Stephen John Blundell (born 1967)[1] is a professor of physics at the University of Oxford. He was previously head of Condensed Matter Physics at Oxford, and is also a professorial fellow of Mansfield College, Oxford. His research is concerned with using muon-spin rotation and magnetoresistance techniques to study a range of organic and inorganic materials, particularly those showing interesting magnetic, superconducting, or dynamical properties.[2]
Stephen Blundell | |
---|---|
Born | Stephen John Blundell 1967 (age 56–57)[1] |
Alma mater | University of Cambridge (BA, PhD) |
Spouse | Katherine Blundell |
Awards | Daiwa Adrian Prize |
Scientific career | |
Fields | Physics |
Institutions | University of Oxford |
Thesis | Spin-dependent transport in artificial structures (1993) |
Website | users |
Education
editBlundell completed both his undergraduate and graduate studies at the University of Cambridge, attending Peterhouse, Cambridge for his undergraduate degree in physics and theoretical physics and doing his PhD at the Cavendish Laboratory at Cambridge.[3]
Career and research
editHe was subsequently offered a Science and Engineering Research Council (SERC) research fellowship which involved a move to the Clarendon Laboratory at Oxford; he was later awarded a junior research fellowship at Merton College, Oxford, where he began research in organic magnets and superconductors using muon-spin rotation. In 1997 he was appointed to a university lectureship in the Oxford Physics Department and a tutorial fellowship at Mansfield College, Oxford, and was subsequently promoted to Reader.[when?] In 2004 he was awarded the title of Professor of Physics.[4]
Blundell has authored two textbooks, the first being Magnetism in Condensed Matter,[5] which covers the quantum mechanical nature of magnetism. Most recently he has co-authored, with his wife and colleague, astrophysicist Katherine Blundell of St John's College, Oxford, a textbook entitled Concepts in Thermal Physics.[6] It provides an introduction to the topics of thermal physics and statistical mechanics covered in a typical undergraduate course in physics. Additionally, he has authored the Superconductivity: A Very Short Introduction,[7] part of the Very Short Introductions series published by Oxford University Press, as well as a pedagogical book on quantum field theory with Tom Lancaster.
He has authored or co-authored over 300 articles[2] ranging right across the world of solid-state physics.[8]
Awards and honours
editBlundell was a joint winner of the Daiwa Adrian Prize in 1999 for his work on organic magnets.[6] He was awarded the 2024 Lawrence Bragg Medal and Prize "for contributions to physics scholarship and education through the publication of widely used and influential physics textbooks".[9]
Personal life
editBlundell lives in Oxford with his wife, Professor Katherine Blundell. In 2001, he was quoted in Science as saying, "Ultimately your marriage is more important than your career."[10]
References
edit- ^ a b Stephen J. Blundell at Library of Congress
- ^ a b Stephen Blundell publications indexed by the Scopus bibliographic database. (subscription required)
- ^ Blundell, Stephen John (1993). Spin-dependent transport in artificial structures. lib.cam.ac.uk (PhD thesis). University of Cambridge. OCLC 557401624. EThOS uk.bl.ethos.309331.
- ^ "Recognition of Distinction 2003-2004", Supplement (1) to The Oxford University Gazette, no. 4706 (23 September 2004). Retrieved 20 November 2016.
- ^ Blundel, Stephen (2001). Magnetism in Condensed Matter. Oxford University Press. ISBN 9780198505914.
- ^ a b Blundell, Stephen J.; Blundell, Katherine M. (2010). Concepts in thermal physics (2nd ed.). Oxford: Oxford University Press. doi:10.1093/acprof:oso/9780199562091.001.0001. ISBN 9780199562107. OCLC 607907330.
- ^ Blundel, Stephen (2009). Superconductivity: A Very Short Introduction. Oxford University Press. ISBN 9780199540907.
- ^ "Stephen Blundell Publications". users.ox.ac.uk.
- ^ "2024 Lawrence Bragg Medal and Prize | Institute of Physics".
- ^ Jamieson, Valerie (October 3, 2001). "Love and the two-body problem". sciencemag.org: 37.