Biography:Avadh Saxena

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Short description: American physicist

Avadh Saxena
Avadh recent photo.jpg
Born
India
Scientific career
FieldsCondensed matter physics/material physics, quantum physics, nonlinear science
Institutions
Doctoral advisorJames D. Gunton[1]

Avadh B. Saxena is an American physicist and currently the Group Leader of Physics of Condensed Matter and Complex Systems Group (T-4) at Los Alamos National Laboratory, New Mexico, United States.[2] His contributions cover a range of topics including phase transitions, functional materials, topological defects such as solitons and skyrmions, and Non-Hermitian quantum mechanics. Saxena completed his PhD at the Temple University in 1986 (advisor: James D. Gunton[1]). Subsequently, he held a joint postdoc position at the Materials Research Lab at Penn State (with Gerhard R. Barsch) and Cornell University (with James A. Krumhansl). In 1990 he came to Los Alamos National Laboratory as a visiting scientist/consultant to the Theoretical Division (with Alan R. Bishop), and in 1993 became a Technical Staff Member. In January 2006 he assumed the Deputy Group Leader position of the Condensed Matter and Statistical Physics Group (formerly T-11) and since January 2009 he is the Group Leader of T-4. He is currently also an affiliate professor at the KTH Royal Institute of Technology,[3] and adjunct professor at the University of Barcelona, University of Crete, Greece, Virginia Tech, and University of Arizona, and scientific advisor at the National Institute for Materials Science at Tsukuba, Japan. He is a Fellow of Los Alamos National Laboratory, a Fellow of the American Physical Society (APS), and a member of the Sigma Xi Scientific Research Society and APS.

Academic career

Avadh has more than 475 publications with over 12,000 citations and an h-index of 54 (Google Scholar). He has also co-edited 6 Springer books [4][5][6][7][8][9] in addition to several special journal issues. He is also slated to write a book on the topic of phase transitions in materials (Cambridge University Press). In addition, he has co-organized over 50 international conferences on various research topics.

His main research interests include phase transitions, optical, electronic, vibrational, transport and magnetic properties of functional materials, device physics, soft condensed matter, geometry, topology and nonlinear phenomena. Recently he has been coordinating theoretical efforts at LANL in the context of Beyond Moore's Law[10] quantum computing.

Saxena completed his PhD at the Temple University in 1986 under the supervision of James D. Gunton.[1] In 1990 he was a visiting scientists at Los Alamos National Laboratory, becoming a Technical Staff Member in 1993. He is an affiliate professor at the KTH Royal Institute of Technology,[11] and adjunct professor at the University of Barcelona, University of Crete, Greece, Virginia Tech, and University of Arizona. Avadh serves on many international advisory committees/boards, e.g., ICOMAT,[12] CIMTEC,[13] Deployable Quantum Computing,[14] etc.

Most cited publications

  1. Conformational dynamics of photoexcited conjugated molecules
    By: Tretiak, S; Saxena, A; Martin, RL; et al. Physical Review Letters Volume: 89 Issue: 9 Article Number: 097402 Published: AUG 26 2002
  2. 2-Band Model for Halogen-Bridged Mixed-Valence Transition-Metal Complexes. 1. Ground-state and Excitation Spectrum
    By: Gammel, JT; Saxenx, A; Batistic, I; et al. Physical Review B Volume: 45 Issue: 12 Pages: 6408-6434 Published: MAR 15 1992
  3. Efficient computation of the structural phase behavior of block copolymers
    By: Tzeremes, G; Rasmussen, KO; Lookman, T; et al. Physical Review E Volume: 65 Issue: 4 Article Number: 041806 Part: 1 Published: APR 2002
  4. Real-time observation of nonlinear coherent phonon dynamics in single-walled carbon nanotubes
    By: Gambetta, A.; Manzoni, C.; Menna, E.; et al. NATURE PHYSICS Volume: 2 Issue: 8 Pages: 515-520 Published: AUG 2006
  5. Molecular geometry fluctuation model for the mobility of conjugated polymers
    By: Yu, ZG; Smith, DL; Saxena, A; et al. Physical Review Letters Volume: 84 Issue: 4 Pages: 721-724 Published: JAN 24 2000
  6. Ferroelastic dynamics and strain compatibility
    By: Lookman, T; Shenoy, SR; Rasmussen, KO; et al. Physical Review B Volume: 67 Issue: 2 Article Number: 024114 Published: JAN 1 2003
  7. Particle model for skyrmions in metallic chiral magnets: Dynamics, pinning, and creep
    By: Lin, Shi-Zeng; Reichhardt, Charles; Batista, Cristian D.; et al. Physical Review B Volume: 87 Issue: 21 Article Number: 214419 Published: JUN 17 2013
  8. Martensitic textures: Multiscale consequences of elastic compatibility
    By: Shenoy, SR; Lookman, T; Saxena, A; et al. Physical Review B Volume: 60 Issue: 18 Pages: 12537-12541 Published: NOV 1 1999
  9. Molecular geometry fluctuations and field-dependent mobility in conjugated polymers
    By: Yu, ZG; Smith, DL; Saxena, A; et al. Physical Review B Volume: 63 Issue: 8 Article Number: 085202 Published: FEB 15 2001
  10. Thermally activated avalanches: Jamming and the progression of needle domains
    By: Salje, E. K. H.; Ding, X.; Zhao, Z.; et al. Physical Review B Volume: 83 Issue: 10 Article Number: 104109 Published: MAR 25 2011

References

  1. 1.0 1.1 1.2 "James D. Gunton". https://www.lehigh.edu/~jdg4/. 
  2. "CNLS People". https://cnls.lanl.gov/external/people/Avadh_Saxena.php. 
  3. "LANL Science Highlights, June 27, 2018". https://www.lanl.gov/science-innovation/science-highlights/2018/2018-06.php#award-6. 
  4. Planes, Antoni; Mañosa, Lluís; Saxena, Avadh (2005). Magnetism and Structure in Functional Materials. Springer Series in Materials Science. 79. doi:10.1007/3-540-31631-0. ISBN 978-3-540-23672-6. Bibcode2005msfm.book.....P. https://link.springer.com/book/10.1007/3-540-31631-0. 
  5. Disorder and Strain-Induced Complexity in Functional Materials. Springer Series in Materials Science. 148. 2012. doi:10.1007/978-3-642-20943-7. ISBN 978-3-642-20942-0. https://link.springer.com/book/10.1007/978-3-642-20943-7. 
  6. Saxena, Avadh; Planes, Antoni (2014). Mesoscopic Phenomena in Multifunctional Materials. Springer Series in Materials Science. 198. doi:10.1007/978-3-642-55375-2. ISBN 978-3-642-55374-5. Bibcode2014mpmm.book.....S. https://link.springer.com/book/10.1007/978-3-642-55375-2. 
  7. Avalanches in Functional Materials and Geophysics. Understanding Complex Systems. 2017. doi:10.1007/978-3-319-45612-6. ISBN 978-3-319-45610-2. https://link.springer.com/book/10.1007/978-3-319-45612-6. 
  8. The Role of Topology in Materials. Springer Series in Solid-State Sciences. 189. 2018. doi:10.1007/978-3-319-76596-9. ISBN 978-3-319-76595-2. https://link.springer.com/book/10.1007/978-3-319-76596-9. 
  9. Emerging Frontiers in Nonlinear Science. Nonlinear Systems and Complexity. 32. 2020. doi:10.1007/978-3-030-44992-6. ISBN 978-3-030-44991-9. https://link.springer.com/book/10.1007/978-3-030-44992-6. 
  10. "Beyond's Moore's Law, IEEE Future Direction". https://cmte.ieee.org/futuredirections/2019/03/10/beyond-moores-law/. 
  11. "KTH Royal Institute of Technology". https://www.kth.se/en. 
  12. "16th International Conference on Martensitic Transformation (ICOMAT 2020)". http://www.icomat2020.org/main/ci_overview.htm. 
  13. "15th International Ceramic Congress (CIMTEC 2020)". http://2020.cimtec-congress.org/. 
  14. "TOPQC 2019". https://topqc.org/. 

External links