부산대학교 도서관

High-sensitivity flow measurement technology is a prerequisite for precise dynamic control of microfluidics. Despite the advances in structure optimization, a more efficient approach to improve device sensitivity can be realized by leveraging materials with a higher temperature coefficient of resistance (TCR). This work presents the design and simulation of a vanadium dioxide (VO2)-based microfluidic thermal flow sensor with record high sensitivity. Owing to the phase change property, VO2 demonstrates the maximum TCR of −0.703 and $-0.63\,\,\text{K}^{-{1}}$ in the major heating and cooling curves, respectively, which is more than two orders of magnitude higher than commonly used thermal-sensitive materials. To fully utilize the high thermal sensitivity of VO2, a dual-heater configuration with enhanced thermal differential effect is proposed, and its sensing performance is evaluated in the flow range below $10 \mu \text{L} \cdot $ min $^{-{1}}$ . By individually operating the VO2 thermal sensors at critical transition temperatures in the major hysteresis loop, the sensitivity can reach as high as 2.79 V/ $\mu \text{L} \cdot $ min $^{-{1}}$ , which is about 187.88 times and 277.89 times higher than the VO2-based anemometer and the Pt-based dual-heater calorimetric (DHC) sensor, respectively. The research in the present work may enable a breakthrough in the improvement of high-performance microfluidic thermal flow sensors in the ultralow flow region using nonstandard metamaterials.