Breaking the bandwidth-efficiency trade-off in soliton microcombs via mode coupling

TL;DR

This paper introduces a novel mode coupling technique in microresonators that overcomes the traditional bandwidth-efficiency trade-off, enabling octave-spanning soliton microcombs with over 50% conversion efficiency.

Contribution

The authors demonstrate a new approach leveraging mode interactions within a single microresonator to achieve broadband solitons with high efficiency, surpassing previous limitations.

Findings

Achieved octave-spanning soliton microcombs with >50% efficiency.

Enabled broadband soliton formation at reduced pump power.

Resolved the fundamental bandwidth-efficiency trade-off in soliton microcombs.

Abstract

Dissipative Kerr solitons in optical microresonators have emerged as a powerful tool for compact and coherent frequency comb generation. Advances in nanofabrication have allowed precise dispersion engineering, unlocking octave-spanning soliton combs that are essential for applications such as optical atomic clocks, frequency synthesis, precision spectroscopy, and astronomical spectrometer calibration. However, a key challenge hindering their practical deployment is the intrinsic bandwidth-efficiency trade-off: achieving broadband soliton generation requires large pump detuning, which suppresses power coupling and limits pump-to-comb conversion efficiencies to only a few percent. Recent efforts using pulsed pumping or coupled-resonator architectures have improved efficiency to several tens of percent, yet their bandwidths remain below one-tenth of an octave, inadequate for applications demanding wide spectral coverage. Here, we overcome this limitation by harnessing mode interactions between spatial modes within a single microresonator. The mode hybridization creates an additional power-transfer channel that supports large pump detuning while maintaining strong pump-to-resonator coupling, enabling broadband soliton formation at substantially reduced pump power. Using this approach, we demonstrate an octave-spanning soliton microcomb with a record pump-to-comb conversion efficiency exceeding 50%. These results resolve the fundamental bandwidth-efficiency dilemma in soliton microcombs and paves the way toward fully-integrated, high-efficiency, ultrabroad comb sources for next-generation photonic systems.