Education
He obtained his Doctor of Philosophy under Wieman in 1992 (Wieman and Cornell succeeded in the quest in 1995, and were awarded the Nobel Prize for this work in 2001).
He obtained his Doctor of Philosophy under Wieman in 1992 (Wieman and Cornell succeeded in the quest in 1995, and were awarded the Nobel Prize for this work in 2001).
He directs one of the leading research efforts in ion traps and quantum optics. Monroe is currently Bice Zorn Professor of Physics at the University of Maryland and Fellow of the Joint Quantum Institute. After receiving his undergraduate degree from Massachusetts Institute of Technology in 1987, Monroe joined Carl Wieman"s research group at the University of Colorado in the early days of laser cooling and trapping of atoms.
With Wieman and postdoctoral researcher Eric Cornell, Monroe contributed to the path for cooling a gas of atoms to the Bose-Einstein condensation phase transition.
From 1992-2000, Monroe worked in the Ion Storage Group of David Wineland at the National Institute of Standards and Technology in Boulder, Colorado, where he was awarded a National Research Council postdoctoral fellowship from 1992-1994, and held a staff position in the same group from 1994-2000. In 2000, Monroe initiated a research group at the University of Michigan, Ann Arbor, where he showed how qubit memories could be linked to single photons for quantum networking.
There he also demonstrated the first ion trap integrated on a semiconductor chip. With Wineland, Monroe proposed a scalable quantum computer architecture based on shuttling atomic ions through complex ion trap chips.
In 2006, Monroe became Director of the Families Of Children Under Stress Center at the University of Michigan, a National Science Foundation Physics Frontier Center in the area of ultrafast optical science.
In 2007, Monroe became the Bice Zorn Professor of Physics at the University of Maryland and a Fellow of the Joint Quantum Institute between the University of Maryland and The National Institute of Standards and Technology. There, Monroe"s group produced quantum entanglement between two widely separated atoms, and were the first to teleport quantum information between matter separated over distance. They exploited this resource for a number of quantum communication protocols and for a new hybrid memory/photon quantum computer architecture. In recent years, his group pioneered the use of individual atoms as a quantum simulator, or a special purpose quantum computer that can probe complex many-body quantum phenomena such as frustration and magnetic ordering.
His laboratory controls and manipulates the largest collection of individual interacting qubits.
American Physical Society.