Kevin Storr earned a Ph.D. in low temperature condensed matter physics from the Florida State University at the National High Magnetic Field Laboratory in Tallahassee Florida. He is currently an associate professor of physics at Prairie View A&M University where he mentors undergraduate students in physics research along with directing the thesis of graduate students. He is a member of the Texas Physics Consortium and former faculty senator. He is also known as the Professor of Value. Kevin Storr conducts colloquia in areas of value, leadership, science and education. He is the director of the newly formed, “Global Value Initiative.” He is the recipient of the International Golden Rule Award, The Girma Wolde-Giorgis, Human Conservation Solutionist Award and serves as special advisor to the office of the ambassador-at-large for the Republic of Burundi.

In the area of condensed matter, we use extreme environmental conditions of temperature (down to 20 millikelvin) and magnetic field (≤ 45 Tesla) to elucidate and tune the electronic, magnetic and thermal properties of candidate materials using several techniques. Three of our most commonly employed techniques are: electrical transport, magnetic torque cantilever and specific heat. Here we present results from three classes of materials, each studied using similar methods: organic conductors, heavy fermion systems and hybridized graphene. λ-(BETS)2FeCl4 is a quasi, two dimensional, layered, anisotropic organic conductor which has shown three states below liquid helium temperature: an antiferromagneticinsulator state, metallic state, and a field induced superconducting (FISC) ground states with observed reentrance. Nd1−xCexCoIn5 is 115 heavy fermion single crystal which exhibits unconventional superconductivity due to being an intermetallic compounds with large electron effective masses. This material can progress from having local moment magnetism to a heavy fermion with the gradual substitution of Nd with Ce. This leads to an adjustment of the availability of 4f electron coupling. Hybridized graphene and hexagonal boron nitride (h-BNC) domains as a disordered 2D electronic system was studied using magnetoelectric transport measurements. It clearly showed show an insulating to a metallic anomalous transition during the cooling process which we modulated with electron and hole-doping. It was concluded that in comparison to other 2D systems, that in h-BNC the transition came about from percolation associated with the metallic graphene and hopping conduction along edge states.