Pierre Deymier

Pierre A. Deymier is a researcher in phononics,^[1] acoustic metamaterial,^[1] and materials science. He is a Professor of Materials Science and Engineering and previously department head at the University of Arizona.^[2] He holds appointments with the applied mathematics graduate interdisciplinary program,^[3] BIO5 institute, and School of Sustainable Engineered Systems at the University of Arizona. More recently, he has proposed a novel approach akin to quantum computing using the properties of phonons rather than qubits, which he has dubbed "phi-bits" or "phase-bits".^[4][5]

Pierre A. Deymier
Born	France
Nationality	French
Citizenship	USA, France
Alma mater	MIT, University of Montpellier
Known for	Acoustic metamaterial, Materials science, Computational materials science
Title	Professor of Materials Science & Engineering
Scientific career
Fields	Phononics, Acoustic metamaterial, Quantum computing, Materials science
Institutions	University of Arizona
Doctoral advisor	Gretchen Kalonji
Doctoral students	Frank J. Cherne, Vivek Kapila, Krishna Muralidharan, Javier Carmona, Jim Bucay, Nick Swinteck, Stefan Bringuier, Abdul-Jabar Alsayoud

Biography

Education

Deymier received his engineer's degree in materials science in 1982 from University of Montpellier in France and his Ph.D. in Materials Science & Engineering from MIT in 1985.^[6] His dissertation research was focused on computational materials science.^{[citation needed]} He became assistant professor of materials science & engineering at the University of Arizona in 1985.^[6]

Personal life

His daughter, Alix Deymier, is a professor of biomedical engineering at the University of Connecticut.^{[citation needed]}

Publications

Deymier has published over 180 peer-reviewed publications.^[7] Some of his most highly cited works are:

1. Deymier, P. A.(Ed.). (2013). Acoustic metamaterials and phononic crystals (Vol. 173). Springer Science & Business Media. (Cited 714 times, according to Google Scholar)
2. Vasseur, J. O., Deymier, P. A.. Chenni, B., Djafari-Rouhani, B., Dobrzynski, L., & Prevost, D. (2001). Experimental and theoretical evidence for the existence of absolute acoustic band gaps in two-dimensional solid phononic crystals. Physical Review Letters, 86(14), 3012. (open access) (Cited 574 times, according to Google Scholar.)
3. Sukhovich A, Merheb B, Muralidharan K, Vasseur JO, Pennec Y, Deymier PA, Page JH. Experimental and theoretical evidence for subwavelength imaging in phononic crystals. Physical review letters. 2009 Apr 17;102(15):154301 (open access) (Cited 314 times, according to Google Scholar.)
4. Pennec Y, Vasseur JO, Djafari-Rouhani B, Dobrzyński L, Deymier PA. Two-dimensional phononic crystals: Examples and applications. Surface Science Reports. 2010 Aug 31;65(8):229-91. (Cited 491 times, according to Google Scholar.)
5. Vasseur, J. O., Deymier, P. A. Djafari-Rouhani, B., Pennec, Y., & Hladky-Hennion, A. C. (2008). Absolute forbidden bands and waveguiding in two-dimensional phononic crystal plates. Physical Review B, 77(8), 085415. (open access) (Cited 307 times, according to Google Scholar.)

Awards

• Felix Bloch Award, 2023, International Phononics Society^[usurped]. The prize honors individuals who have made “outstanding and sustained contributions in the field of phononics”.^[8]