Patents by Inventor Tingkai Li

Tingkai Li has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Patent number: 11426488
    Abstract: The invention discloses micron-nano pore gradient oxide ceramic films with biological activity, which are prepared by the following methods: The surface structures are biomedical engineering materials; Inorganic precursor coating solutions or the organic precursor coating solutions are prepared with or without micron and nanopore additives; The surface structures of the substrate are treated in the following steps: (1) The surfaces of the substrate are coated by the inorganic precursor coating solutions or the organic precursor coating solutions with or without micron and nanopore additives; (2) The substrate with coatings are dried, sintered, naturally cooled, and cleaned. (3) The biomedical engineering materials with the micron-nanopore gradient oxide ceramic films, especially biomimetic micro-nanoporous gradient alumina film, yttrium partially stabilized zirconia film, and alumina doped yttrium partially stabilized zirconia films in this invention greatly improve biocompatibility and biological activity.
    Type: Grant
    Filed: May 18, 2018
    Date of Patent: August 30, 2022
    Assignee: Hangzhou Erran Technologies Co., Ltd.
    Inventors: Tingkai Li, Zhijian Shen, Jie Zhang, Wuyuan Zhao, Li Tao
  • Publication number: 20210137655
    Abstract: The invention discloses a biologically active zirconia denture has a gradient structure, the gradient structure consisting of a biomimetic nano-gradient biologically active outer surface layer, the nano-gradient outer surface layer is composed of zirconia nanocrystals and a plurality of nanopores penetrating gradiently through the layer, a micron-gradient biocompatible inner layer, the micron-gradient inner surface layer is composed of zirconia microncrystals and a plurality of micronpores penetrating gradiently through the layer, a dense micron-gradient biocompatible matrix structure, a uniform gradient transition is formed at the interface between the nano-gradient outer layer and the micron-gradient inner layer, and the micron-gradient inner layer and the matrix. The invention has the advantages of high strength, high toughness, low friction coefficient, low abrasion to the teeth, good biocompatibility and biological activity.
    Type: Application
    Filed: July 5, 2018
    Publication date: May 13, 2021
    Inventors: James Zhijian Shen, Tingkai Li
  • Publication number: 20200179564
    Abstract: The invention discloses micron-nano pore gradient oxide ceramic films with biological activity, which are prepared by the following methods: The surface structures are biomedical engineering materials; Inorganic precursor coating solutions or the organic precursor coating solutions are prepared with or without micron and nanopore additives; The surface structures of the substrate are treated in the following steps: (1) The surfaces of the substrate are coated by the inorganic precursor coating solutions or the organic precursor coating solutions with or without micron and nanopore additives; (2) The substrate with coatings are dried, sintered, naturally cooled, and cleaned. (3) The biomedical engineering materials with the micron-nanopore gradient oxide ceramic films, especially biomimetic micro-nanoporous gradient alumina film, yttrium partially stabilized zirconia film, and alumina doped yttrium partially stabilized zirconia films in this invention greatly improve biocompatibility and biological activity.
    Type: Application
    Filed: November 29, 2018
    Publication date: June 11, 2020
    Inventors: Tingkai Li, Zhijian Shen, Jie Zhang, Wuyuan Zhao, Li Tao
  • Patent number: 9385278
    Abstract: Semiconductor growth substrates and associated systems and methods for die singulation are disclosed. A representative method for manufacturing semiconductor devices includes forming spaced-apart structures at a dicing street located between neighboring device growth regions of a substrate material. The method can further include epitaxially growing a semiconductor material by adding a first portion of semiconductor material to the device growth regions and adding a second portion of semiconductor material to the structures. The method can still further include forming semiconductor devices at the device growth regions, and separating the semiconductor devices from each other at the dicing street by removing the spaced-apart structures and the underlying substrate material at the dicing street.
    Type: Grant
    Filed: February 9, 2015
    Date of Patent: July 5, 2016
    Assignee: Micron Technology, Inc.
    Inventors: Xiaolong Fang, Lifang Xu, Tingkai Li, Thomas Gehrke
  • Publication number: 20150155440
    Abstract: Semiconductor growth substrates and associated systems and methods for die singulation are disclosed. A representative method for manufacturing semiconductor devices includes forming spaced-apart structures at a dicing street located between neighboring device growth regions of a substrate material. The method can further include epitaxially growing a semiconductor material by adding a first portion of semiconductor material to the device growth regions and adding a second portion of semiconductor material to the structures. The method can still further include forming semiconductor devices at the device growth regions, and separating the semiconductor devices from each other at the dicing street by removing the spaced-apart structures and the underlying substrate material at the dicing street.
    Type: Application
    Filed: February 9, 2015
    Publication date: June 4, 2015
    Inventors: Xiaolong Fang, Lifang Xu, Tingkai Li, Thomas Gehrke
  • Patent number: 8951842
    Abstract: Semiconductor growth substrates and associated systems and methods for die singulation are disclosed. A representative method for manufacturing semiconductor devices includes forming spaced-apart structures at a dicing street located between neighboring device growth regions of a substrate material. The method can further include epitaxially growing a semiconductor material by adding a first portion of semiconductor material to the device growth regions and adding a second portion of semiconductor material to the structures. The method can still further include forming semiconductor devices at the device growth regions, and separating the semiconductor devices from each other at the dicing street by removing the spaced-apart structures and the underlying substrate material at the dicing street.
    Type: Grant
    Filed: January 12, 2012
    Date of Patent: February 10, 2015
    Assignee: Micron Technology, Inc.
    Inventors: Xiaolong Fang, Lifang Xu, Tingkai Li, Thomas Gehrke
  • Publication number: 20130181219
    Abstract: Semiconductor growth substrates and associated systems and methods for die singulation are disclosed. A representative method for manufacturing semiconductor devices includes forming spaced-apart structures at a dicing street located between neighboring device growth regions of a substrate material. The method can further include epitaxially growing a semiconductor material by adding a first portion of semiconductor material to the device growth regions and adding a second portion of semiconductor material to the structures. The method can still further include forming semiconductor devices at the device growth regions, and separating the semiconductor devices from each other at the dicing street by removing the spaced-apart structures and the underlying substrate material at the dicing street.
    Type: Application
    Filed: January 12, 2012
    Publication date: July 18, 2013
    Inventors: Xiaolong Fang, Lifang Xu, Tingkai Li, Thomas Gehrke
  • Patent number: 7968419
    Abstract: A method is provided for forming a metal/semiconductor/metal (MSM) back-to-back Schottky diode from a silicon (Si) semiconductor. The method deposits a Si semiconductor layer between a bottom electrode and a top electrode, and forms a MSM diode having a threshold voltage, breakdown voltage, and on/off current ratio. The method is able to modify the threshold voltage, breakdown voltage, and on/off current ratio of the MSM diode in response to controlling the Si semiconductor layer thickness. Generally, both the threshold and breakdown voltage are increased in response to increasing the Si thickness. With respect to the on/off current ratio, there is an optimal thickness. The method is able to form an amorphous Si (a-Si) and polycrystalline Si (polySi) semiconductor layer using either chemical vapor deposition (CVD) or DC sputtering. The Si semiconductor can be doped with a Group V donor material, which decreases the threshold voltage and increases the breakdown voltage.
    Type: Grant
    Filed: September 21, 2008
    Date of Patent: June 28, 2011
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Sheng Teng Hsu, David R. Evans
  • Patent number: 7811837
    Abstract: A method of fabricating an electroluminescent device includes, on a prepared substrate, depositing a rare earth-doped silicon-rich layer on gate oxide layer as a light emitting layer; and annealing and oxidizing the structure to repair any damage caused to the rare earth-doped silicon-rich layer; and incorporating the electroluminescent device into a CMOS IC. An electroluminescent device fabricated according to the method of the invention includes a substrate, a rare earth-doped silicon-rich layer formed on the gate oxide layer for emitting a light of a pre-determined wavelength; a top electrode formed on the rare earth-doped silicon-rich layer; and associated CMOS IC structures fabricated thereabout.
    Type: Grant
    Filed: October 16, 2006
    Date of Patent: October 12, 2010
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Wei Gao, Yoshi Ono, Sheng Teng Hsu
  • Patent number: 7723729
    Abstract: A compound semiconductor-on-silicon (Si) wafer with a Si nanowire buffer layer is provided, along with a corresponding fabrication method. The method forms a Si substrate. An insulator layer is formed overlying the Si substrate, with Si nanowires having exposed tips. Compound semiconductor is selectively deposited on the Si nanowire tips. A lateral epitaxial overgrowth (LEO) process grows compound semiconductor from the compound semiconductor-coated Si nanowire tips, to form a compound semiconductor layer overlying the insulator. Typically, the insulator layer overlying the Si substrate is a thermally soft insulator (TSI), silicon dioxide, or SiXNY, where x?3 and Y?4. The compound semiconductor can be GaN, GaAs, GaAlN, or SiC. In one aspect, the Si nanowire tips are carbonized, and SiC is selectively deposited overlying the carbonized Si nanowire tips, prior to the selective deposition of compound semiconductor on the Si nanowire tips.
    Type: Grant
    Filed: February 25, 2008
    Date of Patent: May 25, 2010
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Sheng Teng Hsu
  • Patent number: 7696550
    Abstract: A multi-layer PrxCa1-xMnO3 (PCMO) thin film capacitor and associated deposition method are provided for forming a bipolar switching thin film. The method comprises: forming a bottom electrode; depositing a nanocrystalline PCMO layer; depositing a polycrystalline PCMO layer; forming a multi-layer PCMO film with bipolar switching properties; and, forming top electrode overlying the PCMO film. If the polycrystalline layers are deposited overlying the nanocrystalline layers, a high resistance can be written with narrow pulse width, negative voltage pulses. The PCMO film can be reset to a low resistance using a narrow pulse width, positive amplitude pulse. Likewise, if the nanocrystalline layers are deposited overlying the polycrystalline layers, a high resistance can be written with narrow pulse width, positive voltage pulses, and reset to a low resistance using a narrow pulse width, negative amplitude pulse.
    Type: Grant
    Filed: May 22, 2007
    Date of Patent: April 13, 2010
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Lawrence J. Charneski, Wei-Wei Zhuang, David R. Evans, Sheng Teng Hsu
  • Patent number: 7633108
    Abstract: A method is provided for forming a metal/semiconductor/metal (MSM) current limiter and resistance memory cell with an MSM current limiter. The method provides a substrate; forms an MSM bottom electrode overlying the substrate; forms a ZnOx semiconductor layer overlying the MSM bottom electrode, where x is in the range between about 1 and about 2, inclusive; and, forms an MSM top electrode overlying the semiconductor layer. The ZnOx semiconductor can be formed through a number of different processes such as spin-coating, direct current (DC) sputtering, radio frequency (RF) sputtering, metalorganic chemical vapor deposition (MOCVD), or atomic layer deposition (ALD).
    Type: Grant
    Filed: August 15, 2007
    Date of Patent: December 15, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Sheng Teng Hsu, Wei-Wei Zhuang, David R. Evans
  • Patent number: 7625595
    Abstract: A method of monitoring synthesis of PCMO precursor solutions includes preparing a PCMO precursor solution and withdrawing samples of the precursor solution at intervals during a reaction phase of the PCMO precursor solution synthesis. The samples of the PCMO precursor solution are analyzed by UV spectroscopy to determine UV transmissivity of the samples of the PCMO precursor solution and the samples used to form PCMO thin films. Electrical characteristics of the PCMO thin films formed from the samples are determined to identify PCMO thin films having optimal electrical characteristics. The UV spectral characteristics of the PCMO precursor solutions are correlated with the PCMO thin films having optimal electrical characteristics. The UV spectral characteristics are used to monitor synthesis of future batches of the PCMO precursor solutions, which will result in PCMO thin films having optimal electrical characteristics.
    Type: Grant
    Filed: April 11, 2006
    Date of Patent: December 1, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Wei-Wei Zhuang, David R. Evans, Tingkai Li, Sheng Teng Hsu
  • Patent number: 7608514
    Abstract: A metal/semiconductor/metal (MSM) binary switch memory device and fabrication process are provided. The device includes a memory resistor bottom electrode, a memory resistor material over the memory resistor bottom electrode, and a memory resistor top electrode over the memory resistor material. An MSM bottom electrode overlies the memory resistor top electrode, a semiconductor layer overlies the MSM bottom electrode, and an MSM top electrode overlies the semiconductor layer. The MSM bottom electrode can be a material such as Pt, Ir, Au, Ag, TiN, or Ti. The MSM top electrode can be a material such as Pt, Ir, Au, TiN, Ti, or Al. The semiconductor layer can be amorphous Si, ZnO2, or InO2.
    Type: Grant
    Filed: September 15, 2007
    Date of Patent: October 27, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Sheng Teng Hsu, Tingkai Li
  • Patent number: 7598108
    Abstract: A thermal expansion interface between silicon (Si) and gallium nitride (GaN) films using multiple buffer layers of aluminum compounds has been provided, along with an associated fabrication method. The method provides a (111) Si substrate and deposits a first layer of AlN overlying the substrate by heating the substrate to a relatively high temperature of 1000 to 1200° C. A second layer of AlN is deposited overlying the first layer of AlN at a lower temperature of 500 to 800° C. A third layer of AlN is deposited overlying the second layer of AlN by heating the substrate to the higher temperature range. Then, a grading Al1-XGaXN layer is formed overlying the third layer of AlN, where 0<X<1, followed by a fixed composition Al1-XGaXN layer overlying the first grading Al1-XGaXN layer. An epitaxial GaN layer can then be grown overlying the fixed composition Al1-XGaXN layer.
    Type: Grant
    Filed: July 6, 2007
    Date of Patent: October 6, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Douglas J. Tweet, Jer-Shen Maa, Sheng Teng Hsu
  • Patent number: 7585788
    Abstract: A method is provided for forming a rare earth element-doped silicon oxide (SiO2) precursor with nanocrystalline (nc) Si particles. In one aspect the method comprises: mixing Si particles into a first organic solvent, forming a first solution with a first boiling point; filtering the first solution to remove large Si particles; mixing a second organic solvent having a second boiling point, higher than the first boiling point, to the filtered first solution; and, fractionally distilling, forming a second solution of nc Si particles. The Si particles are formed by immersing a Si wafer into a third solution including hydrofluoric (HF) acid and alcohol, applying an electric bias, and forming a porous Si layer overlying the Si wafer. Then, the Si particles are mixed into the organic solvent by depositing the Si wafer into the first organic solvent, and ultrasonically removing the porous Si layer from the Si wafer.
    Type: Grant
    Filed: September 12, 2005
    Date of Patent: September 8, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Wei-Wei Zhuang, Yoshi Ono, Sheng Teng Hsu, Tingkai Li
  • Patent number: 7544625
    Abstract: A method is provided for forming a silicon oxide (SiOx) thin-film with embedded nanocrystalline silicon (Si). The method deposits SiOx, where x is in the range of 1 to 2, overlying a substrate, using a high-density (HD) plasma-enhanced chemical vapor deposition (PECVD) process. As a result, the SiOx thin-film is embedded with nanocrystalline Si. The HD PECVD process may use an inductively coupled plasma (ICP) source, a substrate temperature of less than about 400° C., and an oxygen source gas with a silicon precursor. In one aspect, a hydrogen source gas and an inert gas are used, where the ratio of oxygen source gas to inert gas is in the range of about 0.02 to 5. The SiOx thin-film with embedded nanocrystalline Si typically has a refractive index in the range of about 1.6 to 2.2, with an extinction coefficient in the range of 0 to 0.5.
    Type: Grant
    Filed: May 4, 2006
    Date of Patent: June 9, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Pooran Chandra Joshi, Tingkai Li, Yoshi Ono, Apostolos T. Voutsas, John W. Hartzell
  • Patent number: 7531466
    Abstract: A method of making a doped silicon oxide thin film using a doped silicon oxide precursor solution includes mixing a silicon source in an organic acid and adding 2-methoxyethyl ether to the silicon source and organic acid to from a preliminary precursor solution. The resultant solution is heated, stirred and filtered. A doping impurity is dissolved in 2-methoxyethanol to from a doped source solution, and the resultant solution mixed with the previously described resultant solution to from a doped silicon oxide precursor solution. A doped silicon oxide thin film if formed on a wafer by spin coating. The thin film and the wafer are baked at progressively increasing temperatures and the thin film and the wafer are annealed.
    Type: Grant
    Filed: July 26, 2006
    Date of Patent: May 12, 2009
    Assignee: Sharp LaborAtories of America, Inc.
    Inventors: Wei-Wei Zhuang, Yoshi Ono, Tingkai Li
  • Patent number: 7531207
    Abstract: Methods of forming depositing a ferroelectric thin film, such as PGO, by preparing a substrate with an upper surface of silicon, silicon oxide, or a high-k material, such as hafnium oxide, zirconium oxide, aluminum oxide, and lanthanum oxide, depositing an indium oxide film over the substrate, and then depositing the ferroelectric film using MOCVD.
    Type: Grant
    Filed: February 17, 2004
    Date of Patent: May 12, 2009
    Assignee: Sharp Laboratories of America, Inc.
    Inventors: Tingkai Li, Sheng Teng Hsu, Bruce D. Ulrich
  • Patent number: RE47382
    Abstract: A method is provided for forming a metal/semiconductor/metal (MSM) back-to-back Schottky diode from a silicon (Si) semiconductor. The method deposits a Si semiconductor layer between a bottom electrode and a top electrode, and forms a MSM diode having a threshold voltage, breakdown voltage, and on/off current ratio. The method is able to modify the threshold voltage, breakdown voltage, and on/off current ratio of the MSM diode in response to controlling the Si semiconductor layer thickness. Generally, both the threshold and breakdown voltage are increased in response to increasing the Si thickness. With respect to the on/off current ratio, there is an optimal thickness. The method is able to form an amorphous Si (a-Si) and polycrystalline Si (polySi) semiconductor layer using either chemical vapor deposition (CVD) or DC sputtering. The Si semiconductor can be doped with a Group V donor material, which decreases the threshold voltage and increases the breakdown voltage.
    Type: Grant
    Filed: June 27, 2013
    Date of Patent: May 7, 2019
    Assignee: Xenogenic Development Limited Liability Company
    Inventors: Tingkai Li, Sheng Teng Hsu, David R. Evans