Realizing the Strongly Correlated d-Wave Mott-Insulator State in a Fermionic Cold-Atom Optical Lattice

Michael Peterson; Chuanwei Zhang; Sumanta Tewari; Sankar Das Sarma

Realizing the Strongly Correlated $d$-Wave Mott-Insulator State in a Fermionic Cold-Atom Optical Lattice

ORAL

Abstract

We show that a new state of matter, the $d$-wave Mott-insulator state ($d$-Mott state) (introduced recently by [H. Yao, W. F. Tsai, and S. A. Kivelson, Phys. Rev. B 76, 161104 (2007)]), which is characterized by a nonzero expectation value of a local plaquette operator embedded in an insulating state, can be engineered using ultracold atomic fermions in two-dimensional double-well optical lattices. We characterize and analyze the parameter regime where the $d$-Mott state is stable. We predict the testable signatures of the state in the time-of-flight measurements.

^*Work supported by ARO-DARPA.

March 19, 2009, 2:42 PM – March 19, 2009, 2:54 PM

Authors

Michael Peterson
- University of Maryland
Chuanwei Zhang
- University of Maryland
Sumanta Tewari
- University of Maryland
Sankar Das Sarma
- Condensed Matter Theory Center, Department of Physics, University of Maryland, College Park, MD
- University of Maryland
- University of Maryland, College Park
- Condensed Matter Theory Center, Department of Physics, University of Maryland, College Park MD 20742