Professor of Physics
Ph.D., 1992 - Cornell University
Louisiana State University
Department of Physics & Astronomy
211-B Nicholson Hall, Tower Dr.
Baton Rouge, LA 70803-4001
(225) 578-2606-Office, 9105-Lab
Experimental Condensed Matter Physics
Magnetic materials that can be manipulated with the same control as present day electronic materials based on silicon technology are required for future development of spintronics and spin-based version of quantum computing. Spintronics has been coined to refer to devices that make use of not only the charge properties of semiconductors and metals, as in today's transistor based devices, but also of the carriers spin (intrinsic angular momentum). We have focused our research on materials systems that may offer such control. This includes silicon based magnetic semiconductors, germanides, oxides, and sulfides where the carrier concentration and magnetic state can be controlled chemically or with external pressure. In addition, an understanding of the properties of these materials requires exploration of their low temperature properties. Since these materials are typically near metal-insulating and non-magnetic to magnetic phase transitions the physics of quantum phase transitions play a role in determining their low temperature properties.
My research interests include: Magnetic semiconductors, quantum critical behavior in low carrier density materials, magnetoresistive materials and mechanisms of magnetoresistance, and quantum spin systems such as one-dimensional antiferromagnets which can be carrier doped.
Image above describes quantum critical physics of spin systems with temperature decreasing in the foreground. The green oval represents unpaired spin complexes responsible for the inelastic scattering which causes the non-Fermi liquid behavior. Light blue oval region demonstrates that the majority of the magnetic moments in the system are coupled into a singlet state.
Current and Select Publications
Cao G, Xie W, Phelan WA, DiTusa JF, Jin R. 2017. Electrical anisotropy and coexistence of structural transitions and superconductivity in IrTe2. Phys Rev B 95:035148. http://journals.aps.org/prb/abstract/10.1103/PhysRevB.95.035148
Dhital C, Khan MA, Saghayezhian M, Phelan WA, Young DP, Jin RY, DiTusa JF. 2017. Effect of negative chemical pressure on the prototypical itinerant magnet MnSi. Phys Rev B 95:024407. http://journals.aps.org/prb/abstract/10.1103/PhysRevB.95.024407
- DiTusa, J. F., Goodrich, R. G., Harrison, N., & Choi, E. S.,"Fermi surface of Ce1-xVx across the quantum critical point," Phys. Rev. B 82, 075114 (2010).
- Manyala, N., DiTusa, J. F., Aeppli, G., & Ramirez, A. P., "Doping a semiconductor to create an unconventional metal," Nature 454, 976-980 (2008).
- Capan, C., Jo, Y-J., Balicas, L. Goodrich, R. G., DiTusa, J. F., Vekhter, I., Murphy, T. P., Bianchi, A. D., Pham, L. D., Cho, J. Y., Chan, J. Y., Young, D. P., & Fisk, Z., "Fermi surface evolution through a heavy fermion superconductor-to-antiferromagnet transition: de Haas-van Alphen effect in Cd substituted CeCoIn5," Phys. Rev. B 82, 035112 (2010) [Editors’ suggestion].
- Guo, S., Young, D. P., Macaluso, R. T., Browne, D. A., Henderson, N. L., Chan, J. Y., Henry, L. L., & DiTusa, J. F., "Discovery of the Griffiths phase in the itinerant magnetic semiconductor Fe1-xCoxS2," Phys. Rev. Lett. 100, 017209 (2008).