N. Peter Armitage


N. Peter Armitage is an American physicist who is currently a Professor of Physics and Astronomy at The Johns Hopkins University. His research centers on understanding material systems which exhibit coherent quantum effects at low temperatures, like superconductors and quantum magnetism.  His principal scientific interest is understanding how is it that large ensembles of strongly interacting, but fundamentally simple particles like electrons in solids act collectively to exhibit complex emergent quantum phenomena.  He exploits and develops techniques using low frequency microwave and THz range radiation that probe these systems at their natural frequency scales. The material systems of interest require new measurement techniques as their relevant frequencies typically fall between the range of usual optical and electronic methods.

Career

Armitage received a BS degree from Rutgers University and a PhD from Stanford University in 2002. He did postdoctoral work at the University of California, Los Angeles and the University of Geneva. He joined the faculty of Johns Hopkins in 2006 as an assistant professor of physics and is currently a Professor of Physics and Astronomy.
He is known primarily for is work on superconductivity, magnetism, disordered systems, and topological materials. Most recently his group succeeded in measuring the quantized magnetoelectric "axion" response of topological insulators. This quantized response is the 3D equivalent in topological insulators of the quantized Hall plateaus found in quantum Hall systems.
Armitage has been a recipient of a DARPA Young Faculty Award, an NSF Career Award, a Sloan Research Fellowship, was a three time Kavli Frontiers Fellow, the William Spicer Award from the Stanford Synchrotron Radiation Laboratory, the from the University of Illinois, the , and was the at the UCSB Materials Department. He is a member of the Quantum Materials Program at the Canadian Institute for Advanced Research
and was the co-chair of the 2014 Gordon Research Conference in Correlated Electron Systems.