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21. 发明申请

US20070222353A1 Device and method for achieving enhanced field emission utilizing nanostructures grown on a conductive substrate 失效
标题翻译：用于通过在导电基底上生长的纳米结构实现增强的场发射的装置和方法
公开(公告)号：US20070222353A1
公开(公告)日：2007-09-27
申请号：US11651267
申请日：2007-01-09
申请人： Zhifeng Ren , Sung Jo , Debasish Banerjee
发明人： Zhifeng Ren , Sung Jo , Debasish Banerjee
IPC分类号： H01J1/02
CPC分类号： H01J1/304 , B82Y10/00 , H01J2201/30469 , H01L2924/0002 , H01L2924/00
摘要： A device and method is presented for achieving a high field emission from the application of a low electric field. More specifically, the device includes a substrate wherein a plurality of nanostructures are grown on the substrate. The relationship of the nanostructures and the substrate (the relationship includes the number of nanostructures on the substrate, the orientation of the nanostructures in relationship to each other and in relationship to the substrate, the geometry of the substrate, the morphology of the nanostructures and the morphology of the substrate, the manner in which nanostructures are grown on the substrate, the composition of nanostructure and composition of substrate, etc) allow for the generation of the high field emission from the application of the low electric field.
摘要翻译：提出了一种用于实现低电场应用的高场发射的装置和方法。更具体地，该器件包括其中在衬底上生长多个纳米结构的衬底。纳米结构和衬底的关系（该关系包括衬底上的纳米结构的数量，纳米结构的取向彼此关系并且与衬底的关系，衬底的几何形状，纳米结构的形态和衬底的形态，纳米结构在衬底上生长的方式，纳米结构的组成和衬底的组成等）允许从低电场的应用产生高场发射。

22. 发明授权

US10067265B2 Semi-transparent reflectors 有权
公开(公告)号：US10067265B2
公开(公告)日：2018-09-04
申请号：US12902763
申请日：2010-10-12
申请人： Benjamin Alan Grayson , Debasish Banerjee , Masahiko Ishii
发明人： Benjamin Alan Grayson , Debasish Banerjee , Masahiko Ishii
IPC分类号： G02B5/10 , G02B1/00 , G02B5/08 , G02B1/10
CPC分类号： G02B1/005 , G02B1/10 , G02B5/0825 , G02B5/0833
摘要： In one embodiment, a semi-transparent reflector may include a multilayered photonic structure. The multilayered photonic structure includes a plurality of coating layers of high index dielectric material and a plurality of coating layers of low index dielectric material. The plurality of coating layers of high index dielectric material and the plurality of coating layers of low index dielectric material of the multilayered photonic structure are arranged in an [LH . . . (LH)N . . . L] structure. L is one of the plurality of coating layers of low index dielectric material. H is one of the plurality of coating layers of high index dielectric material. N is a positive integer. The multilayered photonic structure has substantially constant reflectance values for wavelengths of electromagnetic radiation in a visible spectrum over a range of angles of incidence of the electromagnetic radiation.

23. 发明授权

US09978924B2 Method of producing thermoelectric material 有权
公开(公告)号：US09978924B2
公开(公告)日：2018-05-22
申请号：US13166860
申请日：2011-06-23
申请人： Debasish Banerjee , Minjuan Zhang , Takuji Kita
发明人： Debasish Banerjee , Minjuan Zhang , Takuji Kita
IPC分类号： H01L35/12 , H01L35/26 , H01L35/22 , C01B19/00 , H01L35/14 , H01L35/34
CPC分类号： H01L35/26 , C01B19/007 , H01L35/14 , H01L35/22 , H01L35/34
摘要： A process for manufacturing a nanocomposite thermoelectric material having a plurality of nanoparticle inclusions. The process includes determining a material composition to be investigated for the nanocomposite thermoelectric material, the material composition including a conductive bulk material and a nanoparticle material. In addition, a range of surface roughness values for the insulating nanoparticle material that can be obtained using current state of the art manufacturing techniques is determined. Thereafter, a plurality of Seebeck coefficients, electrical resistivity values, thermal conductivity values and figure of merit values as a function of the range of nanoparticle material surface roughness values is calculated. Based on these calculated values, a nanocomposite thermoelectric material composition or ranges of compositions is/are selected and manufactured.

24. 发明授权

US09229140B2 Omnidirectional UV-IR reflector 有权
标题翻译：全向UV-IR反射器
公开(公告)号：US09229140B2
公开(公告)日：2016-01-05
申请号：US13014398
申请日：2011-01-26
申请人： Debasish Banerjee , Minjuan Zhang , Masahiko Ishii
发明人： Debasish Banerjee , Minjuan Zhang , Masahiko Ishii
IPC分类号： G02B1/00 , G02B5/28
CPC分类号： G02B5/281 , G02B5/282 , G02B5/283 , G02B5/285
摘要： The present invention provides an omnidirectional ultraviolet (UV)-infrared (IR) reflector. The omnidirectional UV-IR reflector includes a multilayer stack having at least three layers, the at least three layers having at least one first index of refraction material A1 and at least one second index of refraction layer B1. The at least one first index of refraction material layer and the at least one second index of refraction material layer can be alternately stacked on top of each other to provide the at least three layers. In addition, the at least one first index of refraction material layer and the at least one second index of refraction material layer each have a predefined thickness of dA1 and dB1, respectively, with the thickness dA1 not being generally equal to the dB1 thickness such that the multilayer stack has a non-periodic layered structure.
摘要翻译：本发明提供了全向紫外（UV） - 红外（IR）反射器。全向UV-IR反射器包括具有至少三层的多层堆叠，所述至少三层具有至少一个第一折射材料折射率A1和至少一个第二折射率折射率层B1。所述至少一个第一折射材料折射率层和所述至少一个第二折射材料折射率层可以交替地堆叠在彼此的顶部以提供所述至少三个层。另外，折射材料层和至少一个第二折射材料层的至少一个第一折射率分别具有dA1和dB1的预定厚度，其厚度dA1通常不等于dB1厚度，使得多层堆叠具有非周期性分层结构。

25. 发明授权

US08861087B2 Multi-layer photonic structures having omni-directional reflectivity and coatings incorporating the same 有权
标题翻译：具有全向反射率的多层光子结构和包含其的涂层
公开(公告)号：US08861087B2
公开(公告)日：2014-10-14
申请号：US12389221
申请日：2009-02-19
申请人： Debasish Banerjee , Benjamin Alan Grayson , Minjuan Zhang , Masahiko Ishii
发明人： Debasish Banerjee , Benjamin Alan Grayson , Minjuan Zhang , Masahiko Ishii
IPC分类号： G02B1/10 , G02B5/28 , G02B5/08 , G02B5/26
CPC分类号： G02B5/0825 , G02B1/115 , G02B5/0833 , G02B5/26 , G02B5/28 , G02B13/14 , G02B13/143 , Y10T428/24942
摘要： A multi-layer photonic structure may include alternating layers of high index material and low index material having a form [H(LH)N] where, H is a layer of high index material, L is a layer of low index material and N is a number of pairs of layers of high index material and layers of low index material. N may be an integer ≧1. The low index dielectric material may have an index of refraction nL from about 1.3 to about 2.5. The high index dielectric material may have an index of refraction nH from about 1.8 to about 3.5, wherein nH>nL and the multi-layer photonic structure comprises a reflectivity band of greater than about 200 nm for light having angles of incidence from about 0 degrees to about 80 degrees relative to the multi-layer photonic structure. The multi-layer photonic structure may be incorporated into a paint or coating system thereby forming an omni-directional reflective paint or coating.
摘要翻译：多层光子结构可以包括具有[H（LH）N]形式的高折射率材料和低折射率材料的交替层，其中H是高折射率材料层，L是低折射率材料层，N是多层高指数材料和低折射率材料层。 N可以是≧1的整数。低折射率介电材料可以具有约1.3至约2.5的折射率nL。高折射率介电材料可以具有约1.8至约3.5的折射率nH，其中对于具有大约0度的入射角的光，nH> nL和多层光子结构包括大于约200nm的反射带到大约80度相对于多层光子结构。多层光子结构可以结合到涂料或涂料体系中，从而形成全向反射涂料或涂料。

26. 发明授权

US08749881B2 Narrow band omnidirectional reflectors and their use as structural colors 有权
标题翻译：窄带全向反射器及其作为结构颜色的用途
公开(公告)号：US08749881B2
公开(公告)日：2014-06-10
申请号：US12388395
申请日：2009-02-18
申请人： Debasish Banerjee , Masahiko Ishii , Minjuan Zhang
发明人： Debasish Banerjee , Masahiko Ishii , Minjuan Zhang
IPC分类号： F21V9/06
CPC分类号： G02B5/26 , G02B5/0825 , G02B5/0833
摘要： Disclosed is a multilayer structure wherein a first layer of a first material having an outer surface and a refracted index between 2 and 4 extends across an outer surface of a second layer having a refractive index between 1 and 3. The multilayer stack has a reflective band of less than 200 nanometers when viewed from angles between 0° and 80° and can be used to reflect a narrow range of electromagnetic radiation in the ultraviolet, visible and infrared spectrum ranges. In some instances, the reflection band of the multilayer structure is less than 100 nanometers. In addition, the multilayer structure can have a quantity defined as a range to mid-range ratio percentage of less than 2%.
摘要翻译：公开了一种多层结构，其中具有外表面和2和4之间的折射率的第一材料的第一层延伸穿过折射率在1和3之间的第二层的外表面。多层堆叠具有反射带从0°到80°之间的角度观察时，小于200纳米，可用于在紫外线，可见光和红外光谱范围内反射窄范围的电磁辐射。在一些情况下，多层结构的反射带小于100纳米。此外，多层结构可以具有定义为中等范围比例百分比的范围小于2％的量。

27. 发明申请

US20130003245A1 FOCUSING DEVICE FOR LOW FREQUENCY OPERATION 有权
标题翻译：用于低频操作的聚焦装置
公开(公告)号：US20130003245A1
公开(公告)日：2013-01-03
申请号：US13172109
申请日：2011-06-29
申请人： Debasish Banerjee , Hideo Iizuka , Jaewook Lee , Ercan Mehmet Dede
发明人： Debasish Banerjee , Hideo Iizuka , Jaewook Lee , Ercan Mehmet Dede
IPC分类号： H01F13/00
CPC分类号： G02B1/002 , G01R33/38 , G02B3/08 , G02B5/3058
摘要： An example apparatus for obtaining a desired magnetic field distribution from an incident magnetic field, such as a kHz magnetic field, comprises a structure receiving the incident magnetic field and generating the desired magnetic field distribution at a predetermined distance from the transmitting side of the apparatus. The desired magnetic field distribution results from a spatial distribution of induced electrical current over the structure. Examples of the invention also include design methods and methods of using the apparatus.
摘要翻译：用于从诸如kHz磁场的入射磁场获得期望的磁场分布的示例性装置包括接收入射磁场并在与设备的发射侧预定距离处产生期望的磁场分布的结构。所需的磁场分布来自结构上的感应电流的空间分布。本发明的实例还包括使用该装置的设计方法和方法。

28. 发明申请

US20120307369A1 OMNIDIRECTIONAL REFLECTOR 审中-公开
公开(公告)号：US20120307369A1
公开(公告)日：2012-12-06
申请号：US13572071
申请日：2012-08-10
申请人： Debasish Banerjee , Minjuan Zhang , Songtao Wu , Masahiko Ishii
发明人： Debasish Banerjee , Minjuan Zhang , Songtao Wu , Masahiko Ishii
IPC分类号： G06F17/50 , G02B5/28
CPC分类号： G02B5/285 , G02B5/0833 , G02B5/085 , G02B5/286 , G02B27/0012
摘要： A process for designing and manufacturing an omnidirectional structural color (OSC) multilayer stack. The process can include providing a digital processor operable to execute at least one module and a table of index of refraction values corresponding to different materials that are usable for manufacturing an OSC multilayer stack. An initial design for the OSC multilayer stack can be provided and at least one additional layer is added to the initial design OSC multilayer stack to create a modified OSC multilayer stack. In addition, the thickness of each layer of the modified OSC multilayer stack is calculated using a merit function module until an optimized OSC multilayer stack has been calculated.
摘要翻译：一种设计和制造全向结构颜色（OSC）多层堆叠的方法。该过程可以包括提供可操作以执行至少一个模块的数字处理器和对应于可用于制造OSC多层堆叠的不同材料的折射率值的表。可以提供用于OSC多层堆叠的初始设计，并且至少一个附加层被添加到初始设计OSC多层堆叠中以创建修改的OSC多层堆叠。此外，使用优点功能模块计算修改的OSC多层叠层的每层的厚度，直到已经计算了优化的OSC多层堆叠。

29. 发明申请

US20120298928A1 METHOD OF PRODUCING THERMOELECTRIC MATERIAL 有权
标题翻译：生产热电材料的方法
公开(公告)号：US20120298928A1
公开(公告)日：2012-11-29
申请号：US13548395
申请日：2012-07-13
申请人： Michael Paul Rowe , Li Qin Zhou , Minjuan Zhang , Debasish Banerjee
发明人： Michael Paul Rowe , Li Qin Zhou , Minjuan Zhang , Debasish Banerjee
IPC分类号： H01B1/06 , B82Y30/00
CPC分类号： H01L35/26 , B82Y30/00 , H01L35/16 , H01L35/18 , Y10S977/779 , Y10S977/833
摘要： A thermoelectric material is provided. The material can be a grain boundary modified nanocomposite that has a plurality of bismuth antimony telluride matrix grains and a plurality of zinc oxide nanoparticles within the plurality of bismuth antimony telluride matrix grains. In addition, the material has zinc antimony modified grain boundaries between the plurality of bismuth antimony telluride matrix grains.
摘要翻译：提供热电材料。该材料可以是在多个铋碲化铋基体晶粒内具有多个铋碲化锑基体晶粒和多个氧化锌纳米粒子的晶界改性纳米复合材料。此外，该材料在多个铋锑碲化物基质颗粒之间具有锌锑改性的晶界。

30. 发明申请

US20120298924A1 METHOD OF PRODUCING THERMOELECTRIC MATERIAL 审中-公开
标题翻译：生产热电材料的方法
公开(公告)号：US20120298924A1
公开(公告)日：2012-11-29
申请号：US13117286
申请日：2011-05-27
申请人： Debasish Banerjee , Minjuan Zhang , Takuji Kita
发明人： Debasish Banerjee , Minjuan Zhang , Takuji Kita
IPC分类号： H01B1/00 , B82Y40/00
CPC分类号： H01B1/02 , B82Y40/00 , H01L35/26 , H01L35/34
摘要： A process for manufacturing a thermoelectric material having a plurality of grains and grain boundaries. The process includes determining a material composition to be investigated for the thermoelectric material and then determining a range of values of grain size and/or grain boundary barrier height obtainable for the material composition using current state of the art manufacturing techniques. Thereafter, a range of figure of merit values for the material composition is determined as a function of the range of values of grain size and/or grain boundary barrier height. And finally, a thermoelectric material having the determined material composition and an average grain size and grain boundary barrier height corresponding to the maximum range of figure of merit values is manufactured.
摘要翻译：一种具有多个晶粒和晶界的热电材料的制造方法。该方法包括确定要研究的热电材料的材料组成，然后确定使用现有技术制造技术的材料组合物可获得的晶粒尺寸和/或晶界势垒高度的范围。此后，根据晶粒尺寸和/或晶界势垒高度的值的范围确定材料组成的品质因数值的范围。最后，制造具有确定的材料组成和平均晶粒尺寸和晶界势垒高度对应于品质因数值的最大范围的热电材料。

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