公开(公告)号：US07875311B1

公开(公告)日：2011-01-25

申请号：US12418648

申请日：2009-04-06

Applicant: Guillermo R Villalobos ,  Jasbinder S. Sanghera ,  Shyam S Bayya ,  Ishwar D. Aggarwal

Inventor： Guillermo R Villalobos ,  Jasbinder S. Sanghera ,  Shyam S Bayya ,  Ishwar D. Aggarwal

IPC: B05D7/00 ,  C04B35/04 ,  C01D3/02

CPC classification number: C04B35/443 ,  C04B35/62655 ,  C04B35/62828 ,  C04B35/62886 ,  C04B35/645 ,  C04B2235/3203 ,  C04B2235/444 ,  C04B2235/445 ,  C04B2235/5436 ,  C04B2235/72 ,  C04B2235/721 ,  C04B2235/9653

Abstract: A ceramic having at least about 90% by weight magnesium aluminate and having a bulk scattering and absorption loss of less than about 1/cm at any wavelength in a range of about 0.23 to about 5.3 microns or 0.2/cm at any wavelength in a range of about 0.27 to about 4.5 microns. A method of making a ceramic by providing a plurality of particles having a magnesium aluminate core and a fluoride salt coating; heating the particles in an oxidizing atmosphere to a temperature in the range of about 400° C. to about 750° C.; and sintering the particles to form a solid ceramic.

Abstract translation: 一种陶瓷，其具有至少约90重量％的铝酸镁，并且在任何波长范围内，在任何波长范围内，在约0.23至约5.3微米或0.2 /厘米范围内的体积散射和吸收损失小于约1 / 为约0.27至约4.5微米。 一种通过提供多个具有铝酸镁芯和氟化物盐涂层的颗粒来制造陶瓷的方法; 将氧化气氛中的颗粒加热至约400℃至约750℃的温度; 并烧结颗粒以形成固体陶瓷。

公开(公告)号：US07873251B2

公开(公告)日：2011-01-18

申请号：US12765910

申请日：2010-04-23

Applicant: Shyam S. Bayya ,  Jasbinder S. Sanghera ,  Leslie Brandon Shaw ,  Ishwar D. Aggarwal

Inventor： Shyam S. Bayya ,  Jasbinder S. Sanghera ,  Leslie Brandon Shaw ,  Ishwar D. Aggarwal

IPC: G02B6/02 ,  C03B37/022

CPC classification number: C03B37/02781 ,  C03B2201/78 ,  C03B2203/12 ,  C03B2203/14 ,  C03B2203/16 ,  C03B2203/42 ,  C03B2205/10 ,  C03C3/253 ,  C03C13/048 ,  G02B6/02328 ,  G02B6/02347

Abstract: A photonic band gap fiber and method of making thereof is provided. The fiber is made of a germanate glass comprising at least 30 mol % of a germanium oxide and has a longitudinal central opening, a microstructured region having a plurality of longitudinal surrounding openings, and a jacket. The air fill fraction of the microstructured region is at least about 90%. The fiber may be made by drawing a preform into a fiber, while applying gas pressure to the microstructured region. The air fill fraction of the microstructured region is changed during the drawing.

Abstract translation: 提供了一种光子带隙光纤及其制造方法。 纤维由包含至少30mol％的氧化锗的锗酸盐玻璃制成，并且具有纵向中心开口，具有多个纵向周围开口的微结构区域和护套。 微结构区域的空气填充部分至少约为90％。 纤维可以通过将预成型件拉入纤维中，同时向微结构化区域施加气体压力。 在绘图期间，微结构化区域的空气填充部分发生变化。

公开(公告)号：US20110002585A1

公开(公告)日：2011-01-06

申请号：US12645315

申请日：2009-12-22

Applicant: Daniel J. Gibson ,  Leslie Brandon Shaw ,  Jasbinder S. Sanghera ,  Frederic H. Kung ,  Ishwar D. Aggarwal

Inventor： Daniel J. Gibson ,  Leslie Brandon Shaw ,  Jasbinder S. Sanghera ,  Frederic H. Kung ,  Ishwar D. Aggarwal

IPC: G02B6/26 ,  C03B37/01 ,  C03B23/057

CPC classification number: G02B6/2856 ,  G02B6/102 ,  H01S3/06708 ,  H01S3/06737

Abstract: The present invention is generally directed to a device comprising multiple specialty glass optical fibers that combines several different mid-infrared optical signals from multiple optical fibers into one signal in a single optical fiber. In addition, the present invention provides for a method of making the device.

Abstract translation: 本发明一般涉及一种包括多个专用玻璃光纤的装置，其将来自多根光纤的多个不同的中红外光信号组合成单个光纤中的一个信号。 另外，本发明提供一种制造该装置的方法。

公开(公告)号：US07693388B1

公开(公告)日：2010-04-06

申请号：US12210467

申请日：2008-09-15

Applicant: Vinh Q Nguyen ,  Jasbinder S Sanghera ,  Ishwar D Aggarwal

Inventor： Vinh Q Nguyen ,  Jasbinder S Sanghera ,  Ishwar D Aggarwal

IPC: G02B6/00 ,  G02B6/02

CPC classification number: C03B37/01265 ,  C03B2201/86 ,  C03C3/321 ,  C03C13/043

Abstract: A thermally stable chalcogenide glass, a process for making the same, and an optical fiber drawn therefrom are provided. A chalcogenide glass having the composition Ge(5−y)As(32−x)Se(59+x)Te(4+y) (0≦y≦1 and 0≦x≦2) is substantially free from crystallization when it is heated past the glass transition temperature Tg or drawn into optical fibers. A process for making the thermally stable chalcogenide glass includes purifying the components to remove oxides and scattering centers, batching the components in a preprocessed distillation ampoule, gettering oxygen impurities from the mixture, and heating the components to form a glass melt. An optical fiber formed from the chalcogenide glass is substantially free from crystallization and exhibits low signal loss in the near-infrared region, particularly at wavelengths of about 1.55 μm.

Abstract translation: 提供了热稳定的硫族化物玻璃，其制造方法和从其中提取的光纤。 具有Ge（5-y）As（32-x）Se（59 + x）Te（4 + y）（0＆nlE; y＆nlE; 1和0＆nlE; x＆nlE; 2）组成的硫族化物玻璃基本上没有结晶 被加热超过玻璃化转变温度Tg或拉制成光纤。 制造热稳定的硫族化物玻璃的方法包括纯化组分以除去氧化物和散射中心，将组分在预处理的蒸馏安瓿中进行配料，从混合物中吸收氧杂质，并加热组分以形成玻璃熔体。 由硫族化物玻璃形成的光纤基本上没有结晶，并且在近红外区域特别是在约1.55μm的波长下表现出低信号损失。

公开(公告)号：US20100067862A1

公开(公告)日：2010-03-18

申请号：US12210467

申请日：2008-09-15

Applicant: Vinh Q. Nguyen ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal

Inventor： Vinh Q. Nguyen ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal

IPC: G02B6/00 ,  C01B19/00 ,  C03B25/00 ,  C03B37/075

CPC classification number: C03B37/01265 ,  C03B2201/86 ,  C03C3/321 ,  C03C13/043

Abstract: A thermally stable chalcogenide glass, a process for making the same, and an optical fiber drawn therefrom are provided. A chalcogenide glass having the composition Ge(5−y)As(32−x)Se(59+x)Te(4+y) (0≦y≦1 and 0≦x≦2) is substantially free from crystallization when it is heated past the glass transition temperature Tg or drawn into optical fibers. A process for making the thermally stable chalcogenide glass includes purifying the components to remove oxides and scattering centers, batching the components in a preprocessed distillation ampoule, gettering oxygen impurities from the mixture, and heating the components to form a glass melt. An optical fiber formed from the chalcogenide glass is substantially free from crystallization and exhibits low signal loss in the near-infrared region, particularly at wavelengths of about 1.55 μm.

Abstract translation: 提供了热稳定的硫族化物玻璃，其制造方法和从其中提取的光纤。 具有Ge（5-y）As（32-x）Se（59 + x）Te（4 + y）（0＆nlE; y＆nlE; 1和0＆nlE; x＆nlE; 2）组成的硫族化物玻璃基本上没有结晶 被加热超过玻璃化转变温度Tg或拉制成光纤。 制造热稳定的硫族化物玻璃的方法包括纯化组分以除去氧化物和散射中心，将组分在预处理的蒸馏安瓿中进行配料，从混合物中吸收氧杂质，并加热组分以形成玻璃熔体。 由硫族化物玻璃形成的光纤基本上没有结晶，并且在近红外区域特别是在约1.55μm的波长下表现出低信号损失。

公开(公告)号：US20100022378A1

公开(公告)日：2010-01-28

申请号：US12179797

申请日：2008-07-25

Applicant: Vinh Q. Nguyen ,  Jasbinder S. Sanghera ,  Shyam S. Bayya ,  Geoff Chin ,  Ishwar D. Aggarwal

Inventor： Vinh Q. Nguyen ,  Jasbinder S. Sanghera ,  Shyam S. Bayya ,  Geoff Chin ,  Ishwar D. Aggarwal

IPC: C03C3/32 ,  C03B37/075

CPC classification number: C03B5/2252 ,  C03B5/06 ,  C03B2201/86 ,  C03B2211/00 ,  C03C3/32 ,  Y02P40/57

Abstract: The present invention is generally directed to a method of making chalcogenide glasses including holding the melt in a vertical furnace to promote homogenization and mixing; slow cooling the melt at less than 10° C. per minute; and sequentially quenching the melt from the top down in a controlled manner. Additionally, the present invention provides for the materials produced by such method. The present invention is also directed to a process for removing oxygen and hydrogen impurities from chalcogenide glass components using dynamic distillation.

Abstract translation: 本发明一般涉及一种制备硫族化物玻璃的方法，包括将熔体保持在立式炉中以促进均质化和混合; 以低于每分钟10℃的速度缓慢冷却熔体; 并且以受控的方式从上到下依次淬火熔体。 此外，本发明提供了通过这种方法制造的材料。 本发明还涉及使用动态蒸馏从硫族化物玻璃组分中除去氧和氢杂质的方法。

公开(公告)号：US07403326B2

公开(公告)日：2008-07-22

申请号：US11296714

申请日：2005-12-02

Applicant: Brandon Shaw ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal ,  Peter A. Thielen

Inventor： Brandon Shaw ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal ,  Peter A. Thielen

IPC: G02F1/01 ,  G02F1/35 ,  G02F2/02 ,  G02B6/00 ,  H01S3/30

CPC classification number: H01S3/2383 ,  F41G7/00 ,  F41G7/004 ,  G01S3/7803 ,  H01S3/067 ,  H01S3/06754 ,  H01S3/094061 ,  H01S3/1022 ,  H01S3/1603 ,  H01S3/1613 ,  H01S3/1616 ,  H01S2303/00 ,  H04N9/31 ,  Y10S385/901

Abstract: This invention pertains to a scene projection system and a method for projecting a scene that can simulate light temperature of above 2000 K. The system comprises of a light source part for generating light at a lower wavelength; a means part for individually controlling dynamic range, contrast, brightness, temporal characteristics and temporal dynamics of the light; a rare earth doped fiber part that re-emits the output light at a higher wavelength; and a means part for conveying light between its parts. The method comprises steps of generating light at a lower wavelength; individually controlling temporal characteristics, temporal dynamics, brightness and contrast of the light; passing the light through a rare earth-doped fiber; and re-emitting the light at a higher wavelength.

Abstract translation: 本发明涉及场景投影系统和投影场景的方法，该场景可模拟2000K以上的光温。该系统包括用于产生较低波长的光的光源部分; 用于单独控制光的动态范围，对比度，亮度，时间特性和时间动态的装置部分; 稀土掺杂光纤部件，其以更高的波长重新发射输出光; 以及用于在其部分之间传送光的装置部分。 该方法包括产生较低波长的光的步骤; 单独控制光的时间特征，时间动力学，亮度和对比度; 将光通过稀土掺杂光纤; 并重新发射较高波长的光。

公开(公告)号：US07295740B2

公开(公告)日：2007-11-13

申请号：US11623359

申请日：2007-01-16

Applicant: Jasbinder S Sanghera ,  Pablo C Pureza ,  Frederic H Kung ,  Daniel Gibson ,  Leslie Brandon Shaw ,  Ishwar D Aggarwal

Inventor： Jasbinder S Sanghera ,  Pablo C Pureza ,  Frederic H Kung ,  Daniel Gibson ,  Leslie Brandon Shaw ,  Ishwar D Aggarwal

IPC: G02B6/02

CPC classification number: G02B6/02328 ,  C03B37/0122 ,  C03B37/01274 ,  C03B37/025 ,  C03B37/02781 ,  C03B2201/60 ,  C03B2201/62 ,  C03B2201/70 ,  C03B2201/78 ,  C03B2201/80 ,  C03B2201/84 ,  C03B2201/86 ,  C03B2201/88 ,  C03B2203/12 ,  C03B2203/14 ,  C03B2203/16 ,  C03B2203/42 ,  C03B2205/10 ,  C03C11/00 ,  C03C13/043 ,  G02B6/02347 ,  G02B6/02361 ,  G02B6/02371

Abstract: A photonic band gap fiber and method of making thereof is provided. The fiber is made of a non-silica-based glass and has a longitudinal central opening, a microstructured region having a plurality of longitudinal surrounding openings, and a jacket. The air fill fraction of the microstructured region is at least about 40%. The fiber may be made by drawing a preform into a fiber, while applying gas pressure to the microstructured region. The air fill fraction of the microstructured region is changed during the drawing.

Abstract translation: 提供了一种光子带隙光纤及其制造方法。 纤维由非二氧化硅基玻璃制成并具有纵向中心开口，具有多个纵向周围开口的微结构区域和护套。 微结构区域的空气填充部分为至少约40％。 纤维可以通过将预成型件拉入纤维中，同时向微结构化区域施加气体压力。 在绘图期间，微结构化区域的空气填充部分发生变化。

公开(公告)号：US07285509B2

公开(公告)日：2007-10-23

申请号：US10758750

申请日：2004-01-15

Applicant: Shyam S. Bayya ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal

Inventor： Shyam S. Bayya ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal

IPC: C03C3/253

CPC classification number: C03C3/253 ,  C03C3/23

Abstract: This invention pertains to a BGG glass material with excellent optical and mechanical properties and to a method for its preparation characterized by the use of a halogen component. The BGG glass material is essentially devoid of water, has excellent optical transmission in the visible and mid-infrared wavelength range, and can be easily molded in small and large sizes and complex shapes at a low cost.

Abstract translation: 本发明涉及具有优异的光学和机械性能的BGG玻璃材料及其制备方法，其特征在于使用卤素组分。 BGG玻璃材料基本上没有水，在可见光和中红外波长范围内具有优异的光学透射率，并且可以以低成本容易地以小尺寸和大尺寸和复杂形状模制。

公开(公告)号：US6145342A

公开(公告)日：2000-11-14

申请号：US16334

申请日：1998-01-30

Applicant: Shyam S. Bayya ,  Cathy S. Scotto ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal

Inventor： Shyam S. Bayya ,  Cathy S. Scotto ,  Jasbinder S. Sanghera ,  Ishwar D. Aggarwal

IPC: C03B8/02 ,  C03C1/00 ,  C03C3/32 ,  C03C17/02

CPC classification number: C03C1/006 ,  C03C17/02 ,  C03C3/321 ,  C03C2217/287 ,  C03C2218/113 ,  Y10S65/15

Abstract: Sol-gel process conducted under an inert gas in a solvent at a temperature up to the boiling points of the solvent and by-products by reacting a chalcogen source, a glass network former-intermediate metal in the form of an alkoxide or a non-alkoxide and a catalyst to form a homogeneous product having average particle size of below 100 nm with catalyst, if the catalyst is a catalyst dopant, uniformly dispersed in the particles.

Abstract translation: 溶胶 - 凝胶法在惰性气体溶剂中，在溶剂沸点和副产物的温度下，通过使硫族元素源，醇盐形式的无机玻璃网络前体 - 中间体金属反应， 醇盐和催化剂，如果催化剂是催化剂掺杂剂，均匀分散在颗粒中，则用催化剂形成平均粒度小于100nm的均相产物。