公开(公告)号：US07829050B2

公开(公告)日：2010-11-09

申请号：US11707601

申请日：2007-02-13

Applicant: Zhaoning Yu ,  Zhiyong Li ,  Wei Wu ,  Shih-Yuan Wang ,  R. Stanley Williams

Inventor： Zhaoning Yu ,  Zhiyong Li ,  Wei Wu ,  Shih-Yuan Wang ,  R. Stanley Williams

IPC: C01B21/068

CPC classification number: C30B29/10 ,  C30B29/60

Abstract: Various embodiments of the present invention are directed to methods of forming single-crystal metal-silicide nanowires and resulting nanowire structures. In one embodiment of the present invention, a method of fabricating nanowires is disclosed. In the method, a number of nanowire-precursor members are formed. Each of the nanowire-precursor members includes a substantially single-crystal silicon region and a polycrystalline-metallic region. The substantially single-crystal silicon region and the polycrystalline-metallic region of each of the nanowire-precursor members is reacted to form corresponding substantially single-crystal metal-silicide nanowires. In another embodiment of the present invention, a nanowire structure is disclosed. The nanowire structure includes a substrate having an electrically insulating layer. A number of substantially single-crystal metal-silicide nanowires are positioned on the electrically insulating layer.

Abstract translation: 本发明的各种实施方案涉及形成单晶金属硅化物纳米线和所得纳米线结构的方法。 在本发明的一个实施例中，公开了一种制造纳米线的方法。 在该方法中，形成许多纳米线前体部件。 每个纳米线前体构件包括基本单晶硅区域和多晶金属区域。 每个纳米线前体部件的大致单晶硅区域和多晶金属区域反应形成对应的基本单晶金属硅化物纳米线。 在本发明的另一个实施方案中，公开了一种纳米线结构。 纳米线结构包括具有电绝缘层的衬底。 大量单晶金属硅化物纳米线位于电绝缘层上。

公开(公告)号：US20090274874A1

公开(公告)日：2009-11-05

申请号：US12247832

申请日：2008-10-08

Applicant: Zhiyong Li ,  R. Stanley Williams

Inventor： Zhiyong Li ,  R. Stanley Williams

IPC: B32B5/00 ,  B28B11/08

CPC classification number: H01L51/0012 ,  B82Y10/00 ,  B82Y20/00 ,  B82Y40/00 ,  G03F7/0002 ,  H01L51/001 ,  H01L51/0021 ,  Y10T428/24479 ,  Y10T428/249921

Abstract: A photonic device includes a substrate and at least one molecularly assembled or atomic layer deposited nano-structure defined on the substrate. The nano-structure has a controlled resolution less than or equal to 100 nm.

Abstract translation: 光子器件包括衬底和限定在衬底上的至少一个分子组装或原子层沉积的纳米结构。 纳米结构具有小于或等于100nm的受控分辨率。

公开(公告)号：US07609377B2

公开(公告)日：2009-10-27

申请号：US11796455

申请日：2007-04-26

Applicant: Wei Wu ,  Zhiyong Li ,  Shih-Yuan Wang ,  Zhaoning Yu ,  R. Stanley Williams

Inventor： Wei Wu ,  Zhiyong Li ,  Shih-Yuan Wang ,  Zhaoning Yu ,  R. Stanley Williams

IPC: G01J3/44

CPC classification number: G01N21/658

Abstract: An apparatus and related methods for facilitating surface-enhanced Raman spectroscopy (SERS) is described. A SERS-active structure near which a plurality of analyte molecules is disposed is periodically deformed at an actuation frequency. A synchronous measuring device synchronized with the actuation frequency receives Raman radiation scattered from the analyte molecules and generates therefrom at least one Raman signal measurement.

Abstract translation: 描述了用于促进表面增强拉曼光谱（SERS）的装置和相关方法。 多个分析物分子附近的SERS-活性结构以致动频率周期性地变形。 与致动频率同步的同步测量装置接收从分析物分子散射的拉曼辐射，并由此产生至少一个拉曼信号测量。

公开(公告)号：US07507293B2

公开(公告)日：2009-03-24

申请号：US11096669

申请日：2005-03-31

Applicant: Zhiyong Li ,  R. Stanley Williams ,  M. Saif Islam ,  Philip J. Kuekes

Inventor： Zhiyong Li ,  R. Stanley Williams ,  M. Saif Islam ,  Philip J. Kuekes

IPC: C30B25/02

CPC classification number: C30B11/12 ,  B82Y10/00 ,  B82Y30/00 ,  C30B11/00 ,  C30B29/605 ,  Y10S977/762 ,  Y10S977/813

Abstract: Fabrication of a photonic crystal is described. A patterned array of nanowires is formed, the nanowires extending outward from a surface, the nanowires comprising a catalytically grown nanowire material. Spaces between the nanowires are filled with a slab material, the patterned array of nanowires defining a patterned array of channels in the slab material. The nanowire material is then removed from the channels.

Abstract translation: 描述了光子晶体的制造。 形成纳米线的图案阵列，纳米线从表面向外延伸，纳米线包含催化生长的纳米线材料。 在纳米线之间的空间填充有板坯材料，图案化的纳米线阵列在板坯材料中限定了图案化的通道阵列。 然后从通道中除去纳米线材料。

公开(公告)号：US20080218740A1

公开(公告)日：2008-09-11

申请号：US12074133

申请日：2008-02-29

Applicant: R. Stanley Williams ,  Shih-Yuan Wang ,  Philip J. Kuekes ,  Theodore I. Kamins ,  Duncan Stewart ,  Alexandre M. Bratkovski ,  Jason Blackstock ,  Zhiyong Li

Inventor： R. Stanley Williams ,  Shih-Yuan Wang ,  Philip J. Kuekes ,  Theodore I. Kamins ,  Duncan Stewart ,  Alexandre M. Bratkovski ,  Jason Blackstock ,  Zhiyong Li

IPC: G01N21/00

CPC classification number: H01L33/18 ,  B82Y20/00 ,  H01L29/0665 ,  H01L29/0673 ,  H01L29/068 ,  H01L33/06 ,  H01L33/08 ,  H01S5/341 ,  H01S5/4031

Abstract: Embodiments of the present invention are related to nanowire-based devices that can be configured and operated as modulators, chemical sensors, and light-detection devices. In one aspect, a nanowire-based device includes a reflective member, a resonant cavity surrounded by at least a portion of the reflective member, and at least one nanowire disposed within the resonant cavity. The nanowire includes at least one active segment selectively disposed along the length of the nanowire to substantially coincide with at least one antinode of light resonating within the cavity. The active segment can be configured to interact with the light resonating within the cavity.

Abstract translation: 本发明的实施例涉及可以配置和操作为调制器，化学传感器和光检测装置的基于纳米线的器件。 在一个方面，基于纳米线的器件包括反射部件，由反射部件的至少一部分包围的谐振腔以及设置在谐振腔内的至少一个纳米线。 纳米线包括至少一个有源区段，沿着纳米线的长度选择性地设置，以与腔内谐振的至少一个光波导基本重合。 活动段可以被配置为与腔内共振的光相互作用。

公开(公告)号：US20080193359A1

公开(公告)日：2008-08-14

申请号：US11707601

申请日：2007-02-13

Applicant: Zhaoning Yu ,  Zhiyong Li ,  Wei Wu ,  Shih-Yuan Wang ,  R. Stanley Williams

Inventor： Zhaoning Yu ,  Zhiyong Li ,  Wei Wu ,  Shih-Yuan Wang ,  R. Stanley Williams

IPC: C01B21/068

CPC classification number: C30B29/10 ,  C30B29/60

Abstract: Various embodiments of the present invention are directed to methods of forming single-crystal metal-silicide nanowires and resulting nanowire structures. In one embodiment of the present invention, a method of fabricating nanowires is disclosed. In the method, a number of nanowire-precursor members are formed. Each of the nanowire-precursor members includes a substantially single-crystal silicon region and a polycrystalline- metallic region. The substantially single-crystal silicon region and the polycrystalline-metallic region of each of the nanowire-precursor members is reacted to form corresponding substantially single-crystal metal-silicide nanowires. In another embodiment of the present invention, a nanowire structure is disclosed. The nanowire structure includes a substrate having an electrically insulating layer. A number of substantially single-crystal metal-silicide nanowires are positioned on the electrically insulating layer.

Abstract translation: 本发明的各种实施方案涉及形成单晶金属硅化物纳米线和所得纳米线结构的方法。 在本发明的一个实施例中，公开了一种制造纳米线的方法。 在该方法中，形成许多纳米线前体部件。 每个纳米线前体构件包括大致单晶硅区域和多晶金属区域。 每个纳米线前体部件的大致单晶硅区域和多晶金属区域反应形成对应的基本单晶金属硅化物纳米线。 在本发明的另一个实施方案中，公开了一种纳米线结构。 纳米线结构包括具有电绝缘层的衬底。 大量单晶金属硅化物纳米线位于电绝缘层上。

公开(公告)号：US20080093217A1

公开(公告)日：2008-04-24

申请号：US11584678

申请日：2006-10-20

Applicant: Wei Wu ,  R. Stanley Williams ,  Shih-Yuan Wang ,  Philip J. Kuekes ,  Zhiyong Li

Inventor： Wei Wu ,  R. Stanley Williams ,  Shih-Yuan Wang ,  Philip J. Kuekes ,  Zhiyong Li

IPC: G01N27/26

CPC classification number: G01N21/658

Abstract: A method of forming a plurality of NERS-active structures is disclosed. Particularly, a substrate having a surface and a liquid including nanoparticles is deposited on at least a portion of the surface of the substrate. At least one electric field may be generated proximate to the surface and at least a portion of the nanoparticles may be arranged via the electric field. A system includes at least two electrodes configured for producing at least one electric field for substantially arranging nanoparticles substantially according to a selected pattern. A NERS-active structure includes a substrate and a plurality of features located at predetermined positions on a surface of the substrate and at least one NERS-active nanoparticle at least partially embedded therein.

Abstract translation: 公开了一种形成多个NERS-活性结构的方法。 特别地，具有表面和包含纳米颗粒的液体的基底沉积在基底表面的至少一部分上。 可以在表面附近产生至少一个电场，并且可以经由电场布置至少一部分纳米颗粒。 一种系统包括至少两个电极，所述至少两个电极被配置用于产生至少一个电场，用于基本上根据所选择的图案基本上布置纳米颗粒。 NERS活性结构包括基底和位于基底表面上的预定位置的多个特征以及至少部分地嵌入其中的至少一个NERS-活性纳米颗粒。

公开(公告)号：US07151599B2

公开(公告)日：2006-12-19

申请号：US11044421

申请日：2005-01-27

Applicant: M. Saif Islam ,  Shih-Yuan Wang ,  Wei Wu ,  Zhiyong Li ,  R. Stanley Williams

Inventor： M. Saif Islam ,  Shih-Yuan Wang ,  Wei Wu ,  Zhiyong Li ,  R. Stanley Williams

IPC: G01J3/44 ,  G01N21/65

CPC classification number: G01N21/658 ,  G01N2201/0873

Abstract: Devices, systems, and methods for enhancing Raman spectroscopy and hyper-Raman are disclosed. A molecular analysis device for performing Raman spectroscopy comprises a substrate and a laser source disposed on the substrate. The laser source may be configured for emanating a laser radiation, which may irradiate an analyte disposed on a Raman enhancement structure. The Raman enhancement structure may be disposed in a waveguide. The molecular analysis device also includes a wavelength demultiplexer and radiation sensors disposed on the substrate and configured for receiving a Raman scattered radiation, which may be generated by the irradiation of the analyte and Raman enhancement structure.

Abstract translation: 公开了用于增强拉曼光谱和超拉曼的装置，系统和方法。 用于执行拉曼光谱的分子分析装置包括设置在基板上的基板和激光源。 激光源可以被配置为发射激光辐射，其可照射设置在拉曼增强结构上的分析物。 拉曼增强结构可以设置在波导中。 该分子分析装置还包括布置在基板上的波长解复用器和辐射传感器，并且被配置为用于接收可以通过分析物的照射和拉曼增强结构产生的拉曼散射辐射。

公开(公告)号：US09453793B2

公开(公告)日：2016-09-27

申请号：US13452218

申请日：2012-04-20

Applicant: Alexandre M Bratkovski ,  R Stanley Williams ,  Zhiyong Li

Inventor： Alexandre M Bratkovski ,  R Stanley Williams ,  Zhiyong Li

IPC: G01N21/00 ,  G01N21/01 ,  G01N21/65 ,  G01N21/64

CPC classification number: G01N21/01 ,  G01N21/648 ,  G01N21/658

Abstract: Examples of integrated sensors are disclosed herein. An example of an integrated sensor includes a flexible substrate, and an array of spaced apart sensing members formed on a surface of the flexible substrate. Each of the spaced apart sensing members includes a plurality of polygon assemblies. The polygon assemblies are arranged in a controlled pattern on the surface of the flexible substrate such that each of the plurality of polygon assemblies is a predetermined distance from each other of the plurality of polygon assemblies, and each of the plurality of polygon assemblies including collapsible signal amplifying structures controllably positioned in a predetermined geometric shape.

Abstract translation: 本文公开了集成传感器的示例。 集成传感器的示例包括柔性基板和形成在柔性基板的表面上的间隔开的感测部件阵列。 每个间隔开的感测构件包括多个多边形组件。 多边形组件以可控的图案布置在柔性基板的表面上，使得多个多边形组件中的每一个距离多个多边形组件中的彼此之间是预定距离，并且多个多边形组件中的每一个包括可折叠信号 放大结构可控地定位在预定的几何形状。

公开(公告)号：US09279767B2

公开(公告)日：2016-03-08

申请号：US13879255

申请日：2010-10-20

Applicant: Zhiyong Li ,  R. Stanley Williams

Inventor： Zhiyong Li ,  R. Stanley Williams

IPC: G01N21/00 ,  G01N21/64 ,  G01N21/65

CPC classification number: G01N21/6428 ,  G01N21/648 ,  G01N21/658 ,  G01N33/54373

Abstract: A chemical-analysis device integrated with a metallic-nanofinger device for chemical sensing. The chemical-analysis device includes a metallic-nanofinger device, and a platform. The metallic-nanofinger device includes a substrate, and a plurality of nanofingers coupled with the substrate. A nanofinger of the plurality includes a flexible column, and a metallic cap coupled to an apex of the flexible column. At least the nanofinger and a second nanofinger of the plurality of nanofingers are to self-arrange into a close-packed configuration with at least one analyte molecule. A morphology of the metallic cap is to generate a shifted plasmonic-resonance peak associated with amplified luminescence from the analyte molecule. A method for using, and a chemical-analysis apparatus including the chemical-analysis device are also provided.

Abstract translation: 与用于化学感测的金属纳米酮装置集成的化学分析装置。 化学分析装置包括金属纳米装置和平台。 金属纳米装置包括衬底和与衬底耦合的多个纳米器件。 多个纳米针板包括柔性柱和联接到柔性柱的顶点的金属帽。 至少纳米角蛋白和多个纳米针的第二纳米角键将与至少一个分析物分子自组织成紧密堆积的构型。 金属盖的形态是产生与来自分析物分子的放大发光相关的移位等离子体共振峰。 还提供了一种使用方法和包括该化学分析装置的化学分析装置。