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Gang H Fan

from Austin, TX
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Also known as:
Fan Gang
Related to:
Dan XuLin L Lin, 58George Q Xu, 74Renling Xu, 64Fang Liu, 51Wei Q Xu, 49
Connected to:
Allison Fan, 29Bei Fan, 44Bobby H Fan, 55Bonnie P Fan, 33Brian W Fan, 61Caleb K Fan, 27Charles W Fan, 53Cheng G Fan, 60Chenming Fan, 40Chi R Fan, 67

Gang Fan Phones & Addresses

  • Austin, TX
  • 1300 S Pleasant Valley Rd, Austin, TX 78741

Work

Company: Massachusetts institute of technology (mit) Sep 2020 Position: Postdoctoral researcher

Education

Degree: Doctorates, Doctor of Philosophy School / High School: The University of Texas at Austin 2011 to 2019 Specialities: Chemical Engineering, Philosophy

Languages

English • Mandarin

Ranks

Certificate: Master In Light Scattering

Industries

Chemicals

Resumes

Resumes

Gang Fan Photo 1

Postdoctoral Researcher

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Location:
Austin, TX
Industry:
Chemicals
Work:
Massachusetts Institute of Technology (Mit)
Postdoctoral Researcher
The University of Texas at Austin
Graduate Research Assistant
Technische Universität München Jun 2014 - Jul 2014
Research Fellow
Tianjin University Aug 2011 - Jun 2014
Graduate Researcher
National Center For Nanoscience and Technology Oct 2012 - Mar 2014
Research Fellow
Education:
The University of Texas at Austin 2011 - 2019
Doctorates, Doctor of Philosophy, Chemical Engineering, Philosophy Tianjin University 2011 - 2013
Masters, Chemical Engineering
Languages:
English
Mandarin
Certifications:
Master In Light Scattering

Publications

Us Patents

Metabolic Control Over Organometallic Catalysts Using Electroactive Bacteria

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US Patent:
20210017552, Jan 21, 2021
Filed:
Mar 26, 2019
Appl. No.:
15/733681
Inventors:
- Austin TX, US
Gang FAN - Austin TX, US
Chris DUNDAS - Austin TX, US
Austin GRAHAM - Austin TX, US
Nathaniel LYND - Austin TX, US
International Classification:
C12P 7/62
Abstract:
Disclosed herein is a method for effecting atom or group transfer polymerization comprising polymerizing one or more radically-polymerizable monomers in the presence of a system comprising an electrically active micro-organism, a transition metal catalyst, one or more radically-polymerizable monomers, and a radical initiator. Micro-organism respiratory electron flux is harnessed to control the performance of a metal-catalyzed polymerization. The bacterial electron transport pathways of the electroactive micro-organisms can be engineered to tune and adapt various function of the electroactive micro-organism and its role in polymerization. Polymerization may be accomplished under aerobic or anaerobic conditions. Freshly cultured micro-organisms or lyophilized micro-organisms may be used to direct polymerization.
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Gang H Fan from Austin, TX Get Report