sazio ,  John Victor Badding ,  Dan William Hewak

IPC: H01L21/36 ,  H01L21/00

CPC classification number: G02B6/02385 ,  C03B19/00 ,  C03B37/0122 ,  C03B2201/58 ,  C03B2203/42 ,  C03C13/04 ,  C03C25/104 ,  C23C4/123 ,  C23C16/045 ,  C23C16/45557 ,  G02B1/002 ,  G02B6/0229 ,  G02B6/02352 ,  G02B6/02357 ,  G02B6/02371 ,  G02B6/0238 ,  Y10T428/24273

Abstract: A method of fabricating a semiconductor metamaterial is provided, comprising providing a sample of engineered microstructured material that is transparent to electromagnetic radiation and comprises one or more elongate, high aspect ratio voids, passing through the voids a high pressure fluid comprising a semiconductor material carried in a carrier fluid, and causing the semiconductor material to deposit onto the surface of the one or more voids of the engineered microstructured material to form the metamaterial. Many microstructured materials and semiconductor materials can be used, together with various techniques for controlling the location, spatial extent, and thickness of the deposition of the semiconductor within the microstructured material, so that a wide range of different metamaterials can be produced.

Abstract translation: 提供一种制造半导体超材料的方法，其包括提供对电磁辐射透明的工程化微结构材料的样品，并且包括一个或多个细长的高纵横比空隙，通过空隙将高压流体包含在 载体流体，并且使半导体材料沉积到工程化微结构材料的一个或多个空隙的表面上以形成超材料。 可以使用许多微结构材料和半导体材料以及用于控制半导体在微结构化材料内的沉积的位置，空间范围和厚度的各种技术，从而可以产生宽范围的不同的超材料。

公开(公告)号：US20060240968A1

公开(公告)日：2006-10-26

申请号：US11456659

申请日：2006-07-11

Applicant: Jochen Freund ,  Monika Gierke ,  Uwe Kolberg ,  Ruediger Hentschel ,  Rolf Clasen

Inventor： Jochen Freund ,  Monika Gierke ,  Uwe Kolberg ,  Ruediger Hentschel ,  Rolf Clasen

IPC: C03C3/115

CPC classification number: C03B19/12 ,  C03B2201/10 ,  C03B2201/12 ,  C03B2201/30 ,  C03B2201/50 ,  C03B2201/58 ,  C03C1/006 ,  C03C3/089

Abstract: The invention relates to a method for manufacturing optical glasses and coloured glasses with the aid of a fluid phase sintering process from a basic material encompassing at least SiO2 powder as well as additives for reducing the temperature of the fluid phase sintering and/or melting process encompassing the following steps: the starting materials are dissolved in any sequence in a fluid medium to produce a solution as far as is possible and a suspension to the extent that they are not dispersed in solution; a greenbody is produced from the dissolved and dispersed starting materials; the greenbody is dried the dried greenbody is fluid-phase sintered at temperatures below 1200° C., in particular in the temperature range from 600° C. to 1200° C.

Abstract translation: 本发明涉及一种借助于包含至少SiO 2粉末的基本材料的流体相烧结工艺以及用于降低流体温度的添加剂来制造光学眼镜和有色玻璃的方法 包括以下步骤：将起始材料以任何顺序溶解在流体介质中以尽可能地产生溶液，并将悬浮液悬浮至不分散在溶液中的程度; 生物体由溶解和分散的原料制成; 干燥的生物体干燥的生物体在低于1200℃的温度下进行流相相烧结，特别是在600℃至1200℃的温度范围内。

公开(公告)号：US20060196228A1

公开(公告)日：2006-09-07

申请号：US11358942

申请日：2006-02-21

Applicant: Yuichi Aoki

Inventor： Yuichi Aoki

IPC: C03B37/00 ,  C03C10/16

CPC classification number: C03C14/006 ,  C03B23/047 ,  C03B25/025 ,  C03B32/00 ,  C03B2201/58 ,  C03C4/00 ,  C03C19/00 ,  C03C23/007 ,  C03C2214/08 ,  C03C2214/30 ,  Y02P40/57

Abstract: A method for producing a polarizing glass wherein a glass preform containing metal halide particles having a prescribed particle size dispersed therein is heated to a prescribed temperature and elongated, to thereby form a glass sheet containing elongated metal halide particles, and then said metal halide particles are reduced to the metal, characterized in that the glass sheet having been heated and elongated is quenched and then subjected to an annealing treatment, and thereafter, the above metal halide particles are reduced to the metal. The method allows the removal of the stress which generates during the above heating and elongating treatment and residues in the glass sheet, without the reduction of the extinction ratio of the resultant glass sheet, which results in the production of a polarizing glass having good optical characteristics at a low cost.

公开(公告)号：US20060042323A1

公开(公告)日：2006-03-02

申请号：US11034156

申请日：2005-01-12

Applicant: Philipp Kornreich ,  Douglas Keller ,  James Flattery

Inventor： Philipp Kornreich ,  Douglas Keller ,  James Flattery

IPC: C03C25/46

CPC classification number: C03C25/52 ,  C03B37/026 ,  C03B37/027 ,  C03B2201/58 ,  C03B2203/10 ,  C03B2203/36 ,  C03C25/1063 ,  C03C25/42 ,  C03C25/46 ,  G02B6/02 ,  G02B6/02214 ,  G02B6/03622 ,  H01S3/06708

Abstract: A method of forming a preform which has a glass core surrounded by an outer glass cladding with a coating of a light interactive material disposed between the core and cladding. The method includes providing a glass core having a viscosity which lies within a given preselected temperature range, followed by forming a substantially homogeneous coating of a light interactive material over the surface of the core, with the coating material having a viscosity which is equal to or less than the viscosity of the glass core. A glass cladding is formed over the coated layer, with the cladding glass having a viscosity which overlaps the viscosity of the core glass and a thermal coefficient of expansion compatible with that of the core. The light interactive material is an inorganic material which includes a metal, metal alloy, ferrite, magnetic material and a semiconductor.

Abstract translation: 一种形成预成型体的方法，其具有由外部玻璃包层围绕的玻璃核，其具有设置在芯和包层之间的光交互材料的涂层。 该方法包括提供具有在给定的预选温度范围内的粘度的玻璃芯，随后在芯的表面上形成基本上均匀的光相互作用材料的涂层，涂层材料的粘度等于或等于 小于玻璃核心的粘度。 在涂层上形成玻璃包层，其中包层玻璃具有与芯玻璃的粘度重叠的粘度和与芯的玻璃的膨胀相容的热膨胀系数。 光交互材料是包括金属，金属合金，铁氧体，磁性材料和半导体的无机材料。

公开(公告)号：US20050135759A1

公开(公告)日：2005-06-23

申请号：US10744543

申请日：2003-12-22

Applicant: Xingwu Wang ,  Samuel DiVita ,  Howard Greenwald

Inventor： Xingwu Wang ,  Samuel DiVita ,  Howard Greenwald

IPC: C03B37/012 ,  C03B37/014 ,  C03C13/04 ,  C03C14/00 ,  G02B6/02 ,  G02F1/01 ,  G02F1/025 ,  G02F1/095 ,  G02F1/125

CPC classification number: G02B6/02328 ,  B82Y15/00 ,  B82Y20/00 ,  B82Y25/00 ,  C03B37/01282 ,  C03B37/01413 ,  C03B2201/32 ,  C03B2201/42 ,  C03B2201/58 ,  C03B2203/42 ,  C03C13/04 ,  C03C14/006 ,  G02B6/0229 ,  G02B6/02338 ,  G02B6/02357 ,  G02B6/02361 ,  G02F1/0115 ,  G02F1/025 ,  G02F1/095 ,  G02F1/125 ,  G02F2202/36

Abstract: A fiber assembly comprised of nanoparticles, wherein said nanoparticles are a mixture of nanomagnetic particles and nanooptical particles.

Abstract translation: 由纳米颗粒组成的纤维组合物，其中所述纳米颗粒是纳米磁性颗粒和纳米光学颗粒的混合物。

公开(公告)号：US06536236B2

公开(公告)日：2003-03-25

申请号：US09906182

申请日：2001-07-16

Applicant: David G. Grossman ,  Lisa R. Vandegrift ,  Joseph M. Williams ,  George N. Whitbred, III

Inventor： David G. Grossman ,  Lisa R. Vandegrift ,  Joseph M. Williams ,  George N. Whitbred, III

IPC: C03C2300

CPC classification number: C03C14/006 ,  C03B23/047 ,  C03B32/02 ,  C03B2201/20 ,  C03B2201/40 ,  C03B2201/58 ,  C03C2214/08 ,  C03C2214/30

Abstract: A method of producing a polarizing glass article that exhibits a broad band of high contrast polarizing properties in the infrared region of the radiation spectrum. The polarizing glass is phase-separated or exhibits photochromic properties based on silver, copper, or copper-cadmium halide crystals or a combination thereof, which are precipitated in the glass and having a size in the range of 200-5000 Å. The glass has a surface layer containing elongated silver, copper, or copper cadmium metal particles, or a mixture thereof. The method comprises subjecting the glass article to a time-temperature cycle in which the temperature is at least about 76° C. or greater above the glass softening point, in a step to thermally form and precipitate large halide crystals, and elongated metallic particles under a stress of not over about 3000 psi, preferably not over about 2675 psi.