New Avenues in Chip-Scale Atomic Quantum Sensors

The miniaturization of atomic quantum sensors is reshaping how we measure magnetic fields, electromagnetic radiation, and time. By combining micromachined vapor cells, integrated photonics, and advanced laser architectures, it is now possible to bring quantum-level precision to compact, robust, and deployable devices. In this talk, I will highlight a few examples in chip-scale magnetometry, time-keeping, and electrometry studied in our lab. First, I will discuss remote atomic magnetometry, where atomic sensors are interrogated and read out optically from a distant station via free-space links, allowing magnetic-field mapping over tens of meters with sensitivities at the picotesla level in unshielded environments (Kfir Levi et al., Optica Quantum, 2025). Next, I will present work on optical clocks and frequency division using micro-frequency combs, demonstrating hybrid-locked SiN Kerr-microcomb systems that achieve residual fractional instability at the 10⁻¹⁶ level and support compact, chip-integrated optical timekeeping (Andrei Diakonov et al., arXiv:2508.07258). Finally, I will show our results on Rydberg-atom electric-field sensing in wafer-scale Pyrex–Si–Pyrex micromachined vapor cells, where narrow-linewidth Rydberg spectroscopy enables detection of RF fields down to ~10 μV/cm, illustrating subwavelength quantum antennas on a chip (Avital Giat et al., arXiv:2504.09559). Together, these results highlight how hybrid atomic–photonic architectures are redefining the landscape of chip-scale quantum sensing.