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Portable Laser-Pumped Rb Atomic Clock with Digital Circuits

Atomic Physics 2025-08-20 v2 Quantum Physics

Abstract

Reducing the size and complexity of high-performance timekeeping devices is an ever-growing need for various applications, such as 6G wireless technology, positioning, navigation and timing (PNT), Internet of Things (IoT), and ultrafast spectroscopy. This work presents a distributed feedback (DFB) laser-pumped Rb atomic clock, which features extraordinary frequency stability, small size and low power consumption. The DFB laser head employs a built-in isolator with a linewidth of approximately 1 MHz. For complete optical pumping of the atoms in the absorption cell, the laser beam is expanded to a diameter of 10 mm by using an optical diffuser-based beam expander. The physics package is based on a magnetron microwave cavity and surrounded by two layers of magnetic shielding. The overall volume of the optical system combined with the physics package is 250 cm3^3. The proposed atomic clock is also designed to operate at a low temperature, whose absorption cell is maintained at 323 K. Benefiting from the lower Rb atom density, the excited atoms present a long population relaxation time of 5.8 ms. The frequency synthesizer and frequency-locked loop are implemented by digital circuits. The short-term stability of the atomic clock is measured to be 1.8×1012τ1/21.8\times10^{-12}\tau ^{-1/2} (1-100s). Our achievement paves the way for practical application of the laser-pumped Rb atomic clocks.

Keywords

Cite

@article{arxiv.2508.12437,
  title  = {Portable Laser-Pumped Rb Atomic Clock with Digital Circuits},
  author = {Qiang Hao and Shaojie Yang and Peter Yun and Jun Ruan and Shougang Zhang},
  journal= {arXiv preprint arXiv:2508.12437},
  year   = {2025}
}
R2 v1 2026-07-01T04:53:51.726Z