Patents by Inventor Xiao-Dong Zhou

Xiao-Dong Zhou 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: 11757087
    Abstract: Methods are provided for forming an electrode. The method can comprise thermally reducing GeO2 powders at a reducing temperature of 300° C. to 600° C. to produce Ge particles; mixing the Ge particles with an organic binder and a carbon source; and pressing the Ge particles with the binder and the carbon source to form the electrode. Electrodes are also provided that include a plurality of microparticles comprising Ge grains, an organic binder, and a carbon source, wherein the Ge grains comprise cubic Ge and are bonded together to form Ge particles, and wherein the Ge grains define nanopores within the electrode.
    Type: Grant
    Filed: February 3, 2021
    Date of Patent: September 12, 2023
    Assignee: University of South Carolina
    Inventors: Xiao-Dong Zhou, Kuber Mishra, Fu-Sheng Ke
  • Publication number: 20210184203
    Abstract: Methods are provided for forming an electrode. The method can comprise thermally reducing GeO2 powders at a reducing temperature of 300° C. to 600° C. to produce Ge particles; mixing the Ge particles with an organic binder and a carbon source; and pressing the Ge particles with the binder and the carbon source to form the electrode. Electrodes are also provided that include a plurality of microparticles comprising Ge grains, an organic binder, and a carbon source, wherein the Ge grains comprise cubic Ge and are bonded together to form Ge particles, and wherein the Ge grains define nanopores within the electrode.
    Type: Application
    Filed: February 3, 2021
    Publication date: June 17, 2021
    Inventors: XIAO-DONG ZHOU, KUBER MISHRA, FU-SHENG KE
  • Patent number: 10944101
    Abstract: Methods are provided for forming an electrode. The method can comprises: thermally reducing GeO2 powders at a reducing temperature of 300° C. to 600° C. to produce Ge particles; mixing the Ge particles with an organic binder and a carbon source; and pressing the Ge particles with the binder and the carbon source to form the electrode. Electrodes are also provided that include a plurality of microparticles comprising Ge grains, an organic binder, and a carbon source, wherein the Ge grains comprise cubic Ge and are bonded together to form Ge particles, and wherein the Ge grains define nanopores within the electrode.
    Type: Grant
    Filed: March 2, 2015
    Date of Patent: March 9, 2021
    Assignee: University of South Carolina
    Inventors: Xiao-Dong Zhou, Kuber Mishra, Fu-Sheng Ke
  • Patent number: 10003083
    Abstract: In some examples, a fuel cell including an anode; electrolyte; and cathode separated from the anode by the electrolyte, wherein the cathode includes a Pr-nickelate based material with (Pr1-xAx)n+1(Ni1-yBy)nO3n+1+? as a general formula, where n is 1 as an integer, A is an A-site dopant including of a metal of a group formed by one or more lanthanides, and B is a B-site dopant including of a metal of a group formed by one or more transition metals, wherein the A and B-site dopants are provided such that there is an increase in phase-stability and reduction in degradation of the Pr-nickelate based material, and A is at least one metal cation of lanthanides, La, Nd, Sm, or Gd, B is at least one metal cation of transition metals, Cu, Co, Mn, Zn, or Cr, where: 0<x<1, and 0<y?0.4.
    Type: Grant
    Filed: July 21, 2015
    Date of Patent: June 19, 2018
    Assignees: LG Fuel Cell Systems, Inc., University of South Carolina
    Inventors: Hwa Young Jung, Zhengliang Xing, Zhien Liu, Richard W. Goettler, Xiao-Dong Zhou, Emir Dogdibegovic
  • Publication number: 20170363689
    Abstract: Accelerated testing protocols that can be utilized for determining and projecting the durability of SOFC cathodes are described. The accelerated testing protocols can be carried out under simulated operation conditions so as to provide in a matter of a few hundred hours data that can correlate to the condition of the cathode following operation of the cell over the course of a typical operation life span of several thousand hours. A testing protocol can include cycling a SOFC from OCV to operating potential at a predetermined current density. Each cycle can be relatively short, for instance less than one minute.
    Type: Application
    Filed: June 14, 2017
    Publication date: December 21, 2017
    Inventors: Xiao-Dong Zhou, Emir Dogdibegovic
  • Publication number: 20160020470
    Abstract: In some examples, a fuel cell including an anode; electrolyte; and cathode separated from the anode by the electrolyte, wherein the cathode includes a Pr-nickelate based material with (Pr1-xAx)n+1(Ni1-yBy)nO3n+1+? as a general formula, where n is 1 as an integer, A is an A-site dopant including of a metal of a group formed by one or more lanthanides, and B is a B-site dopant including of a metal of a group formed by one or more transition metals, wherein the A and B-site dopants are provided such that there is an increase in phase-stability and reduction in degradation of the Pr-nickelate based material, and A is at least one metal cation of lanthanides, La, Nd, Sm, or Gd, B is at least one metal cation of transition metals, Cu, Co, Mn, Zn, or Cr, where: 0<x<1, and 0<y?0.4.
    Type: Application
    Filed: July 21, 2015
    Publication date: January 21, 2016
    Inventors: Hwa Young Jung, Zhengliang Xing, Zhien Liu, Richard W. Goettler, Xiao-Dong Zhou, Emir Dogdibegovic
  • Publication number: 20150249247
    Abstract: Methods are provided for forming an electrode. The method can comprises: thermally reducing GeO2 powders at a reducing temperature of 300° C. to 600° C. to produce Ge particles; mixing the Ge particles with an organic binder and a carbon source; and pressing the Ge particles with the binder and the carbon source to form the electrode. Electrodes are also provided that include a plurality of microparticles comprising Ge grains, an organic binder, and a carbon source, wherein the Ge grains comprise cubic Ge and are bonded together to form Ge particles, and wherein the Ge grains define nanopores within the electrode.
    Type: Application
    Filed: March 2, 2015
    Publication date: September 3, 2015
    Inventors: Xiao-Dong Zhou, Kuber Mishra, Fu-Sheng Ke
  • Patent number: 8907673
    Abstract: For magnetic resonance imaging (MRI), a dynamic frequency drift correction method for binomial water excitation method includes collecting the reference one-dimensional navigation signal by an MRI device; acquiring one current one-dimensional navigation signal after scanning N images, wherein N is a positive integer; calculating the frequency drift according to the reference one-dimensional navigation signal and the current one-dimensional navigation signal; calculating and setting the initial phase of the next radio frequency signal by the MRI device according to the frequency drift.
    Type: Grant
    Filed: April 29, 2011
    Date of Patent: December 9, 2014
    Assignee: Siemens Aktiengesellschaft
    Inventors: Qiang He, De He Weng, Xiao Dong Zhou
  • Patent number: 8638099
    Abstract: A method for reducing magnetic resonance temperature measurement errors, which is used for the high-intensity focused ultrasound device for monitoring magnetic resonance imaging includes obtaining a magnetic resonance phase diagram as a reference image before the high-intensity focused ultrasound device heats the heating area; obtaining another magnetic resonance phase diagram as a heating image during or after the heating process of the high intensity focused ultrasound device; calculating the temperature changes in the heating area according to said heating image and reference image. The method further includes measuring the magnetic field changes caused by the position changes of the ultrasonic transducer of said high-intensity focused ultrasound device, and then compensating for the temperature changes according to said magnetic field changes. The present invention can significantly reduce the temperature errors caused by the position changes of the ultrasonic transducer.
    Type: Grant
    Filed: May 31, 2011
    Date of Patent: January 28, 2014
    Assignee: Siemens Aktiengesellschaft
    Inventors: Cheng Ni, Xiao Dong Zhou
  • Patent number: 8476904
    Abstract: A method for magnetic resonance imaging, in which a magnetic resonance imaging device employs a multi-echo imaging sequence, includes the steps of: applying, to one of the multiple echoes, a first number of steps of phase encoding, applying a readout gradient, and collecting the data of this echo to reconstruct an anatomical image; and applying, to another one of the multiple echoes, a second number of steps of phase encoding, applying a readout gradient, and collecting the data of this echo to construct a temperature image. The method is capable of obtaining at the same time both a temperature image with high time resolution and an anatomical image with high spatial resolution.
    Type: Grant
    Filed: March 21, 2011
    Date of Patent: July 2, 2013
    Assignee: Siemens Aktiengesellschaft
    Inventors: Marc Beckmann, Cheng Ni, Xiao Dong Zhou
  • Patent number: 8401614
    Abstract: A method for reducing errors in the measurement of temperature by magnetic resonance, for use in magnetic resonance imaging-guided HIFU equipment, includes acquiring an MR phase image, as a reference image, before heating an area to be heated with the HIFU equipment; acquiring another MR phase image, as a heated image, during or after the heating by the HIFU equipment; and calculating the temperature change in the heated area according to said heated image and said reference image; and making compensation to said temperature change according to the change in the magnetic field caused by the position change of an ultrasonic transducer in said HIFU equipment. The method can reduce significantly the temperature errors resulting from the position changes of the ultrasonic transducer.
    Type: Grant
    Filed: February 19, 2010
    Date of Patent: March 19, 2013
    Assignee: Siemens Aktiengesellschaft
    Inventors: Xiao Dong Zhou, Cheng Ni
  • Patent number: 8116843
    Abstract: In a method for automatically selecting a region of interest covering a heated area, in the context of high intensity focused ultrasonic technology during acquisition of magnetic resonance data, phase data of a scanned area are acquired, and a heated area is identified in the scanned area according to the phase data acquired. An image is reconstructed and displayed, and in the displayed image a region of interest covering the heated area is automatically demarcated according to a predetermined size of said region of interest that covers and is larger than the heated area. The method causes the heated area to be automatically and completely included in the region of interest; and eliminates the instability of a manual selection of the region of interest.
    Type: Grant
    Filed: January 16, 2008
    Date of Patent: February 14, 2012
    Assignee: Siemens Aktiengesellschaft
    Inventors: Yong Ming Dai, Xiao Dong Zhou
  • Publication number: 20110291654
    Abstract: A method for reducing magnetic resonance temperature measurement errors, which is used for the high-intensity focused ultrasound device for monitoring magnetic resonance imaging includes obtaining a magnetic resonance phase diagram as a reference image before the high-intensity focused ultrasound device heats the heating area; obtaining another magnetic resonance phase diagram as a heating image during or after the heating process of the high intensity focused ultrasound device; calculating the temperature changes in the heating area according to said heating image and reference image. The method further includes measuring the magnetic field changes caused by the position changes of the ultrasonic transducer of said high-intensity focused ultrasound device, and then compensating for the temperature changes according to said magnetic field changes. The present invention can significantly reduce the temperature errors caused by the position changes of the ultrasonic transducer.
    Type: Application
    Filed: May 31, 2011
    Publication date: December 1, 2011
    Inventors: Cheng Ni, Xiao Dong Zhou
  • Publication number: 20110267057
    Abstract: For magnetic resonance imaging (MRI), a dynamic frequency drift correction method for binomial water excitation method includes collecting the reference one-dimensional navigation signal by an MRI device; acquiring one current one-dimensional navigation signal after scanning N images, wherein N is a positive integer; calculating the frequency drift according to the reference one-dimensional navigation signal and the current one-dimensional navigation signal; calculating and setting the initial phase of the next radio frequency signal by the MRI device according to the frequency drift.
    Type: Application
    Filed: April 29, 2011
    Publication date: November 3, 2011
    Inventors: Qiang He, De He Weng, Xiao Dong Zhou
  • Publication number: 20110241668
    Abstract: A method for magnetic resonance imaging, in which a magnetic resonance imaging device employs a multi-echo imaging sequence, includes the steps of: applying, to one of the multiple echoes, a first number of steps of phase encoding, applying a readout gradient, and collecting the data of this echo to reconstruct an anatomical image; and applying, to another one of the multiple echoes, a second number of steps of phase encoding, applying a readout gradient, and collecting the data of this echo to construct a temperature image. The method is capable of obtaining at the same time both a temperature image with high time resolution and an anatomical image with high spatial resolution.
    Type: Application
    Filed: March 21, 2011
    Publication date: October 6, 2011
    Inventors: Marc Beckmann, Cheng Ni, Xiao Dong Zhou
  • Publication number: 20100249668
    Abstract: An ultrasonic transducer has at least two sets of transducer units, with all the transducer units in each set having the same focus position and the transducer units in the different sets having different focus positions. Since the focus points of the sets of ultrasonic transducer units are distributed in a relatively large spatial range, the range of ultrasonic therapy can be increased even within the narrow and limited space of magnetic resonance imaging equipment.
    Type: Application
    Filed: February 25, 2010
    Publication date: September 30, 2010
    Inventors: Xiao Dong Zhou, Florian Steinmeyer, Cheng Ni
  • Publication number: 20100217114
    Abstract: A method for reducing errors in the measurement of temperature by magnetic resonance, for use in magnetic resonance imaging-guided HIFU equipment, includes acquiring an MR phase image, as a reference image, before heating an area to be heated with the HIFU equipment; acquiring another MR phase image, as a heated image, during or after the heating by the HIFU equipment; and calculating the temperature change in the heated area according to said heated image and said reference image; and making compensation to said temperature change according to the change in the magnetic field caused by the position change of an ultrasonic transducer in said HIFU equipment. The method can reduce significantly the temperature errors resulting from the position changes of the ultrasonic transducer.
    Type: Application
    Filed: February 19, 2010
    Publication date: August 26, 2010
    Inventors: Xiao Dong Zhou, Cheng Ni
  • Publication number: 20100047656
    Abstract: Solid-state ionic or electrochemical devices can depend critically on the proper formation of a dense, Gd-doped ceria (GDC) layer on a porous substrate. Devices and methods of the present invention are characterized by the formation of a transitional buffer layer, which is less than 10 microns thick and comprises GDC, located between the porous substrate and the dense GDC layer. The transitional buffer layer provides a practical way to form the dense GDC layer on the porous substrate without cracks in the GDC layer and without clogging the pores of the substrate.
    Type: Application
    Filed: August 19, 2008
    Publication date: February 25, 2010
    Inventors: Xiaohong S Li, Prabhakar Singh, Xiao-Dong Zhou
  • Publication number: 20090194223
    Abstract: A method for forming electrical connections between parts of a fuel cell that includes subjecting a contact paste positioned between the parts to alternating flows of gasses having varying high and low partial pressures of oxygen. This method demonstrates the ability to form conductive interconnections that have sufficient mechanical stability because these pastes can be cured at a temperature less than the temperatures of the surrounding materials thus allowing desired portions to be cured while allowing other portions such as the glass or ceramic portions to maintain their desired mechanical and electrical properties.
    Type: Application
    Filed: February 5, 2009
    Publication date: August 6, 2009
    Applicant: Battelle Memorial Institute
    Inventors: Benjamin P. McCarthy, Larry R. Pederson, Yeong-Shyung Chou, Xiao-Dong Zhou, Wayne A. Surdoval, Lane C. Wilson
  • Publication number: 20090182223
    Abstract: A method for automatically selecting a region of interest covering a heated area, in the context of high intensity focused ultrasonic technology achieves automatic selection of the region of interest on the basis of the phase recognition completed in a magnetic resonance data acquisition and the position of the focus of a focused ultrasonic sensor. The method includes the steps of acquiring the phase data of a scanned area during a scanning process, then determining a heated area in the scanned area according to the phase data acquired; and in a displayed image acquired by the image reconstruction, demarcating a region of interest covering the heated area according to a predetermined size of said region of interest that covers and is larger than the heated area.
    Type: Application
    Filed: January 16, 2008
    Publication date: July 16, 2009
    Inventors: Yong Ming Dai, Xiao Dong Zhou