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1. 发明授权

US07857959B2 Methods of fabricating nanowires and electrodes having nanogaps 有权
标题翻译：制造纳米线的方法和具有纳米角的电极
公开(公告)号：US07857959B2
公开(公告)日：2010-12-28
申请号：US11804464
申请日：2007-05-18
申请人： John T. Fourkas , Michael J. Naughton , Richard A. Farrer
发明人： John T. Fourkas , Michael J. Naughton , Richard A. Farrer
IPC分类号： C25D5/02
CPC分类号： G01R33/093 , B82Y25/00 , C25D1/006 , C25D1/04 , C25D11/045 , G01R33/1269
摘要： A cost-effective and highly reproducible method of fabricating nanowires, and small gaps or spacings in nanowires is disclosed. The nanogaps bridge an important size regime between 1 nm and 100 nm. The nanogaps can be selectively predetermined to be as small as 1.0 nm, or larger than 1000 nm. These electrode gaps can be useful in preparing molecular electronic devices that involve making electrical contact to individual molecules, such as biomolecules, or small clusters of molecules. Microelectrodes having nanogaps for electrical and magnetic applications formed by the method, and as well as biosensors and their use in detecting a biological species, such as DNA, are also disclosed.
摘要翻译：公开了一种制造纳米线的成本有效且高度可再现的方法，以及纳米线中的小间隙或间隔。纳米角桥接在1nm和100nm之间的重要尺寸。纳米角可以选择性地预定为小至1.0nm，或大于1000nm。这些电极间隙可用于制备分子电子器件，其涉及与单个分子（例如生物分子）或小分子簇的电接触。还公开了通过该方法形成的具有用于电和磁应用的纳米角的微电极以及生物传感器及其在检测生物物种如DNA中的用途。

2. 发明申请

US20100258443A1 Methods of fabricating nanowires and electrodes having nanogaps 有权
公开(公告)号：US20100258443A1
公开(公告)日：2010-10-14
申请号：US11804464
申请日：2007-05-18
申请人： John T. Fourkas , Michael J. Naughton , Richard A. Farrer
发明人： John T. Fourkas , Michael J. Naughton , Richard A. Farrer
IPC分类号： C25D1/04 , B22D19/16 , B29C39/02
CPC分类号： G01R33/093 , B82Y25/00 , C25D1/006 , C25D1/04 , C25D11/045 , G01R33/1269
摘要： A cost-effective and highly reproducible method of fabricating nanowires, and small gaps or spacings in nanowires is disclosed. The nanogaps bridge an important size regime between 1 nm and 100 nm. The nanogaps can be selectively predetermined to be as small as 1.0 nm, or larger than 1000 nm. These electrode gaps can be useful in preparing molecular electronic devices that involve making electrical contact to individual molecules, such as biomolecules, or small clusters of molecules. Microelectrodes having nanogaps for electrical and magnetic applications formed by the method, and as well as biosensors and their use in detecting a biological species, such as DNA, are also disclosed.

3. 发明申请

US20080285040A1 Electrical Detection of Plasmon Resonances 审中-公开
标题翻译：等离子体共振的电气检测
公开(公告)号：US20080285040A1
公开(公告)日：2008-11-20
申请号：US11816252
申请日：2006-02-27
申请人： John T. Fourkas , Daniel Lim , Christopher Lafratta , Michael J. Naughton
发明人： John T. Fourkas , Daniel Lim , Christopher Lafratta , Michael J. Naughton
IPC分类号： G01N21/62 , G01R27/02
CPC分类号： G01N21/554
摘要： A method includes detecting a plasmon resonance in a material based on a change in at least one electrical property of the material. For example, the material can be a sensor portion of an electrical circuit, wherein the method can further include: exposing the sensor portion to a test material; optically illuminating the sensor portion when the test material is present, and monitoring the change in the at least one electrical property of the sensor portion in response to the optical illumination. The monitored changed in the at least one electrical property of the sensor portion can provide information about the test material, such as the presence or absence of selected analytes and/or their binding affinities. In another example, the material is a part of a receiver for a plasmonic circuit. An apparatus for carrying out the method is also disclosed.
摘要翻译：一种方法包括基于材料的至少一种电性质的变化来检测材料中的等离子体共振。例如，该材料可以是电路的传感器部分，其中该方法还可以包括：将传感器部分暴露于测试材料; 当存在测试材料时光学照射传感器部分，并响应于光学照明监测传感器部分的至少一个电特性的变化。在传感器部分的至少一个电性能中监测的监测变化可以提供关于测试材料的信息，例如选择的分析物的存在或不存在和/或其结合亲和力。在另一示例中，材料是等离子体激元电路的接收器的一部分。还公开了一种用于执行该方法的装置。

4. 发明授权

US07963953B2 Article with adjustable elastomeric waist belt 有权
标题翻译：文章带弹性腰带可调节
公开(公告)号：US07963953B2
公开(公告)日：2011-06-21
申请号：US11904407
申请日：2007-09-27
申请人： Edward P. Erdman , Michael J. Naughton , Stacy J. Driskell
发明人： Edward P. Erdman , Michael J. Naughton , Stacy J. Driskell
IPC分类号： A61F13/15
CPC分类号： A61F13/49015 , A61F13/49012 , D04H1/42
摘要： A disposable absorbent article includes a main body, a sleeve-like member extending adjacent the waist edge of the front or rear portions, and an adjustable elastomeric waist belt having a central portion and a pair of opposite free ends each defining ear-like projections. The central portion of the elastomeric member can be disposed in a sleeve-like member with each ear-like projection extending out from opposite sides. The central portion can be attached to the sleeve-like member and/or the main body near a longitudinal axis of the main body or adjacent the waist edge of the main body. The ear-like projections can be attachable to each other or the main body to form the desired waist size of the wearer of the absorbent article.
摘要翻译：一次性吸收制品包括主体，邻近前部或后部的腰部边缘延伸的套筒状构件，以及可调节的弹性腰带，其具有中心部分和一对相对的自由端，每个限定耳状突起。弹性构件的中心部分可以设置在套筒状构件中，每个耳状突起从相对侧延伸出来。中心部分可以在主体的纵向轴线附近或邻近主体的腰部边缘附接到套筒状构件和/或主体。耳状突起可以彼此附接或主体，以形成吸收性物品的使用者的期望的腰围尺寸。

5. 发明授权

US07462270B2 Cantilever probes for nanoscale magnetic and atomic force microscopy 失效
标题翻译：用于纳米级磁力和原子力显微镜的悬臂探头
公开(公告)号：US07462270B2
公开(公告)日：2008-12-09
申请号：US11800598
申请日：2007-05-07
申请人： Michael J. Naughton
发明人： Michael J. Naughton
IPC分类号： C25D5/18
CPC分类号： G01Q60/08 , G01Q60/38 , G01Q60/50 , G01Q60/52 , G01Q60/54 , G01Q70/12 , G01R33/0385 , Y10T29/49002
摘要： The various embodiments discloses a cantilever probe comprising a first electrode and a second electrode engaged to a substrate and a branched cantilever wherein the cantilever comprises a nanostruture. Furthermore, the probe comprises a first arm of the cantilever engaged to the first electrode and a second arm of the cantilever engaged to the second electrode. Additionally, the cantilever probe comprises an electrical circuit coupled to the cantilever wherein the electrical circuit is capable of measuring a change in piezoresistance of the cantilever resulting from an atomic force and/or a magnetic force applied to the cantilever. Additionally, the invention discloses a method of performing atomic force microscopy, magnetic force microscopy, or magnetic resonance force microscopy. The nanostructures may comprise carbon or non-carbon materials. Additionally, the nanostructures may include nanotubes, nanowire, nanofibers and various other types of nanostructures.
摘要翻译：各种实施例公开了一种悬臂探头，其包括接合到基底的第一电极和第二电极以及分支悬臂，其中悬臂包括纳米级缝合物。此外，探针包括接合到第一电极的悬臂的第一臂和与第二电极接合的悬臂的第二臂。此外，悬臂探头包括耦合到悬臂的电路，其中电路能够测量由施加到悬臂的原子力和/或磁力产生的悬臂的压阻变化。此外，本发明公开了一种执行原子力显微镜，磁力显微镜或磁共振力显微镜的方法。纳米结构可以包括碳或非碳材料。另外，纳米结构可以包括纳米管，纳米线，纳米纤维和各种其他类型的纳米结构。

6. 发明授权

US06418081B1 System for detection of buried objects 失效
标题翻译：埋藏物体检测系统
公开(公告)号：US06418081B1
公开(公告)日：2002-07-09
申请号：US09692789
申请日：2000-10-20
申请人： Surajit Sen , Michael J. Naughton
发明人： Surajit Sen , Michael J. Naughton
IPC分类号： G01V104
CPC分类号： G01N29/045 , F41H11/12 , G01N29/223 , G01N29/346 , G01N29/348 , G01N2291/015 , G01N2291/0235 , G01N2291/02458 , G01N2291/02491 , G01V1/001 , G01V1/047
摘要： The present invention discloses a buried object detection system. The detection system has an acoustic emitter capable of generating a non-linear acoustic impulse or a continuous acoustic signal of variable amplitude and frequency. Sensors are deployed on an appropriate surface or surfaces of a granular medium, which are capable of detecting the backscattered and, if possible, forward scattered signals of the original impulse or wave from a buried inclusion or inclusions. The information received by the sensors may be transmitted to a computer for further manipulation and analysis.
摘要翻译：本发明公开了一种掩埋物体检测系统。检测系统具有能够产生可变幅度和频率的非线性声脉冲或连续声信号的声发射器。传感器部署在颗粒介质的适当表面或表面上，颗粒介质能够检测来自埋入夹杂物或夹杂物的原始脉冲或波浪的反向散射和可能的向前散射的信号。传感器接收的信息可以传送到计算机进行进一步的操作和分析。

7. 发明授权

US5012008A Supported amorphous phase heterogeneous catalysts for biphasic hydroformylation 失效
标题翻译：用于双相加氢甲酰化的负载非晶相非均相催化剂
公开(公告)号：US5012008A
公开(公告)日：1991-04-30
申请号：US461828
申请日：1990-01-08
申请人： Russell S. Drago , Mark J. Barnes , Michael J. Naughton
发明人： Russell S. Drago , Mark J. Barnes , Michael J. Naughton
IPC分类号： C07C45/50
CPC分类号： C07C45/50
摘要： Normal aldehydes are produced in high selectivity by the vapor phase reaction of lower olefins with hydrogen and carbon monoxide in the presence of supported liquid phase catalysts at temperatures of 80.degree. C. to 100.degree. C. under pressures of 1 to 5 atmospheres.
摘要翻译：通过在负载型液相催化剂存在下，在80至100℃，1至5大气压的压力下，通过低级烯烃与氢气和一氧化碳的气相反应，可以高选择性地生产正醛。

8. 发明申请

US20140209154A1 Embedded Nanopatterns for Optical Absorbance and Photovoltaics 审中-公开
标题翻译：用于光吸收和光伏的嵌入式纳米图案
公开(公告)号：US20140209154A1
公开(公告)日：2014-07-31
申请号：US14239597
申请日：2012-08-17
申请人： Michael J. Naughton , Michael J. Burns , Fan Ye
发明人： Michael J. Naughton , Michael J. Burns , Fan Ye
IPC分类号： H01L31/0352 , H01L31/0232
CPC分类号： H01L31/035209 , H01L31/02327 , H01L31/0352 , H01L31/0543 , H01L31/0547 , H01L31/056 , H01L31/075 , Y02E10/52 , Y02E10/548
摘要： Devices and methods for enhancing optical absorbance and photovoltaics are disclosed. In some embodiments, a light absorbing device comprises a light absorbing material having a front surface and a back surface, and a planar array of nanostructures embedded within the light absorbing material between the front surface and the back surface of the light absorbing material. The nanostructures may be formed from a metallic material.
摘要翻译：公开了用于增强光吸收和光伏的装置和方法。在一些实施例中，光吸收装置包括具有前表面和后表面的光吸收材料，以及嵌入光吸收材料的前表面和后表面之间的纳米结构的平面阵列。纳米结构可以由金属材料形成。

9. 发明申请

US20100249877A1 Apparatus and Methods for Visual Perception Using an Array of Nanoscale Waveguides 有权
标题翻译：使用纳米级波导阵列的视觉感知的装置和方法
公开(公告)号：US20100249877A1
公开(公告)日：2010-09-30
申请号：US12744240
申请日：2008-11-21
申请人： Michael J. Naughton
发明人： Michael J. Naughton
IPC分类号： A61N1/04
CPC分类号： B82Y20/00 , A61N1/0543 , A61N1/36046
摘要： Nanoscale photovoltaic devices fabricated from nanoscale waveguides that receive, propagate, and convert incident light into electrical neural signals, and methods of using these photovoltaic devices for visual perception are disclosed herein. A visual neuroprosthetic device includes an array of nanoscale waveguides (170), each nanoscale waveguide (370) in the array (170) having a photovoltaic material (320) located between an internal conductor and an external conductor, wherein each nanoscale waveguide (370) receives, propagates, and converts incident light into electrical neural signals.
摘要翻译：本文公开了由纳米尺度波导制造的纳米尺度光电器件，其将入射光接收，传播和转换成电神经信号，以及使用这些光伏器件用于视觉感知的方法。视觉神经假体装置包括纳米尺度波导阵列（170），阵列（170）中的每个纳米级波导（370）具有位于内部导体和外部导体之间的光伏材料（320），其中每个纳米级波导（370）接收，传播和将入射光转换成电神经信号。

10. 发明授权

US07754964B2 Apparatus and methods for solar energy conversion using nanocoax structures 失效
标题翻译：使用纳米结构的太阳能转换的装置和方法
公开(公告)号：US07754964B2
公开(公告)日：2010-07-13
申请号：US11401606
申请日：2006-04-10
申请人： Krysztof J. Kempa , Michael J. Naughton , Zhifeng Ren , Yang Wang , Jakub A. Rybczynski
发明人： Krysztof J. Kempa , Michael J. Naughton , Zhifeng Ren , Yang Wang , Jakub A. Rybczynski
IPC分类号： H01L25/00 , H01L31/00 , H01L31/042 , H02N6/00
CPC分类号： B82Y20/00 , B82Y30/00 , G02B6/107 , H01L31/035227 , H01L31/07 , H01L51/0048 , H01L51/4213 , Y02E10/50
摘要： An apparatus and method for solar conversion using nanocoax structures are disclosed herein. A nano-optics apparatus for use as a solar cell comprising a plurality of nano-coaxial structures comprising an internal conductor surrounded by a semiconducting material coated with an outer conductor; a film having the plurality of nano-coaxial structures; and a protruding portion of the an internal conductor extending beyond a surface of the film. A method of fabricating a solar cell comprising: coating a substrate with a catalytic material; growing a plurality of carbon nanotubes as internal cores of nanocoax units on the substrate; oxidizing the substrate; coating with a semiconducting film; and filling with a metallic medium that wets the semiconducting film of the nanocoax units.
摘要翻译：本文公开了一种使用纳摩结构的太阳能转换装置和方法。一种用作太阳能电池的纳米光学装置，包括多个纳米同轴结构，其包括由涂覆有外导体的半导体材料包围的内部导体; 具有多个纳米同轴结构的膜; 以及延伸超过膜表面的内部导体的突出部分。一种制造太阳能电池的方法，包括：用催化材料涂覆基板; 在衬底上生长多个碳纳米管作为纳米单元的内核; 氧化底物; 用半导体膜涂覆; 并填充润湿纳米单体的半导体膜的金属介质。

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