Patents by Inventor Bongjun Yeom

Bongjun Yeom 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: 11167999
    Abstract: The present disclosure provides a biomimetic composite that includes a plurality of nanostructures each having at least one axial geometry region comprising an inorganic material. The nanostructures may be a plurality of substantially aligned (e.g., in a vertical orientation) axial geometry nanowires comprising zinc oxide or alternatively hedgehog-shaped nanoparticles with needles comprising zinc oxide. A polymeric matrix disposed in void regions defined between respective nanostructures of the plurality of nanostructures. The biomimetic composite exhibits a viscoelastic figure of merit (VFOM) of greater than or equal to about 0.001 up to about 0.6 or greater. Methods of making such biomimetic composites are also provided.
    Type: Grant
    Filed: February 22, 2019
    Date of Patent: November 9, 2021
    Assignee: THE REGENTS OF THE UNIVERSITY OF MICHIGAN
    Inventors: Nicholas A. Kotov, Bongjun Yeom
  • Patent number: 10629324
    Abstract: New stretchable electrically conductive composite materials comprising at least one polymer and a plurality of nanoparticles are provided, which exhibit high conductivity even at high strain levels. The composite may comprise polyurethane as the polymer and spherical gold nanoparticles. Such materials have conductivity levels as high as 11,000 Scm?1 at 0% strain and 2,400 Scm?1 at 110% strain. Furthermore, certain embodiments of the composite have a maximum tensile strain of 480% while still exhibiting conductivity of 35 Scm?1. The inventive materials are highly flexible, highly conductive and suitable for a variety of applications, especially for advanced medical devices, implants, and flexible electronics. The disclosure also provides methods of making such stretchable electrically conductive nanocomposites, including formation by layer-by-layer and vacuum assisted flocculation.
    Type: Grant
    Filed: February 19, 2018
    Date of Patent: April 21, 2020
    Assignee: THE REGENTS OF THE UNIVERSITY OF MICHIGAN
    Inventors: Nicholas A. Kotov, Yoonseob Kim, Jian Zhu, Matthew Di Prima, Bongjun Yeom
  • Publication number: 20190256369
    Abstract: The present disclosure provides a biomimetic composite that includes a plurality of nanostructures each having at least one axial geometry region comprising an inorganic material. The nanostructures may be a plurality of substantially aligned (e.g., in a vertical orientation) axial geometry nanowires comprising zinc oxide or alternatively hedgehog-shaped nanoparticles with needles comprising zinc oxide. A polymeric matrix disposed in void regions defined between respective nanostructures of the plurality of nanostructures. The biomimetic composite exhibits a viscoelastic figure of merit (VFOM) of greater than or equal to about 0.001 up to about 0.6 or greater. Methods of making such biomimetic composites are also provided.
    Type: Application
    Filed: February 22, 2019
    Publication date: August 22, 2019
    Inventors: Nicholas A. KOTOV, Bongjun YEOM
  • Publication number: 20180174699
    Abstract: New stretchable electrically conductive composite materials comprising at least one polymer and a plurality of nanoparticles are provided, which exhibit high conductivity even at high strain levels. The composite may comprise polyurethane as the polymer and spherical gold nanoparticles. Such materials have conductivity levels as high as 11,000 Scm?1 at 0% strain and 2,400 Scm?1 at 110% strain. Furthermore, certain embodiments of the composite have a maximum tensile strain of 480% while still exhibiting conductivity of 35 Scm?1. The inventive materials are highly flexible, highly conductive and suitable for a variety of applications, especially for advanced medical devices, implants, and flexible electronics. The disclosure also provides methods of making such stretchable electrically conductive nanocomposites, including formation by layer-by-layer and vacuum assisted flocculation.
    Type: Application
    Filed: February 19, 2018
    Publication date: June 21, 2018
    Applicant: The Regents of The University of Michigan
    Inventors: Nicholas A. Kotov, Yoonseob Kim, Jian Zhu, Matthew Di Prima, Bongjun Yeom
  • Patent number: 9922746
    Abstract: New stretchable electrically conductive composite materials comprising at least one polymer and a plurality of nanoparticles are provided, which exhibit high conductivity even at high strain levels. The composite may comprise polyurethane as the polymer and spherical gold nanoparticles. Such materials have conductivity levels as high as 11,000 Scm?1 at 0% strain and 2,400 Scm?1 at 110% strain. Furthermore, certain embodiments of the composite have a maximum tensile strain of 480% while still exhibiting conductivity of 35 Scm?1. The inventive materials are highly flexible, highly conductive and suitable for a variety of applications, especially for advanced medical devices, implants, and flexible electronics. The disclosure also provides methods of making such stretchable electrically conductive nanocomposites, including formation by layer-by-layer and vacuum assisted flocculation.
    Type: Grant
    Filed: February 28, 2014
    Date of Patent: March 20, 2018
    Assignee: The Regents of The University of Michigan
    Inventors: Nicholas A. Kotov, Yoonseob Kim, Jian Zhu, Matthew Di Prima, Bongjun Yeom
  • Publication number: 20140249526
    Abstract: New stretchable electrically conductive composite materials comprising at least one polymer and a plurality of nanoparticles are provided, which exhibit high conductivity even at high strain levels. The composite may comprise polyurethane as the polymer and spherical gold nanoparticles. Such materials have conductivity levels as high as 11,000 Scm?1 at 0% strain and 2,400 Scm?1 at 110% strain. Furthermore, certain embodiments of the composite have a maximum tensile strain of 480% while still exhibiting conductivity of 35 Scm?1. The inventive materials are highly flexible, highly conductive and suitable for a variety of applications, especially for advanced medical devices, implants, and flexible electronics. The disclosure also provides methods of making such stretchable electrically conductive nanocomposites, including formation by layer-by-layer and vacuum assisted flocculation.
    Type: Application
    Filed: February 28, 2014
    Publication date: September 4, 2014
    Inventors: Nicholas A. Kotov, Yoonseob Kim, Jian Zhu, Matthew Di Prima, Bongjun Yeom