Christopher W. Jones Explained

Christopher W. Jones is an American chemical engineer and researcher on catalysis and carbon dioxide capture.[1] In 2022 he is the John Brock III School Chair and Professor of Chemical & Biomolecular Engineering and adjunct professor of chemistry and biochemistry at the Georgia Institute of Technology, in Atlanta, Georgia. Previously he served as associate vice president for research at Georgia Tech (2013-2019), including a stint as interim executive vice-president for research in 2018.

Early life and education

Jones was born in Michigan, where he graduated from Troy High School in 1991. He earned a bachelor's degree from the University of Michigan and masters and doctorate degrees from the California Institute of Technology, all in chemical engineering. Following a post-doctoral appointment in chemistry and chemical engineering at the California Institute of Technology, he joined the faculty at the Georgia Institute of Technology in 2000.

Career

Jones has been recognized for his contributions to research in catalysis by the American Chemical Society with the Ipatieff Prize in 2010, the North American Catalysis Society with the Paul H. Emmett Award in Fundamental Catalysis in 2013 and the American Society of Engineering Education with the Curtis W. McGraw Research Award, also in 2013. The American Institute of Chemical Engineers recognized him as a leading mid-career researcher in 2017 with the Andreas Acrivos Award for Professional Progress in Chemical Engineering.[2] He was elected to the National Academy of Engineering in 2022 for his contributions to the design and synthesis of catalytic materials and for advancing technologies related to carbon capture and sequestration.[3] [4]

In scholarly publishing, Jones has led multiple successful new journals. In 2011, he was selected by the American Chemical Society (ACS) as the Founding Editor-in-Chief of the new interdisciplinary catalysis journal, ACS Catalysis, which was recognized by the Association of American Publishers as the Best New Journal in Science, Technology & Medicine in 2012.[5] In 2020, he was named the founding Editor-in-Chief of the new open access chemistry journal JACS Au, which is also published by the ACS. He has over 300 journal publications and patents.

Jones conducts research in the field of direct air capture, an approach to the mitigation of climate change in which carbon dioxide is extracted from the atmosphere for sequestration as a means to reduce the global atmospheric carbon dioxide level.[6] Jones is the leading researcher on direct air capture according to a 2022 biobliometric analysis.[7] He is an expert on the use of solid materials containing amines to capture carbon dioxide from air and other ultra-dilute gases,[8] [9] and has partnered with Global Thermostat, LLC, as well as other firms, to develop commercial technologies based on his research in adsorption.[10]

In 2016 Jones published a comprehensive review of materials and technologies for direct air capture.[11] In 2017-2018, he co-led the study of direct air capture technologies and identified knowledge gaps and research needs as part of the US National Academies study of carbon dioxide removal and negative emissions technologies.[12] [13] His updated perspective on research needs in direct air capture was published in 2022.[14]

External links

Notes and References

  1. Web site: Dr. Christopher W. Jones.
  2. Web site: Christopher W. Jones. 2014-06-13.
  3. Web site: National Academy of Engineering Elects 111 Members and 22 International Members . 2022-08-15 . NAE Website.
  4. Web site: Three Named to National Academy of Engineering . 2022-08-15 . coe.gatech.edu . en.
  5. Web site: Prose Award. 2021-08-20.
  6. http://www.chbe.gatech.edu/news/2017/12/influential-research-chbe-professor-chris-jones-work-direct-co2-capture.
  7. 10.1016/j.scca.2022.100009. The impact of Direct Air Capture during the last two decades: A bibliometric analysis of the scientific research, part I. 2022. Casaban. Daniel. Ritchie. Sean. Tsalaporta. Elena. Sustainable Chemistry for Climate Action. 1. 100009. free.
  8. 10.1021/acs.accounts.5b00284. Amine–Oxide Hybrid Materials for CO2 Capture from Ambient Air. 2015. Didas. Stephanie A.. Choi. Sunho. Chaikittisilp. Watcharop. Jones. Christopher W.. Accounts of Chemical Research. 48. 10. 2680–2687. 26356307. free.
  9. http://www.greengeek.ca/new-process-to-remove-carbon-dioxide-from-the-air/ "New process to remove carbon dioxide from the air"
  10. Web site: Global Thermostat.
  11. 10.1021/acs.chemrev.6b00173. Direct Capture of CO2 from Ambient Air. 2016. Sanz-Pérez. Eloy S.. Murdock. Christopher R.. Didas. Stephanie A.. Jones. Christopher W.. Chemical Reviews. 116. 19. 11840–11876. 27560307. free.
  12. https://nas-sites.org/dels/studies/cdr/ "Negative Emissions Technologies and Reliable Sequestration: A Research Agenda".
  13. News: Scientists Push for a Crash Program to Scrub Carbon from the Air. The New York Times. 2018-10-24. Plumer. Brad.
  14. Kong . Fanhe . Rim . Guanhe . Song . MinGyu . Rosu . Cornelia . Priyadarshini . Pranjali . Lively . Ryan P. . Realff . Matthew J. . Jones . Christopher W. . January 2022 . Research needs targeting direct air capture of carbon dioxide: Material & process performance characteristics under realistic environmental conditions . Korean Journal of Chemical Engineering . en . 39 . 1 . 1–19 . 10.1007/s11814-021-0976-0 . 245711099 . 0256-1115.