An atomic frequency comb memory in rare-earth doped thin-film lithium niobate

Atomic frequency combs coherently store optical signals, a key building block for optical quantum computers and quantum networks. Integrating an atomic frequency comb memory into a compact and chip-integrated device is essential to achieve scalable quantum technology. But the majority of such memories have been realized using bulk systems or waveguides with large cross-sections that are difficult to integrate into compact chips, or using fabrication techniques that are not easily adaptable to wafer scale processing. Here we demonstrate a compact chip-integrated atomic frequency comb in thin-film lithium niobate. We utilize rare-earth doped thin-film lithium niobate to demonstrate both coherent control of the atomic ensemble and optical storage using an atomic frequency comb. Our optical memory exhibits a broad storage spectrum exceeding 100 MHz, and optical storage time of over 250 ns. The enhanced optical confinement in our device structure enables coherent rotations on the ions with three orders of magnitude less optical power as compared to previous results in large waveguides. These compact atomic frequency comb memories pave the way towards scalable, highly efficient, electro-optically tunable quantum photonic systems where one can store and manipulate light on chip with high bandwidth and low powers.