Asegun Henry

Asegun Sekou Famake Henry is a Robert N. Noyce Career Development Professor in mechanical engineering at Massachusetts Institute of Technology. His research is focused on energy storage, heat transfer, and phonons.

Early life and education

Henry was born in Tallahassee, Florida, to Anthony Henry and Oare Dozier-Henry, both former professors at Florida A&M University (FAMU); his father is a middle school teacher and adjunct professor of political science and his mother is a professor of adult education.[1] At a young age, his parents exposed him to West African and African-American culture. At ten years old, he started playing the djembe. Henry also excelled in school and was admitted into a state program for gifted children.[1] After graduating from high school, he attended FAMU and graduated with a bachelor's degree in mechanical engineering.[2] Working under Gang Chen, he earned his master's and doctorate degrees in mechanical engineering from Massachusetts Institute of Technology (MIT) in 2009.[2]

Career and research

After graduating from MIT, Henry worked as a postdoc in materials science at Oak Ridge National Laboratory, researching derivations of thermal conductivity from first principles, and later at Northwestern University, where he investigated the thermodynamic properties of oxides.[2][3] He received research fellowships from the Lemelson Foundation, the Department of Energy, the UNCF, and Ford Foundation.[3]

In 2011, Henry was a fellow of the Advanced Research Projects Agency–Energy[3] before he joined Georgia Institute of Technology in April 2012 as assistant professor in the George W. Woodruff School of Mechanical Engineering.[2]

In 2016, Henry earned the National Science Foundation’s Career Award with a grant to study heat conduction via vibrations referred to as phonons. Using sonification, his research hopes to create an educational app to represent the unique vibrations of the elements in the periodic table as sounds audible to the human ear and to study the interaction between the different modes of vibration.[4][5]

On January 23, 2017, Henry’s team at Georgia Tech also achieved the highest recorded operating temperature, 1,200 °C (1,470 K), for a liquid pump which operated continuously for 72 hours.[6] The achievement was recognized by the Guinness World Records.[7] The pump is made entirely of ceramic materials and was able to pump molten tin heated to very high temperatures.[8][9]

Henry also conducts research into cost-effective methods to store renewable energy.[10] In a 2018 paper published Energy & Environmental Science, his team described a storage system, TEGS-MPV (thermal energy grid storage using multi-junction photovoltaics) and given the moniker "Sun in a box" in media sources. TEGS-MPV uses molten silicon as a battery to store energy as heat, ready to be delivered into an electrical grid on demand.[11][12][13] The system is slated to operate at costs significantly lower than existing electrical energy storage systems.[12][14]

References

  1. Angail, Nadirah (April 2016). "The Proud Conqueror: Asegun Henry, PhD". In Scott-Carrol, Joy M.; Sparks, Anthony (eds.). Running the Long Race in Gifted Education: Narratives and Interviews from Culturally Diverse Gifted Adults. Book Publishers Network. pp. 106–13. ISBN 9781945271007.
  2. "People". Georgia Tech Atomistic Simulation & Energy Research Group. Georgia Institute of Technology. Retrieved May 5, 2019.
  3. "Asegun Henry: Fellow, ARPA-E". ARPA-E Energy Innovation Summit. 2012. Retrieved May 5, 2019.
  4. Ouellette, Jennifer (February 22, 2016). "This Scientist Is Turning Every Element In the Periodic Table Into Music". Gizmodo. Retrieved May 5, 2019.
  5. "Award#1554050 - CAREER: Engineering Heat Conduction Through Alloys and Interfaces". National Science Foundation. February 29, 2016. Retrieved May 5, 2019.
  6. Rutherford, Adam (November 12, 2017). "BBC Inside Science: Antibiotics and Farming, Molten Metal Pump, Acoustic Biodiversity, Athenia". BBC Radio 4. Retrieved May 5, 2019.
  7. "Highest operating temperature liquid pump". Guinness World Records. Retrieved May 5, 2019.
  8. O’Heir, Jeff (May 2018). "Pumping Extremely Hot Metal, Part 1". ASME. Retrieved May 5, 2019.
  9. O’Heir, Jeff (May 2018). "Pumping Extremely Hot Metal, Part 2". ASME. Retrieved May 5, 2019.
  10. Wills, Stewart (December 11, 2018). "Putting the "Sun in a Box" for Energy Storage". Optics & Photonics News. Retrieved May 5, 2019.
  11. Czykanski, Marek (December 8, 2018). "Cost-Effective Storage for Renewable Energy". ChemistryViews. Retrieved May 5, 2019.
  12. Claburn, Thomas (December 8, 2018). "Boffins build blazing battery bonfire". The Register. Retrieved May 5, 2019.
  13. Irving, Michael (December 6, 2018). "MIT's conceptual "sun-in-a-box" energy storage system plugs into molten silicon". New Atlas. Retrieved May 5, 2019.
  14. Grossman, David (December 6, 2018). "Scientists Envision Replacing Batteries with a Molten Silicon 'Sun in a Box'". Popular Mechanics. Retrieved May 5, 2019.
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