Mark Humphrey graduated and received his PhD and DSc at the University of Adelaide. He has held positions at Universität Würzburg (1987-1989), the University of Illinois (1989-1990), and the University of New England (1990-1994), before being appointed to ANU.
He has been awarded fellowships by the Krupp Foundation (Germany, 1987), Alexander von Humboldt Foundation (Germany, 1987), CNRS (France, 1988), Telecom Research Laboratories (1991), the Royal Australian Chemical Institute (1997), the Science and Technology Agency (Japan, 2001), the Royal Society of Chemistry (UK, 2002), and the Japan Society for the Promotion of Science (2009), as well as the Gritton Fellowship by the University of Sydney (1990).
He was also awarded the inaugural RACI Organometallic Award (1998), the RACI Inorganic Award (Burrows Award) (2008), the RACI H.G. Smith Memorial Award (2010), the RACI A.E. Leighton Memorial Award (2017), and the David Syme Research Prize (2001), an ARC Australian Research Fellowship (1994), ARC Senior Research Fellowship (1999), and two ARC Australian Professorial Fellowships (2004, 2009), and a 1000 Talents Award (Chinese Government).
He has been Professeur Invité at the Université Rennes I (France) multiple times, Visiting Professor at the Katholieke Universiteit Leuven (Belgium), and is an Honorary Professor of Nanjing University of Science and Technology, Distinguished Professor at Tongji University (China), and Anniversary Professor of Jiangsu University (China). He is the Australian Director of the Australia-China Joint Research Centre for Functional Molecular Materials, and the Australian Director of an International Associated Laboratory (LIA) of the French CNRS. He was the President of the ACT Branch and Chair of the Inorganic Division of the Royal Australian Chemical Institute. He has served on the ARC's College of Expert's (2016-2018) and ERA Research Evaluation Committees (2012, 2018). He was promoted to Professor at ANU in 2003.
The aim of our research is the preparation of new types of potentially useful molecular materials. Understanding how chemical structure can control molecular properties is the key step, and this necessitates coupling chemical synthesis to a range of physical properties studies.
Research in the group involves organometallic, organic, coordination complex and polymer synthesis, spectroscopy, various electrochemical and spectroelectrochemical techniques, molecular modelling, electron microscopy and X-ray structural studies, and a wide range of nonlinear optical studies using high-power lasers.