Precise, coherent, and robust atom interferometers 

Atom interferometers have been instrumental in precise measurements of fundamental constants and tests of fundamental laws of physics. But for new tests of the quantum nature of gravity (Carney et al. 2021) and for robust quantum sensing of acceleration and rotation in the field, atom interferometers must have coherences measured in minutes instead of seconds; sizes measured in centimeters instead of meters; and must be robust against vibrations and magnetic fields instead of requiring bulky shielding and vibration isolation. Lattice-hold atom interferometers are a recent addition to the atomic physicists’ toolbox to meet those challenges. We will discuss coherence limits in lattice interferometry at the one-minute scale (Panda, M. Tao, et al. 2024), their accuracy in sensing gravity (Panda, M. J. Tao, et al. 2024), and their robustness to environmental effects (Panda et al. 2023). 

Carney, Daniel, Holger Müller, and Jacob M. Taylor. 2021. “Using an Atom Interferometer to Infer Gravitational Entanglement Generation.” PRX Quantum 2 (3): 030330.

Panda, Cristian D., Matthew Tao, James Egelhoff, Miguel Ceja, Victoria Xu, and Holger Müller. 2024. “Coherence Limits in Lattice Atom Interferometry at the One-Minute Scale.” Nature Physics 20 (June): 1234.

Panda, Cristian D., Matthew J. Tao, Miguel Ceja, Justin Khoury, Guglielmo M. Tino, and Holger Müller. 2024. “Measuring Gravitational Attraction with a Lattice Atom Interferometer.” Nature, June 26, 1–6.

Panda, C., Ma Tao, Miguel Ceja, Andrew Reynoso, and H. Müller. 2023. “Atomic Gravimeter Robust to Environmental Effects.” Applied Physics Letters, ahead of print, May 9. https://doi.org/10.1063/5.0163101.