Quantum metrology by one-minute interrogation of a coherent atomic spatial superposition

In quantum metrology and quantum information processing, a coherent nonclassical state must be manipulated before unwanted interactions with the environment lead to decoherence. In atom interferometry, the nonclassical state is a spatial superposition, where each atom coexists in multiple locations at once as a collection of phase-coherent partial wavepackets. These states enable precise measurements in fundamental physics and inertial sensing. However, atom interferometers usually use atomic fountains, where the available free-fall time sets a hard time limit on the interrogation of the quantum state. Here, we realize atom interferometry with a spatial superposition state held by an optical lattice for as long as 1 minute, which is more than 25 times longer than any atomic fountain interferometer. We additionally present a theoretical and experimental toolbox to explore limits in coherence due to collective dephasing of the atomic ensemble. These gains in coherence may enable gravimetry measurements, searches for fifth forces, or fundamental probes into the non-classical nature of gravity.