Since the inception of microcomb, whose generation relies on Kerr nonlinearity in microresonator, the coherent soliton state has attracted intense researches. Although the operation of sub-comb outputs is straightforward, as noncoherent comb state, it was often overlooked in previous techniques. With graphene sensitization, this sub-comb heterodyne sensing device exhibits an exceptional response to gas molecular adsorption, achieving detect limits of 1.2 ppb for H 2 S gas and 1.4 ppb for SO 2 gas, respectively. In summary, our research synergizes flexible comb formation, direct offset heterodyne detection, and graphene optoelectronics, leading to an easily operated, ultrasensitive miniature gas sensor. This exploration not only offers a simple system configuration but also sets a new standard for convenient optoelectronic detection. Looking ahead, beyond its application in microsphere-based gas sensing, our interdisciplinary approach shows promise for providing platform-independent solutions for a broader range of sensing applications, including on-chip biochemical sensing and photonic-microwave signal generation and control.
Researchers led by Prof. Baicheng Yao at University of Electronic Science and Technology of China (UESTC), are interested in optical fiber sensors and frequency comb, where the fiber sensors own miniature size and frequency comb boasts exceeding exactitude and steadiness. Their idea is to start with leveraging the formation dynamics of sub-comb state, which can be easily accessed and offers steady and detectable beacon for gas sensing. Under the sensitization effect of graphene, the beacon is activated and shows exceptional response for analytes. The work entitled “ Harnessing sub-comb dynamics in a graphene-sensitized microresonator for gas detection ” was published on Frontiers of Optoelectronics (published on May 1, 2024).
Frontiers of Optoelectronics
Experimental study
Not applicable
Harnessing sub-comb dynamics in a graphene-sensitized microresonator for gas detection
1-May-2024