公开(公告)号：US20210040276A1

公开(公告)日：2021-02-11

申请号：US16986531

申请日：2020-08-06

Applicant: University of South Florida

Inventor： Jing Wang ,  Vishvajitsinh Kosamiya

IPC: C08J3/21 ,  C04B35/46 ,  H01P3/16 ,  C04B41/00 ,  C04B41/46 ,  C04B35/626 ,  C04B35/634 ,  C08K3/22 ,  C08K9/06

Abstract: Described herein are composite materials composed of ceramic particles coated with a surfactant incorporated within a polymer matrix, methods of making same, filaments composed of the same, and articles printed using the filaments. The composite materials and articles described herein have desirable electronic and thermal properties for use in radio frequency (RF) and millimeter wave devices and demonstrate reliable performance at elevated humidity levels.

公开(公告)号：US09443662B2

公开(公告)日：2016-09-13

申请号：US14074280

申请日：2013-11-07

Applicant: UNIVERSITY OF SOUTH FLORIDA

Inventor： Mikhail Ladanov ,  Paula C. Algarin Amaris ,  Garrett Matthews ,  Manoj Kumar Ram ,  Sylvia W. Thomas ,  Ashok Kumar ,  Jing Wang ,  Arash Takshi

IPC: H01L31/02 ,  H01G9/20

CPC classification number: H01G9/204 ,  C01B33/02 ,  C01G9/02 ,  C01P2004/16 ,  C01P2006/40 ,  H01G9/2036 ,  H01G9/2045 ,  H01G9/2059 ,  Y02E10/542 ,  Y10T428/24099

Abstract: A method of forming an ordered nanorods array in a confined space is used to form a high surface area device where an ensemble of parallel trenches has micrometer dimensions for the width and depth of the trenches, which are decorated with crystalline nanowires radiating from the sidewalls and bases of the trenches. The high surface area device is formed by depositing a conformal crystalline seed coating in the trenches, forming microchannels from these trenches by placing a barrier layer on the open surface of the trenches, contacting the conformal coating with a crystal precursor solution that is caused to flow through the microchannels. In an embodiment, a very high surface area electrode is constructed with ZnO nanowires radiating from the sidewalls and base of trenches formed on a silicon substrate. The device can be a dye-sensitized solar cell.

Abstract translation: 在密闭空间中形成有序纳米棒阵列的方法用于形成高表面积装置，其中平行沟槽的整体具有用于沟槽宽度和深度的微米尺寸，其用从侧壁辐射的晶体纳米线进行装饰， 壕沟的基地。 高表面积装置是通过在沟槽中沉积保形结晶种子涂层而形成的，通过在沟槽的开放表面上放置一个阻挡层，使该保形涂层与流动的晶体前体溶液接触，从这些沟槽中形成微通道 通过微通道。 在一个实施例中，非常高的表面积电极由从形成在硅衬底上的沟槽的侧壁和基底辐射的ZnO纳米线构成。 该装置可以是染料敏化太阳能电池。

公开(公告)号：US09691554B2

公开(公告)日：2017-06-27

申请号：US15235153

申请日：2016-08-12

Applicant: University of South Florida

Inventor： Mikhail Ladanov ,  Paula C. Algarin Amaris ,  Garrett Matthews ,  Manoj Kumar Ram ,  Sylvia W. Thomas ,  Ashok Kumar ,  Jing Wang ,  Arash Takshi

IPC: H01L51/00 ,  H01G9/20 ,  C01B33/02 ,  C01G9/02

CPC classification number: H01G9/204 ,  C01B33/02 ,  C01G9/02 ,  C01P2004/16 ,  C01P2006/40 ,  H01G9/2036 ,  H01G9/2045 ,  H01G9/2059 ,  Y02E10/542 ,  Y10T428/24099

Abstract: A method of forming an ordered nanorods array in a confined space is used to form a high surface area device where an ensemble of parallel trenches has micrometer dimensions for the width and depth of the trenches, which are decorated with crystalline nanowires radiating from the sidewalls and bases of the trenches. The high surface area device is formed by depositing a conformal crystalline seed coating in the trenches, forming microchannels from these trenches by placing a barrier layer on the open surface of the trenches, contacting the conformal coating with a crystal precursor solution that is caused to flow through the microchannels. In an embodiment, a very high surface area electrode is constructed with ZnO nanowires radiating from the sidewalls and base of trenches formed on a silicon substrate. The device can be a dye-sensitized solar cell.

公开(公告)号：US20160351341A1

公开(公告)日：2016-12-01

申请号：US15235153

申请日：2016-08-12

Applicant: University of South Florida

Inventor： Mikhail Ladanov ,  Paula C. Algarin Amaris ,  Garrett Matthews ,  Manoj Kumar Ram ,  Sylvia W. Thomas ,  Ashok Kumar ,  Jing Wang ,  Arash Takshi

IPC: H01G9/20 ,  C01B33/02 ,  C01G9/02

CPC classification number: H01G9/204 ,  C01B33/02 ,  C01G9/02 ,  C01P2004/16 ,  C01P2006/40 ,  H01G9/2036 ,  H01G9/2045 ,  H01G9/2059 ,  Y02E10/542 ,  Y10T428/24099

Abstract: A method of forming an ordered nanorods array in a confined space is used to form a high surface area device where an ensemble of parallel trenches has micrometer dimensions for the width and depth of the trenches, which are decorated with crystalline nanowires radiating from the sidewalls and bases of the trenches. The high surface area device is formed by depositing a conformal crystalline seed coating in the trenches, forming microchannels from these trenches by placing a barrier layer on the open surface of the trenches, contacting the conformal coating with a crystal precursor solution that is caused to flow through the microchannels. In an embodiment, a very high surface area electrode is constructed with ZnO nanowires radiating from the sidewalls and base of trenches formed on a silicon substrate. The device can be a dye-sensitized solar cell.

Abstract translation: 在密闭空间中形成有序纳米棒阵列的方法用于形成高表面积装置，其中平行沟槽的整体具有用于沟槽宽度和深度的微米尺寸，其用从侧壁辐射的晶体纳米线进行装饰， 壕沟的基地。 高表面积装置是通过在沟槽中沉积保形结晶种子涂层而形成的，通过在沟槽的开放表面上放置一个阻挡层，使该保形涂层与导致流动的晶体前体溶液接触，从这些沟槽中形成微通道 通过微通道。 在一个实施例中，非常高的表面积电极由从形成在硅衬底上的沟槽的侧壁和基底辐射的ZnO纳米线构成。 该装置可以是染料敏化太阳能电池。

公开(公告)号：US12173127B2

公开(公告)日：2024-12-24

申请号：US16986531

申请日：2020-08-06

Applicant: University of South Florida

Inventor： Jing Wang ,  Vishvajitsinh Kosamiya

IPC: C08J3/21 ,  B33Y70/10 ,  B33Y80/00 ,  C04B35/46 ,  C04B35/626 ,  C04B35/634 ,  C04B41/00 ,  C04B41/46 ,  C08K3/22 ,  C08K9/06 ,  H01P3/16

Abstract: Described herein are composite materials composed of ceramic particles coated with a surfactant incorporated within a polymer matrix, methods of making same, filaments composed of the same, and articles printed using the filaments. The composite materials and articles described herein have desirable electronic and thermal properties for use in radio frequency (RF) and millimeter wave devices and demonstrate reliable performance at elevated humidity levels.

公开(公告)号：US11843364B2

公开(公告)日：2023-12-12

申请号：US17535868

申请日：2021-11-26

Applicant: II-VI Delaware, Inc ,  University of South Florida

Inventor： Wen-Qing Xu ,  Di Lan ,  Jing Wang ,  Weiqi Li ,  Xu Han ,  Chao Liu ,  Elgin Eissler ,  Giovanni Barbarossa

IPC: H03H9/17 ,  H03H9/13 ,  H03H9/02

CPC classification number: H03H9/171 ,  H03H9/02102 ,  H03H9/02228 ,  H03H9/02275 ,  H03H9/02338 ,  H03H9/02448 ,  H03H9/13 ,  H03H9/175

Abstract: An acoustic resonator includes a piezoelectric stack including a piezoelectric layer having a top surface and a bottom surface, a top electrode layer disposed above the top surface, and a bottom electrode layer disposed below the bottom surface. A number of acoustic wave reflectors are disposed on a side of the bottom electrode layer opposite the piezoelectric layer. Each acoustic wave reflector includes a high acoustic impedance layer and may include a low acoustic impedance layer. The acoustic resonator may include a tether that extends laterally to a stacking direction of the layers of the piezoelectric stack. A supporting structure may be coupled to the tether opposite the acoustic resonator for anchoring the acoustic resonator. A mirror, one or more phononic crystals, or both may be positioned on proximate the tether opposite the acoustic resonator to avoid resonant waves from exiting the acoustic resonator in use.

公开(公告)号：US20190181830A1

公开(公告)日：2019-06-13

申请号：US16208857

申请日：2018-12-04

Applicant: II-VI Incorporated ,  University of South Florida

Inventor： Wen-Qing Xu ,  Di Lan ,  Jing Wang ,  Weiqi Li ,  Xu Han ,  Chao Liu ,  Elgin Eissler ,  Giovanni Barbarossa

IPC: H03H9/17 ,  H03H9/13

Abstract: An acoustic resonator includes a piezoelectric stack including a piezoelectric layer having a top surface and a bottom surface, a top electrode layer disposed above the top surface, and a bottom electrode layer disposed below the bottom surface. A number of acoustic wave reflectors are disposed on a side of the bottom electrode layer opposite the piezoelectric layer. Each acoustic wave reflector includes a high acoustic impedance layer and may include a low acoustic impedance layer. The acoustic resonator may include a tether that extends laterally to a stacking direction of the layers of the piezoelectric stack. A supporting structure may be coupled to the tether opposite the acoustic resonator for anchoring the acoustic resonator. A mirror, one or more phononic crystals, or both may be positioned on proximate the tether opposite the acoustic resonator to avoid resonant waves from exiting the acoustic resonator in use.

公开(公告)号：US10161853B1

公开(公告)日：2018-12-25

申请号：US15475874

申请日：2017-03-31

Applicant: University of South Florida

Inventor： Julie Lutti ,  Jing Wang

IPC: G01N15/14 ,  G01N21/03 ,  G01N21/05

Abstract: In one embodiment, a microfluidic platform for optical biosensing, the platform including an optical substrate, a layer provided on the substrate, and a channel formed within the layer and defined by the layer and the substrate through which fluid can flow, the channel including a channel constriction that gradually narrows along a length of the channel to a point at which the channel is physically sized and configured to trap a microsphere suspended in the fluid when the fluid flows through the channel so that the microsphere cannot pass the channel constriction.

公开(公告)号：US20130334455A1

公开(公告)日：2013-12-19

申请号：US13686447

申请日：2012-11-27

Applicant: University of South Florida

Inventor： Thomas Weller ,  Jing Wang ,  Hariharan Srikanth ,  Cesar A. Morales-Silva ,  Kristen Stojak ,  Susmita Pal

IPC: H01F1/00

CPC classification number: H01F1/01 ,  H01B3/006 ,  H01F1/0018 ,  H01F41/005

Abstract: In accordance with the present invention, novel superparamagnetic magneto-dielectric polymer nanocomposites are synthesized using a novel process. The tunability of the dielectric/magnetic properties demonstrated by this novel polymer nanocomposite, when an external DC magnetic field is applied, exceeds what has been previously reported for magneto-dielectric polymer nanocomposite materials.

Abstract translation: 根据本发明，使用新颖的方法合成了新的超顺磁磁介电聚合物纳米复合材料。 当施加外部DC磁场时，由该新型聚合物纳米复合材料证明的介电/磁性能的可调性超过先前报道的磁介电聚合物纳米复合材料。