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research field[J]. Micronanoelectronic Technology, 2014, [11] Senousy M S, Rajapakse R K N D, Mumford D, et al.
51(7): 438–446. Self-heat generation in piezoelectric stack actuators used
[2] Ding X, Li P, Lin S S, et al. Surface acoustic wave mi- in fuel injectors[J]. Smart Materials and Structures, 2009,
crofluidics[J]. Lab on a Chip, 2013, 13(18): 3626–3649. 18(4): 045008.
[3] 赵程, 周佳成, 袁淑雅, 等. 薄膜型声表面波器件的研究进 [12] Li S, Desrosiers J, Bhethanabotla V R. Heating of
展 [J]. 微电子学, 2021, 51(4): 570–576. Rayleigh surface acoustic wave devices in 128 YX LiNbO 3
◦
Zhao Cheng, Zhou Jiacheng, Yuan Shuya, et al. Research and ST X quartz substrates[C]. 2017 IEEE Sensors, 2017:
progress of thin film SAW devices[J]. Microelectronics, 1–3.
2021, 51(4): 570–576. [13] Qi A, Yeo L, Friend J, et al. The extraction of liquid, pro-
[4] Tan M K, Yeo L Y, Friend J R. Rapid fluid flow and
tein molecules and yeast cells from paper through surface
mixing induced in microchannels using surface acoustic acoustic wave atomization[J]. Lab on a Chip, 2010, 10(4):
waves[J]. Europhysics Letters, 2009, 87(4): 47003–47006. 470–476.
[5] Ai Y, Marrone B L. Droplet translocation by focused
[14] Catarino S O, Miranda J M, Lanceros-Mendez S, et al. A
surface acoustic waves[J]. Microfluidics and Nanofluidics,
numerical study on the heat transfer generated by a piezo-
2012, 13: 715–722.
electric transducer in a microfluidic system[J]. Journal of
[6] Jangi M, Luo J T, Tao R, et al. Concentrated ver-
Physics Conference, 2012, 395: 012091.
tical jetting mechanism for isotropically focused Zno/Si
[15] Rajesh J T, Vins B, Ramamoorthy V. Heat generation
surface acoustic waves[J]. International Journal of Multi-
from dielectric loss and vibration using COMSOL Mul-
phase Flow, 2019, 114: 1–8.
tiphysics[C]//Proc. of COMSOL Bangalore Conference,
[7] Huang Q Y, Le Y, Hu H, et al. Experimental research on
2010: 1–4.
surface acoustic wave microfluidic atomization for drug
[16] Tan M K, Friend J R, Matar O K, et al. Capillary
delivery[J]. Scientific Reports, 2022, 12(1): 7930.
wave motion excited by high frequency surface acoustic
[8] Huang Q, Sun Q, Hu H, et al. Thermal effect in the pro-
waves[J]. Physics of Fluids, 2010, 22(11): 112112.
cess of surface acoustic wave atomization[J]. Experimental
Thermal and Fluid Science, 2021, 120: 110257. [17] Johnson S, Shanmuganantham T. Design and analysis of
[9] Huang Q, Hu H, Lei Y, et al. Simulation and experimen- SAW based MEMS gas sensor for the detection of volatile
tal investigation of surface acoustic wave streaming veloc- organic gases[J]. International Journal of Engineering Re-
ity[J]. Japanese Journal of Applied Physics, 2020, 59(6): search & Applications, 2014, 3(4): 254–258.
064001. [18] 杨小庆. 声表面波微流体驱动中的热效应研究 [D]. 哈尔滨:
[10] Collins D J, Manor O, Winkler A, et al. Atomization 哈尔滨工业大学, 2021.
off thin water films generated by high-frequency sub- [19] Lee D, Lee N, Choi G, et al. Heat transfer characteris-
strate wave vibrations[J]. Physical Review E, 2012, 86(5): tics of a focused surface acoustic wave (F-SAW) device for
056312. interfacial droplet jetting[J]. Inventions, 2018, 3(2): 38.
