Associate Professor of Inorganic Chemistry &
Director of Undergraduate Programs
Office: 2103 Hahn Hall South
BS Chemistry, University of California, Berkeley, CA, 1983
PhD Physical Chemistry, Stanford University, Stanford, CA, 1990
Postdoctoral Researcher, DuPont, 1990-1991
Assistant Professor of Chemistry, University of Colorado, Boulder, 1992-2000
Research Associate, Visiting Fellow and Instructor, Univ. of Colorado, Boulder, 2000-2001
Associate Professor of Chemistry, Virginia Tech, 2001-present
Honors and Awards:
Dr. Carroll B. Shannon Excellence in Teaching Award, 2010 and 2016
Certificate of Teaching Excellence Virginia Tech, College of Science, 2010
E. Gary Cook Faculty Teaching Award Virginia Tech, Department of Chemistry, 2008
Research Award E. I. DuPont, Wilmington, DE, Merit award for co-discovery of the first room temperature molecule-based ferromagnet, 1991
We are interested in creating room-temperature permanent magnets from organic molecules and Earth-abundant transition metals. This is a challenging problem because organic molecules are not normally open-shell species and therefore not usually useful for making magnets. Yet, the use of organic molecules as building blocks has the advantage of systematic tunability. For instance, replacing a single hydrogen atom with a fluorine atom on a molecule can produce a new molecule that is largely the same size and shape, but with different electronic properties. An example of this approach is a family of compounds we have reported that result from the reaction of vanadium hexacarbonyl, V(CO)6, and different fluorine-substituted-phenyltricyanoethylenes (FnPTCE, below), to produce solids of the formula V[FnPTCE]2. These become ferrimagnetically ordered at temperatures ranging from 160 K (no fluorine) to 315 K (fluorine in the 2,3,5 and 6 positions). Each of these solids is believed to be a network of S=3/2 V2+ cations bridged through the lone pairs on two or more nitrile nitrogen atoms on S=1/2 FnPTCE radical anions to give a ferrimagnet. What we have found is that the number of fluorine atoms on the phenyl ring and their position on the ring produce systematic effects on the magnetic ordering temperature of the resulting solid, allowing us to essentially “design” new magnets.
Another aspect of our work is working with researchers around the country to measure the interesting magnetic properties of their compounds. Using our Quantum Design SQUID magnetometer, we have collaborated with groups at Georgetown (Stoll), UMSL (Holmes), Vanderbilt (Hanusa), Virginia Tech (Dorn) among many others.
- “Room Temperature and Near Room Temperature Molecule-based Magnets” Harvey, M. D.; Crawford, T. D.; Yee, G. T. Inorg .Chem. 2008, 47, 5649-5655.
- “Room temperature and near-room temperature coordination polymer magnets” Harvey, M. D.; Amshumali, M. K.; Yee, G. T. Synthetic Metals 2014, 188, 53-56.
- “Gd3N@C84(OH)x: A New Egg-Shaped Metallofullerene” Zhang, J.; Ye, Y.; Chen, Y.; Pregot, C.; Li, T.; Balasubramaniam, S.; Hobart, D. B.; Zhang, Y.; Wi, S.; Davis, R. M.; Madsen, L. A.; Morris, J. R.; LaConte, S. M.; Yee, G. T. and Dorn, H. C. J. Am. Chem. Soc. 2014, 136, 2630–2636.
- “Synthesis and Characterization of Di- and Trivalent Pyrazolylborate β-Diketonates and Cyanometalates” Tang, M.; Li, D.; Mallik, U. P.; Zhang, Y-Z.; Clérac, R.; Yee, G. T.; Whangbo, M-H.; Mungalimane, A.; Holmes, S. M. Inorg. Chem., 2011, 50, 5153–5164.