CTQM | JILA Physics Frontier Center

Using Ion Crystals to Simulate Superconductors

A respresentation of the dynamics within the superconducting system

Former JILA Researchers Tobias Bothwell and Colin Kennedy receive the 2022 PML Distinguished Associate Award

Former JILA PhD student Tobias Bothwell (top) and former JILA postdoc Colin Kennedy (bottom) are both honored by NIST's Physical Measurement Laboratory

Read more about Former JILA Researchers Tobias Bothwell and Colin Kennedy receive the 2022 PML Distinguished Associate Award

A Quantum Video Reel

Defining the Limits of Quantum Sensing

A rendering of broadband sensing using quantum channels.

Atoms do the Twist

A rendering of the indifferent interactions of p-waves based on their angular momentum

JILA and NIST Fellow Ana Maria Rey Featured in Quantum Systems Accelerator Article

JILA and NIST Fellow Ana Maria Rey discusses her work in a new article by Quantum Systems Accelerator

Read more about JILA and NIST Fellow Ana Maria Rey Featured in Quantum Systems Accelerator Article

A Magic Balance in Optical Lattice Clocks

Local interactions in the same lattice pull clock frequency negative while interactions between atoms on neighboring lattice sites pull clock frequency positive. By adjusting the atomic confinement, or tightness, of the lattice, researchers can balance these two counteracting forces to increase clock sensitivity.

JILA and NIST Fellow Ana Maria Rey Featured in "Optica Community" Piece

Ana Maria Rey, a JILA and NIST Fellow is also a (2013) MacArthur Fellow. Credit: John D. and Catherine T. MacArthur Foundation.

Read more about JILA and NIST Fellow Ana Maria Rey Featured in "Optica Community" Piece

Clearing Quantum Traffic Jams under the SU(n) of Symmetric Collisions

An artistic rendering of the two planes of the atom's movement, with the real being a 1D lattice and the synthetic referring to the nuclear spin of the atom

Seeing Quantum Weirdness: Superposition, Entanglement, and Tunneling

Long-lived entangelement of Bell state pairs compared to single unentangled atoms in a 3D optical lattice. The Bell state "stopwatch" ticks twice as fast than that of a single atom, holding the promise of higher stability and higher bandwidth for optical clocks.

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