Hybrid-Locked Kerr Microcombs for Flexible On-Chip Optical Clock Division

Optical atomic clocks deliver unrivaled precision, yet their size and complexity still confine them to specialized laboratories. Frequency combs provide the crucial optical-to-microwave division needed for clock readout, but conventional fiber- or bulk-laser combs are far too large for portable use. The advent of chip-integrated microcombs, frequency combs generated in micron-scale resonators, has revolutionized this landscape, enabling fully miniaturized, low-power clocks that bridge optical and radio-frequency domains on a single chip. Nevertheless, stabilizing a microcomb solely through pump laser control entangles otherwise independent feedback parameters, injects extra technical noise, and prevents flexible partial division of the optical frequency. Here, we propose and demonstrate a universal on-chip optical-clock architecture that supports both partial and full optical division. A hybrid passive-active scheme enables locking any two microcomb teeth independently, eliminating cross-coupling of control loops. Using the pump laser as a nonlinear actuator to stabilize an arbitrary tooth, we achieve a residual relative frequency instability of 1e-16. This advance brings integrated optical clocks closer to real-world deployment and opens new avenues for precision timing and navigation.