Litcius/Paper detail

A Self-Sustained Mass Sensor With Physical Closed Loop Based on Thermal-Piezoresistive Coupled Resonators

Aojie Quan, Hemin Zhang, Chen Wang, Chenxi Wang, Linlin Wang, Rui Amendoeira Esteves, Yangyang Guan, Chengxin Li, Michaël Kraft

2022IEEE Transactions on Electron Devices16 citationsDOIOpen Access PDF

Abstract

This article reports a mode-localized mass sensor based on thermal-actuation piezoresistive-detection self-oscillated weakly coupled resonators. Detailed theoretical models and simulations of the self-oscillation of the coupled resonators were established and were also verified using optical and electrical measurements. The sensor was fabricated and characterized in terms of stability, linearity, sensitivity, and resolution. Supplied with only a constant direct current (DC), the resonant mass sensor could oscillate at its resonant frequency with an ultrahigh quality factor of 95 k in air. By implementing the principle of the mode localization phenomenon, ~200 times parametric sensitivity improvement with amplitude ratio output was implemented compared to the traditional frequency output metric. A real-time mass detector with 84-fg resolution and larger than ~700-pg linear measurement range was obtained.

Topics & Concepts

ResonatorPiezoresistive effectSensitivity (control systems)LinearityOscillation (cell signaling)Q factorPhysicsMaterials scienceDetectorParametric statisticsOptoelectronicsControl theory (sociology)AcousticsElectronic engineeringOpticsEngineeringComputer scienceStatisticsBiologyQuantum mechanicsControl (management)Artificial intelligenceMathematicsGeneticsMechanical and Optical ResonatorsAdvanced MEMS and NEMS TechnologiesAcoustic Wave Resonator Technologies