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  1. Y. Luo, B. Yu, H. Yu, and K. Li, “GaN integrated optical devices for glycerol viscosity measurement,” Opt. Lett. 49, 2261-2264 (2024).<\/li>\n
  2. R. Jiao et al., “A Super Stretchable, Strain-Insensitive Vertical Serpentine Conductor Based On MEMS Technology,” 2024 IEEE 37th International Conference on Micro Electro Mechanical Systems (MEMS)<\/em>, Austin, TX, USA, 2024, pp. 650-653, doi: 10.1109\/MEMS58180.2024.10439313.<\/li>\n
  3. Zhaoyu Li, et al.,”Efficient five-axis scanning-inspection path planning for complex freeform surfaces, “Robotics and Computer-Integrated Manufacturing, doi: 10.1016\/j.rcim.2023.102687<\/li>\n
  4. Deng, Y., Xu, K., Jiao, R. et al. Rotating square tessellations enabled stretchable and adaptive curved display. npj Flex Electron<\/em> 8, 4 (2024). https:\/\/doi.org\/10.1038\/s41528-023-00291-y<\/li>\n
  5. Hou Y, Li Z, Wang Z, et al. Programmable and Surface\u2010Conformable Origami Design for Thermoelectric Devices[J]. Advanced Science<\/em>, 2024: 2309052.<\/li>\n
  6. Jiao, R., Wang, R., Wang, Y., Cheung, Y. K., Chen, X., Wang, X., Deng, Y., & Yu, H.<\/i>\u00a0Vertical serpentine interconnect-enabled stretchable and curved electronics.\u00a0Microsyst Nanoeng<\/i>\u00a09<\/b>, 149 (2023). https:\/\/doi.org\/10.1038\/s41378-023-00625-w<\/li>\n
  7. Wang, X., Chen, X., Deng, Y., Cheung, Y. K., Jiang, P., Xu, W., & Yu, H. (2022, January). A Flexible Thermal Flow Sensor with Quadruple Heaters and Suspended Structure for Performance Enhancement. In\u00a02022 IEEE 35th International Conference on Micro Electro Mechanical Systems Conference (MEMS)<\/i>\u00a0(pp. 652-655). IEEE.<\/li>\n
  8. Deng, Y., Liu, W., Cheung, Y. K., Li, Y., Hong, W., & Yu, H. (2021). Curved display based on programming origami tessellations.\u00a0Microsystems & Nanoengineering<\/i>,\u00a07<\/i>(1), 1-10.<\/li>\n
  9. Wang, X., Deng, Y., Chen, X. Jiang, P., Cheung, Y.K. Yu, H.<\/i>\u00a0An ultrafast-response and flexible humidity sensor for human respiration monitoring and noncontact safety warning.\u00a0Microsyst Nanoeng<\/i>\u00a07,\u00a0<\/b>99 (2021). https:\/\/doi.org\/10.1038\/s41378-021-00324-4<\/li>\n
  10. Hou, Y., Yang, Y., Wang, Z., Li, Z., Zhang, X., Bethers, B., … & Yu, H. (2021). Whole Fabric\u2010Assisted Thermoelectric Devices for Wearable Electronics.\u00a0Advanced Science<\/i>, 2103574.<\/li>\n
  11. Wang, X., Deng, Y., Chen, X., Ma, Z., Wang, Y., Xu, W., & Yu, H. (2021). A Vertically Aligned Multiwall Carbon Nanotube-Based Humidity Sensor With Fast Response, Low Hysteresis, and High Repeatability.\u00a0IEEE Sensors Letters<\/i>,\u00a05<\/i>(11), 1-4.<\/li>\n
  12. Yu, Siqi, and Hongyu Yu. “Capacitive Stretchable Strain Sensor with Low Hysteresis Based on Wavy-Shape Interdigitated Metal Electrodes.”\u00a0IEEE Sensors Journal<\/i>\u00a0(2021).<\/li>\n
  13. Zhang, Y., Chen, X., Wang, M. Y., & Yu, H. (2021). Multidimensional Tactile Sensor with a Thin Compound Eye-Inspired Imaging System.\u00a0Soft Robotics<\/i>.<\/li>\n
  14. Y. Wang, J. Guo, Y. Fang, X. Zhang, and H. Yu*, \u201cUltra-light Metamaterial for Sound Absorption Based on Miura-ori Tessellation Structure,\u201d Advanced Engineering Materials, First online: Aug. 2021, DOI: 10.1002\/adem.202100563.<\/li>\n
  15. Y. K. Cheung and H. Yu*, \u201cElectrochemical Based Tilt Sensors with Symmetric Concentric Electrode Pairs,\u201d IEEE Sensors Journal, Date of publication: Aug, 2021, DOI: 10.1109\/JSEN.2021.3102408.<\/li>\n
  16. Hou, Y., Li, Z., Wang, Z., & Yu, H*. “Miura-ori structured flexible microneedle array electrode for biosignal recording.” Microsystems & Nanoengineering 7.1 (2021): 1-8.<\/li>\n
  17. Zeng, Z., Yu, H., Du, S., and Chen, X., \u201cIn situ characterization of buckling dynamics in silicon microribbon on an elastomer substrate,\u201d\u00a0Extreme Mechanics Letters, 2021.<\/li>\n
  18. Li, Y., and Yu, H., \u201cA Planar Developable Double Corrugation Surface Enabled Stretchable Heart Rate Sensing System,\u201d\u00a0IEEE Sensors Journal, 2021.<\/li>\n
  19. Yu, S.,, and Yu, H. “Capacitive Stretchable Strain Sensors Based on Wavy-Structured Metal Electrodes.” 2021 IEEE 16th International Conference on Nano\/Micro Engineered and Molecular Systems (NEMS). IEEE, 2021.<\/li>\n
  20. Li, Y., Liu, W., Deng, Y., Hong, W., and Yu, H., \u201cMiura-ori enabled stretchable circuit boards,\u201d npj Flexible Electronics, 2021.<\/li>\n
  21. Wang, Z., Bi, P., Yang, Y., Ma, H., Lan, Y., Sun, X., … and Xiong, R., \u201cStar-nose-inspired multi-mode sensor for anisotropic motion monitoring,\u201d\u00a0Nano Energy,\u00a02021.<\/li>\n
  22. Hou, Y., Jiao, R., and Yu, H., \u201cMEMS based Geophones and Seismometers,\u201d\u00a0Sensors and Actuators A: Physical, 2020.<\/li>\n
  23. Zeng, Z., Chiu, H. C., Zhao, L., Zhao, T., Zhang, C., Karami, M., … and Chen, X., \u201cDual beam-shear differential interference microscopy for full-field surface deformation gradient characterization,\u201d\u00a0Journal of the Mechanics and Physics of Solids, 2020.<\/li>\n
  24. Hou, Y., Wang, Y., Yu, M., Wang, Z., and Yu, H., \u201cMiura\u2010ori Metastructure Enhanced Conductive Elastomers,\u201d\u00a0Advanced Materials Technologies, 2020.<\/li>\n
  25. Liang, M., Nickerson, S., Dai, L., and Yu, H, \u201cMolecular Electronic Transducer Based Tilting Sensors,\u201d In\u00a02020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS), pp. 765-768, 2020.<\/li>\n
  26. Huang, S., Wang, Z., Xiong, R., Yu, H., and Shi, J, \u201cSignificant enhancement in thermoelectric performance of Mg3Sb2 from bulk to two-dimensional mono layer,\u201d\u00a0Nano Energy,\u00a02019.<\/li>\n
  27. Xu, Y., Lin, W. J., Gliege, M., Gunckel, R., Zhao, Z., Yu, H., and Dai, L. L, \u201cA Dual Ionic Liquid-Based Low-Temperature Electrolyte System,\u201d\u00a0The Journal of Physical Chemistry B, 2018.<\/li>\n
  28. Hou, Y. Shang, M. Yu, C. Feng, H. Yu and S. Yao, \u201cTunable Water Harvesting Surfaces Consisting of Biphilic Nanoscale Topography\u201d ACS nano, 2018.<\/li>\n
  29. Xu, O. Ghag, M. Reimann, P. Sitterle, P. Chatterjee, E. Nofen, H. Jiang, H. Yu and L. Dai, \u201cDevelopment of visible-light responsive and mechanically enhanced \u201csmart\u201d UCST interpenetrating network hydrogels\u201d soft matter, 2018.<\/li>\n
  30. Liang, H. Huang and H. Yu, \u201cMolecular Electronic Transducer Based Planetary Seismometer with New Fabrication Process,\u201d Micro Electroc Mechnaical System (MEMS), 2016 IEEE 20th International Conference on, Shanghai, pp 986-989, 2016<\/li>\n
  31. Liang, H. Yu, M. Ngan, S. Nickerson, E. Nofen, and L. Dai, \u201cMEMS Accelerometer Based on Molecular Electronic Transducers Using Ionic Liquid,\u201d IEEE Nano 2015, Rome, Italy, pp 1167-1170, 2015<\/li>\n
  32. Song, X. Wang, C. Lv, Y. An, M. Liang, T. Ma, D. He, Y. J. Zheng, S.Q. Huang, H. Yu, and H. Jiang, \u201cKirigami-Based Stretchable Lithium-Ion Batteries,\u201d\u00a0Scientific Reports, Volume: 5, Article number: 10988, 2015<\/li>\n
  33. Chatterjee, A. Dai, H. Yu, H. Jiang, and L. L. Dai, \u201cThermal and Mechanical Properties of Poly(N-Isopropylacrylamide) based Hydrogels as a Function of Porosity and Medium Change,\u201d\u00a0Journal of Applied Polymer Science, Volume: 132, Issue: 45, 2015<\/li>\n
  34. Nickerson,\u00a0E. Nofen,\u00a0H. Chen,\u00a0M. Ngan,\u00a0B. Shindel, H. Yu, and\u00a0L. Dai, \u201cA Combined Experimental and Molecular Dynamics Study of Iodide-Based Ionic Liquid and Water Mixtures,\u201d J. Phys. Chem. B,\u00a0Volume: 119, Issue:28, pp 8764\u20138772, 2015<\/li>\n
  35. Gao, R Tang, T Ma, H Jiang, H Yu, GJ Cheng, \u201cLaser Shock Induced Conformal Transferring of Functional Devices on 3D Stretchable Substrates,\u201d IEEE\/ASME Journal of Microelectromechanical Systems, Volume: 24, Issue: 2, pp 414-421, 2015<\/li>\n
  36. Durgun, C. Balanis, C. Birtcher, H. Huang and H. Yu, “High-Impedance Surfaces With Periodically Perforated Ground Planes,” Antennas and Propagation, IEEE Transactions on, Volume: 62, Issue: 9, pp 4510-4517, 2014<\/li>\n
  37. Lv, D. Krishnaraju, G. Konjevod, H. Yu, and H. Jiang, 2014, \u201cOrigami based Mechanical Metamaterials,\u201d Scientific Reports, Volume: 4, Article number; 5979, 2014<\/li>\n
  38. Song, T. Ma, R. Tang, Q. Cheng, X. Wang, D. Krishnaraju, R. Panat, C. K. Chan, H. Yu, and H.Jiang, \u201cOrigami Lithium-ion Batteries,\u201d Nature Communications, Volume: 5 \u00a0Article Number: 3140, 2014<\/li>\n
  39. Tang, H. Tu, Y. Xu, H. Jiang and H. Yu, \u201cMicro Origami Solar Panel,\u201d Applied Physics Letters, Volume: 104 \u00a0\u00a0Issue: 8\u00a0\u00a0\u00a0Article Number: 083501, 2014<\/li>\n
  40. Oiler, R. Tang, T. Ma, and H. Yu, “Thermoelectric Cool-Film Shear Stress Sensor,” Electron Device Letters, IEEE, Volume: 35, Issue: 7, pp 783-785, 2014<\/li>\n
  41. Oiler, E. Shock, H. Hartnett, AJ. Dombard, and H. Yu, “Harsh Environment Sensor Array-Enabled Hot Spring Mapping,” Sensors Journal, IEEE, Volume: 14, Issue: 10, pp 3418-3425, 2014<\/li>\n
  42. Tu, H. Jiang, H. Yu and Y. Xu, \u201cHybrid silicon-polymer platform for self-locking and self-deploying origami\u201d Applied Physics Letters, Volume: 103 \u00a0\u00a0Issue: 24 \u00a0\u00a0\u00a0\u00a0Article Number: 241902 2013<\/li>\n
  43. Oiler, E. Shock, H. Harnett and H. Yu, \u201cMEMS Harsh Environment Sensor Array-Enabled Hot Spring Physical Parameter Mapping,\u201d IEEE Sensors 2013, Taiwan, pp 1-4, 2013<\/li>\n
  44. Tang, H. Huang, Y. Yang, J. Oiler, M. Liang and H. Yu, \u201cThree Dimensional Catheter-based Thermal Sensor for Intravascular Flow Monitoring,\u201d Transducers 2013, Barcelona, Spain, pp 1-4, 2013<\/li>\n
  45. Huang, M. Liang, R. Tang, J. Oiler, T. Ma, and H. Yu, \u201cAn Electrolyte Droplet-based Low Frequency Accelerometer Based on Molecular Electronic Transducer,\u201d Transducers 2013, Barcelona, Spain, pp 1-4, 2013<\/li>\n
  46. Huang, B. Carande, R. Tang, J. Oiler, Z. Dmitriy, V. Agafonov, and H. Yu, \u201cDevelopment of a Micro Seismomter Based on Molecular Electronic Transducer Technology of Planetary Exploration,\u201d Micro Electroc Mechnaical System (MEMS), 2013 IEEE 20th International Conference on, Taiwan, pp 629-632, 2013<\/li>\n
  47. Cheng, Z. Song, T. Ma, B. Smith, R. Tang, H. Yu, H. Jiang and C. Chan, \u201c3D Paper-based Lithium-ion Batteries using Folding,\u201d Nano Letters, Volume: 13, Issue: 10, pp 4969-4974, 2013<\/li>\n
  48. Ma, Y. Wang. R. Tang, H. Yu, and H. Jiang “Pre-patterned ZnO Nanoribbons on Soft Substrates for Stretchable Energy Harvesting Applications” Journal of Applied Physics, Volume:\u00a0113\u00a0\u00a0\u00a0Issue:\u00a020\u00a0\u00a0\u00a0Article Number:\u00a0204503, 2013<\/li>\n
  49. Tang, H. Huang, J. Oiler, M. Liang and H. Yu, \u201cThree Dimensional Flexible Thermal Sensor for Intravascular Flow Monitoring,\u201d IEEE sensors journal, Volume: 13, Issue: 10, pp 3991-3998, 2013<\/li>\n
  50. Gao, R. Tang, T. Ma, H. Jiang, H. Yu, and G. Cheng, \u201cDirect Integration of Functional Structures on 3D Microscale Surfaces by Laser Dynamic Forming,\u201d Journal of Microelectromechanical Systems, Volume: 22, Issue: 6, pp 1428-1437, 2013<\/li>\n
  51. Kim, H. Tu, C. Lv, H. Jiang, H. Yu, and Y. Xu, \u201cA Robust Polymer Microcable Structure for Flexible Devices,\u201d Applied Physics Letters, Volume: 102, Issue: 3, Article Number: 033506, 2013<\/li>\n
  52. Wang, T. Ma, H. Yu, and H. Jiang, \u201cRandom Analysis on Controlled Buckling Structure for Energy Harvesting,\u201d Applied Physics Letters, Volume: 102, Issue: 4, Article Number: 041915, 2013<\/li>\n
  53. Huang, M. Liang, R. Tang, J. Oiler, T. Ma and H. Yu \u201cMolecular Electronic Transducer-Based Low Frequency Accelerometer Fabricated With Post-CMOS Compatible Process Using Droplet as Sensing Body,\u201d IEEE Electron Device Letters, Volume: 34 ,\u00a0\u00a0Issue: 10, pp 1304 \u2013 1306, 2013<\/li>\n
  54. Huang, B. Carande, R. Tang, J. Oiler, D. Zuitsev, V. Agafonov and H. Yu, \u201cA Micro Seismometer based on Molecular Electronic Transducer Technology for Planetary Exploration,\u201d Applied Physics Letters, Volume:\u00a0102\u00a0\u00a0\u00a0Issue:\u00a019\u00a0\u00a0\u00a0Article Number:\u00a0 193512, 2013<\/li>\n
  55. Huang, V. Agafonov and H. Yu, \u201cMolecular Electric Transducers as Motion Sensors: A Review,\u201d Sensors, Volume: 13, Issue: 4, pp 4581-4597, 2013<\/li>\n
  56. Wang, X. Qiu, J. Shi and H. Yu, \u201cRoom Temperature Ozone Detection using ZnO based Film Bulk Acoustic Resonator (FBAR),\u201d Journal of the Electrochemical Society, Volume: 159 \u00a0\u00a0Issue: 1 pp J13-J16,\u00a02012<\/li>\n
  57. Oiler, H. Yu, R. Tang, T. Ma and H. Huang, \u201cThermoelectric Cool-Film Flow Sensor,\u201d IEEE sensors 2012, Taipei, Taiwan, pp 1-5, 2012<\/li>\n
  58. Qiu, R. Tang, R. Liu, H. Huang S. Guo and H. Yu, \u201cA Micro Initiator Realized by Reactive Ni\/Al Nanolaminates,\u201d Journal of Material Science- Material in Electronics, Volume: 23 \u00a0\u00a0Issue: 12\u00a0pp 2140-2144, 2012<\/li>\n
  59. Pang, H. Zhao, E. S. Kim, H. Zhang, H. Yu and X. Hu, \u201cPiezoelectric MicroelectromEchanical Resonant Sensors for Chemical and Biological Detection,\u201d Lab on a Chip, Volume: 12, Issue: 1, pp 29-44, 2012<\/li>\n
  60. Zhang, Q. Yang, W. Pang, J. Ma, and H. Yu, \u201cTemperature Stable Bulk Acoustic Wave Filters Enabling Integration of a Mobile Television Function in UMTS System,\u201d IEEE Microwave and Wireless Components letters, Volume: 22, \u00a0\u00a0Issue: 5, pp 239-241, 2012<\/li>\n
  61. Zhou, W. Pang, Q. Li, H. Yu, X. Hu, and H. Zhang, \u201cExtracting the Electromechanical Coupling Constant of Piezoelectric Thin Film by the High-Tone Bulk Acoustic Resonator Technique,\u201d IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control,\u00a0Volume: 59, Issue: 5, pp 958-962, 2012<\/li>\n
  62. Zhu, C. Lee, E.S. Kim, D. Wu, C. Hu, Q. Zhou, K.K. Shung, and H. Yu, \u201cHigh-overtone Self-Focusing Acoustic Transducers for High Frequency Ultrasonic Doppler,\u201d Ultrasonics, Volume: 50, Issue: 6, pp 544-547, 2011<\/li>\n
  63. Qiu, R. Tang, J. Zhu, J. Oiler, C. Yu, Z. Wang, and H. Yu, \u201cThe Effects of Temperature, Relative Humidity and Reducing Gases on the Ultraviolet Response of ZnO based Film Bulk Acoustic-Wave Resonator,\u201d Sensors and Actuators: B. Chemical, Volume: 151, Issue 2, pp 360\u2013364, 2011<\/li>\n
  64. Wang, X. Qiu, S. Chen, W. Pang, H. Zhang, J. Shi, and H. Yu, \u201cZnO based Film Bulk Acoustic Resonator as Infrared Sensor,\u201d Thin Solid Films, Volume: 519,\u00a0Issue: 18, pp 6144-6147, 2011<\/li>\n
  65. Wang, X. Qiu, J. Zhu, J. Oiler, S.Chen, J.Shi, E. S. Kim, and H. Yu, \u201cDirectional Acoustic Underwater Thruster,\u201d IEEE Trans. Ultrasonics. Ferroelectrics Frequency Control, Volume: 58,\u00a0Issue: 6 \u00a0\u00a0Pages: 1114-1117, 2011<\/li>\n
  66. Yu, L. Ai, W. Dai, N. Rozengurt, H. Yu, T. K. Hsiai, \u201cMEMS Thermal Sensors to Detect Changes in Heat Transfer in the Pre-Atherosclerotic Regions of Fat-Fed New Zealand White Rabbits,\u201d Annals of Biomedical Engineering,\u00a0Volume: 39 \u00a0\u00a0Issue: 6 \u00a0\u00a0pp 1736-1744, 2011<\/li>\n
  67. Yu, R. Li, L. Ai, C. Edington, H. Yu, M. Barr, E.S. Kim, T. K. Hsiai, \u201cElectrochemical Impedance Spectroscopy to Assess Vascular Oxidative Stress,\u201d Annals of Biomedical Engineering, Volume: 39, Issue: 1 \u00a0\u00a0pp 287-296, 2011<\/li>\n
  68. Qiu, R. Tang, R. Liu, S. Guo, and H. Yu, \u201cA Micro Initiator Realized by Reactive Ni\/Al Nanolaminates for MEMS Applications,\u201d Transducers 2011, Beijing, China, pp 1665-1668, 2011<\/li>\n
  69. Tang, X. Qiu, J. Zhu, J. Oiler, H. Huang, H. Wang, and H. Yu, \u201cpH Measurements with ZnO Based Surface Acoustic Wave Resonator,\u201d Transducers 2011, Beijing, China, pp 1132-1135, 2011<\/li>\n
  70. Wang, X. Qiu, R. Tang, J. Oiler, J. Zhu, H. Huang, H. Wang, J. Shi, and H. Yu, \u201cOzone Sensor Using ZnO Based Film Bulk Acoustic Resonator,\u201d Transducers 2011, Beijing, China, pp 1124-1127, 2011<\/li>\n
  71. Oiler, X. Qiu, J. Zhu, R. Tang, S. Chen, H. Huang, K. Holbert, H. Barnaby, and H. Yu, \u201cThe Sensitivity Enhancement for the Radiation Sensor Based on Film Bulk Acoustic-wave Resonator,\u201d Transducers 2011, Beijing, China, pp 2058- 2061, 2011<\/li>\n
  72. Zhu, S. Chen, C. Lin, J. Oiler, H. Wang, Y. Chen, and H. Yu, \u201cThe Fabrication of 3D Aspherical Silicon Microlenses Using a Shadow Mask,\u201d Transducers 2011, Beijing, China, pp 2370-2373, 2011<\/li>\n
  73. Wang, J. Zhu, X. Qiu, R. Tang, C. Yu, J. Oiler, E. S. Kim, and H. Yu, \u201cDirectional Acoustic Underwater Thruster,\u201d IEEE MEMS 2011, Cancun, Mexico, pp 1225-1228, 2011<\/li>\n
  74. Pang, H. Zhang, R.C. Ruby, H. Yu, E.S. Kim, \u201cAnalytical and Experimental Study on the Second Harmonic Mode Response of a Bulk Acoustic Wave Resonator,\u201d Journal of Micromechanics and Microengineering, Volume: 20, Issue: 11, Article number: 115015, 2010<\/li>\n
  75. Zhang, W. Pang, E.S. Kim and H. Yu, \u201cMicromachined Silicon and Polymer Probes Integrated with Film-Bulk-Acoustic-Resonator Mass Sensors,\u201d Journal of Micromechanics and Microengineering, Volume: 20, Issue: 12, Article number: 125008, 2010<\/li>\n
  76. Qiu, D. Welch, J. Christen, J. Zhu, J. Oiler, C. Yu, Z. Wang, and H. Yu, \u201cReactive Nanolayers for Physiologically Compatible Microsystem Packaging,\u201d Journal of Material Science-Material in Electronics, Volume: 21, Issue 6, pp 562-566, 2010<\/li>\n
  77. Qiu, J. Oiler, J. Zhu, Z. Wang, R. Tang, C. Yu and H. Yu, \u201cFilm Bulk Acoustic-Wave Resonator based Relative Humidity Sensor using ZnO Films,\u201d Electrochemical and Solid-State Letters, Volume: 13, Issue: 5, pp J65-J67, 2010<\/li>\n
  78. Qiu, Z. Wang, J. Zhu, J. Oiler, R. Tang, C. Yu and H. Yu, \u201cThe Effects of Relative Humidity and Reducing Gases on the Temperature coefficient of Resonant Frequency of ZnO-Based Film Bulk Acoustic Wave Resonator,\u201d IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control, Volume: 57, Issue 9, pp 1902-1905, 2010<\/li>\n
  79. Qiu, R. Tang, J. Zhu, J. Oiler, C. Yu, Z. Wang, and H. Yu, \u201cExperiment and theoretical analysis of relative humidity sensor based on film bulk acoustic-wave resonator,\u201d Sensors and Actuators B-Chemical, Volume: 147, Issue 2, pp 381-384, 2010<\/li>\n
  80. Qiu, R. Tang, J. Zhu, J. Oiler, Z. Wang and H. Yu \u201cAcetone Sensor Based on Film Bulk Acoustic Resonator,\u201d IEEE SENSORS 2010, Waikoloa, HI, pp 1546-1549, 2010<\/li>\n
  81. Qiu, R. Tang, J. Zhu, J. Oiler, Z. Wang and H. Yu \u201cLateral Field Excitation Film Bulk Acoustic Resonator As Infrared Sensor,\u201d IEEE SENSORS 2010, Waikoloa, HI, pp 623-626, 2010<\/li>\n
  82. Yu, Z. Wang, J. Zhu, X. Qiu, J. Oiler, H. Yu and H. Jiang, \u201cA Mechanically Stretchable Temperature Sensor based on Buckled Thin Film Devices on an Elastomeric Substrate,\u201d IEEE 23rd International Conference on MicroElectroMechanical Systems (MEMS), HongKong, pp 675-678, 2010<\/li>\n
  83. Qiu, J. Zhu, J. Oiler, C. Yu, Z. Wang, H. Yu, \u201cFilm Bulk Acoustic-wave Resonator (FBAR) Based Humidity Sensor,\u201d IEEE NEMS 2010, Xiamen, China, pp 445- 449, 2010<\/li>\n
  84. Zhu, Z. Wang, X. Qiu, J. Oiler, C. Yu, G. Wang and H. Yu, \u201cA novel technique to cover microfluidic systems with Parylene-C,\u201d IEEE NEMS 2010, Xiamen, China, pp 840 -843, 2010<\/li>\n
  85. Oiler, X. Qiu, J. Zhu, Z. Wang, C. Yu, H. Barnaby, K. Holbert and H. Yu, \u201c Film Bulk Acoustic-Wave Resonator based Radiation Sensor\u201d IEEE NEMS 2010, Xiamen, China, pp 967-970, 2010<\/li>\n
  86. Qiu, J. Zhu, J. Oiler, C. Yu, Z. Wang and H. Yu, \u201cLocalized Parylene-C bonding with reactive multilayer foils,\u201d Journal of Physics D: Applied Physics, Volume: 42 Issue: 18 Article Number: 185411, 2009<\/li>\n
  87. Xu, X. Zhang, H. Yu, A. Abbaspour-Tamijani and J. Chae, \u201cIn-Liquid Quality Factor Improvement for Film Bulk Acoustic Resonators by Integration of Microfluidic Channels,\u201d IEEE electron device letters, Volume: 30, Issue: 6, pp 647-652, 2009<\/li>\n
  88. Yu, C. Y. Lee, W. Pang, H. Zhang, A. Brannon, J. Kitching, and E. S. Kim, \u201cHBAR-Based 3.6 GHz Oscillator with Low Power Consumption and Low Phase Noise,\u201d IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control, Volume: 56, Issue: 2, pp 400-403, 2009<\/li>\n
  89. Qiu, J. Zhu, J. Oiler, C. Yu, Z. Wang, and H. Yu, \u201cFilm Bulk Acoustic-wave Resonator Based Ultraviolet Sensor,\u201d Applied Physics Letter, Volume: 94, Issue: 15, Article Number: 151917, 2009<\/li>\n
  90. Qiu, J. Zhu, J. Oiler, H. Yu, \u201cReactive Multilayer Foils for MEMS Wafer Level Packaging,\u201d 59th Electronic Components and Technology Conference, San Diego, CA, pp 1311-1316, 2009<\/li>\n
  91. Qiu, J. Zhu, Z. Wang, J. Oiler, H. Yu, \u201cThe Effects of Ultraviolet Radiation, Humidity and Reducing Gases on the Temperature Coefficient of Resonant Frequency of ZnO Based Film Bulk Acoustic-wave Resonator,\u201d IEEE Ultrasonics Symposium, Roma, Italy, pp 2158- 2161, 2009<\/li>\n
  92. Zhu, X. Qiu, J. Oiler, C. Yu, T.K. Hsiai, E.S. Kim, and H. Yu, “Localized Cell Lysis Using Self Focused Acoustic Transducers,\u201d Transducers ’09, IEEE International Conference on Solid-State Sensors and Actuators, Denver, USA, pp 608-611, 2009<\/li>\n
  93. Qiu, J. Zhu, J. Oiler, C. Yu, Z. Wang and H. Yu, \u201cFilm Bulk Acoustic-wave Resonator (FBAR) based Ultraviolet Sensor,\u201d Transducers ’09, IEEE International Conference on Solid-State Sensors and Actuators, Denver, USA, pp 2354-2357, 2009<\/li>\n
  94. Yu, Z. Wang, H. Yu, and H. Jiang, \u201cA Stretchable Temperature Sensor Based on Elastically Buckled Thin Film Devices on Elastomeric Substrates,\u201d Applied Physics Letter, Volume: 95, Issue: 14, Article Number: 141912, 2009<\/li>\n
  95. Ai, H. Yu, A. Paraboschi, F. Yu, E. S. Kim, R. Li and T. K. Hsiai, \u201cOptimization of Intravascular Shear Stress Assessment in Vivo,\u201d Journal of Biomechanics, Volume: 42 Issue: 10, pp 1429-1437, 2009<\/li>\n
  96. Ai, H. Yu, W. Dai, S. L. Hale, R. A. Kloner and T. K. Hsiai, \u201cReal-Time Intravascular Shear Stress in the Rabbit Abdominal Aorta,\u201d IEEE transactions on biomedical engineering, Volume: 56 Issue: 6 pp1755-1764, 2009<\/li>\n
  97. Yu, H. Gao, H. Yu, H. Jiang, and G. J. Cheng, \u201cLaser Dynamic Forming of Functional Materials Laminated Composites on Patterned Three-dimensional Surfaces with Applications on Flexible Microelectromechanical System,\u201d Applied Physics Letter, Volume: 95, Issue: 9, Article number: 091108, 2009<\/li>\n
  98. Y. Lee, W. Pang, S. C. Hill, H. Yu and E. S. Kim, \u201cAirborne Particle Generation Through Acoustic Ejection of Particles-in-droplets,\u201d Aerosol Science and Technology, Volume: 42, Issue: 10, pp 832-841, 2008<\/li>\n
  99. Y. Lee, H. Yu, W. Pang, and E. S. Kim, \u201cDroplet-based microreactions with oil encapsulation,\u201d Journal of Microelectromechanical systems, Volume: 17, Issue: 1, pp 147-156, 2008<\/li>\n
  100. Ai, M. Rouhanizadeh, J. C. Wu, W. Takabe, H. Yu, M. Alavi, R. Li, Y. Chu, and J. Miller, D. D. Heistad and T. K. Hsiai, \u201cShear stress influences spatial variations in vascular Mn-SOD expression: implication for LDL nitration,\u201d The American Journal of Physiology \u2013 Cell Physiology, Volume: 294, Issue: 6, pp C1576-C1585, 2008<\/li>\n
  101. Yu, L. Ai, M. Rouhanizadeh, R. A. Kloner, E. S. Kim and T. K. Hsiai, \u201cShear Stress Sensor for in vivo Cardiovascular Testing,\u201d Solid-State Sensor and Actuator Workshop, Hilton Head Island, SC, pp 36-39, 2008<\/li>\n
  102. Xu, X. Zhang, H. Yu, A. Abbaspour-Tamijani, and J. Chae,\u201cIntegration of a Film Bulk Acoustic Resonator with Microfluidic Channels for Biomedical Sensing in Liquid,\u201d Solid-State Sensor and Actuator Workshop, Hilton Head Island, SC, pp 142-145, 2008<\/li>\n
  103. Lin, H. Yu, M. Waters, E.S. Kim, and S. D. Goodman, “Explosive Trace Detection with FBAR-Based Sensor,\u201d IEEE International Micro Electro Mechanical Systems Conference, Tucson, AZ, pp 208-211, 2008<\/li>\n
  104. Lee, S. Chen, D. Chi, H. Yu, and E.S. Kim, ” Surface Micromachined GHz Tunable Capacitor with 14:1 Continuous Tuning Range,\u201d IEEE International Micro Electro Mechanical Systems Conference, Tucson, AZ, pp 1008-1011, 2008<\/li>\n
  105. Y. Lee, W. Pang, H. Yu and E. S. Kim, \u201cSubpicoliter droplet generation based on a nozzle-free acoustic transducer,\u201d Applied Physics Letters, Volume:\u00a093, Issue: 3, Article number: 034104, 2008<\/li>\n
  106. M. Cannata, J. A. Williams, Q. Zhou, L. Sun, K. K. Shung, H. Yu and E. S. Kim, \u201cSelf-focused ZnO transducers for ultrasonic biomicroscopy,\u201d Journal of Applied Physics, Volume: 103, Issue: 8, Article Number: 084109, 2008<\/li>\n
  107. Y. Lee, W. Pang, S. J. Chen, D. Chi, H. Yu, and E. S. Kim, \u201cSurface micromachined, complementary-metal-oxide-semiconductor compatible tunable capacitor with 14 : 1 continuous tuning range,\u201d Applied Physics Letters, Volume: 92, Issue: 4, Article Number: 044103, 2008<\/li>\n
  108. Yu, L. Ai, M. Rouhanizadeh, D. Patel, E. Kim, and T. Hsiai, \u201cFlexible Polymer Sensors for In Vivo Intravascular Shear Stress Analysis,\u201d Journal of Microelectromechanical Systems, Volume: 17, Issue: 5, pp 1178-1186, 2008<\/li>\n
  109. Yu, W. Pang, H, Zhang, and E. S. Kim \u201cUltra temperature-stable bulk-acoustic-wave resonators with SiO2 compensation layer,\u201d IEEE Transactions on Ultrasonics, Ferroelectronics and Frequency Control, Volume: 54, Issue: 10, pp 2102-2109, 2007<\/li>\n
  110. Y.Lee, H. Yu, and E. S. Kim, \u201cMicroreactions Using Nanoliter Droplets with Oil Encapsulation,\u201d IEEE International Micro Electro Mechanical Systems Conference, Kobe, Japan, pp 715-718, 2007<\/li>\n
  111. Yu, C. Lee, W. Pang, H. Zhang, and E.S. Kim, ” Low Phase Noise, Low Power Consuming 3.7 GHz Oscillator Based on High-overtone Bulk Acoustic Resonator,\u201d IEEE International Ultrasonics Symposium, New York, NY, pp 1160 \u2013 1163, 2007<\/li>\n
  112. Yu, D. Wu, C. Lee, Q. Zhou, E.S. Kim, and K.K. Shung, “High-overtone Self-Focusing Acoustic Transducer for High Frequency Ultrasonic Imaging,\u201d IEEE International Ultrasonics Symposium, New York, NY, pp 2401 \u2013 2404, 2007<\/li>\n
  113. Cannata, J. Williams, Q. Zhou, H. Yu, E.S. Kim, and K. K. Shung, ” Self-focused ZnO Transducers for Ultrasonic Biomicroscopy,\u201d IEEE International Ultrasonics Symposium, New York, NY, pp 945 \u2013 948, 2007<\/li>\n
  114. Yu, L. Ai, M. Rouhanizadeh, R. Hamilton, J. Hwang, E.S. Kim and T.K. Hsiai, \u201cFlexible Catheter-Based Cardiovscular Shear Stress Sensor,\u201d 2007 BMES Annual Fall Meeting, Los Angeles, CA, September 26-29, pp 1-4, 2007<\/li>\n
  115. Lee, H. Yu, and E.S. Kim, “Harmonic Operation of Acoustic Transducer for Droplet Ejection Application,\u201d Transducers ’07, IEEE International Conference on Solid-State Sensors and Actuators, Lyon, France, pp 1283-1286, 2007<\/li>\n
  116. F. Lo, S.J. Chen, H. Yu, E.S. Kim, L. Marcu, and M. Gundersen, “Multi-Cantilever-Driven Rotational Translation for Actuated Micro Optical Grating,\u201d Transducers ’07, IEEE International Conference on Solid-State Sensors and Actuators, Lyon, France, pp 2421-2424, 2007<\/li>\n
  117. Yu, L. Ai, M. Rouhanizadeh, R. Hamilton, J. Hwang, E. Meng, E.S. Kim and T.K. Hsiai, \u201cPolymer-Based Cardiovascular Shear Stress Sensors,\u201d ASME Frontiers in Biomedical Devices Conference, Irvine, CA, BioMed 2007-38089, 2007<\/li>\n
  118. Lee, H. Yu, and E.S. Kim, “Microreactions Using Nanoliter Droplets with Oil Encapsulation,\u201d IEEE International Micro Electro Mechanical Systems Conference, Kobe, Japan, pp 81-84, 2007<\/li>\n
  119. Dutta, H. Yu, C. Lee, and E.S. Kim, “Liquid Jet Propeller Integrated with Reservoir, Channel, and Cover,\u201d IEEE International Micro Electro Mechanical Systems Conference, Kobe, Japan, pp 683-686, 2007<\/li>\n
  120. Yu, Q. Zou, J.W. Kwon, D. Huang and E.S. Kim, \u201cLiquid Needle,\u201d Journal of Microelectromechanical Systems, Volume: 16, Issue: 4, pp 445-453, 2007<\/li>\n
  121. Y. Lee, S. Kamal-Bahl, H. Yu, J. W. Kwon, and E. S. Kim, \u201cOn-demand DNA synthesis on solid surface by four directional ejectors on a chip,\u201d IEEE\/ASME Journal of Microelectromechanical Systems, Volume: 16, Issue: 5, pp 1130-1139, 2007<\/li>\n
  122. Pang, H. Zhang, Hao, H. Yu, C. Y. Lee, and E. S. Kim, \u201cElectrical frequency tuning of film bulk acoustic resonator,\u201d IEEE\/ASME Journal of Microelectromechanical Systems, Volume: 16, Issue: 6, pp 1303-1313, 2007<\/li>\n
  123. Y. Lee, H. Yu and E.S. Kim, \u201cNanoliter Droplet Coalescence in Air by Directional Acoustic Ejection,\u201d Applied Physics Letter, Volume: 89, Issue: 22, Article number: 223902, 2007<\/li>\n
  124. W. Kwon, H. Yu, Q. Zou and E. S. Kim, \u201cDirectional droplet ejection by nozzleless acoustic ejectors built on ZnO and PZT,\u201d Journal of Micromechanics and Microengineering, Volume: 16, Issue: 12, pp 2697-2704, 2006<\/li>\n
  125. Yu, H, Zhang, W. Pang and E. S. K, \u201cTemperature Stable, Post-Process Tunable, High Q HBARs at 3~5 GHz\u201d Solid-State Sensor and Actuator Workshop, Hilton Head Island, SC, pp 1-4, 2006<\/li>\n
  126. Lee, H. Yu, and E. S. Kim, \u201cAcoustic Ejector with Novel Lens Employing Air-Reflectors\u201d IEEE International Micro Electro Mechanical Systems Conference, Istanbul, Turkey, pp 170-173, 2006<\/li>\n
  127. Pang, L. Yan, H. Zhang, H. Yu, E.S. Kim and W.C. Tang, “Ultra-sensitive Mass Sensor Based on Lateral Extensional Mode Piezoelectric Resonator,\u201d IEEE International Micro Electro Mechanical Systems Conference, Istanbul, Turkey, pp 78-81, 2006<\/li>\n
  128. Yu, J.W. Kwon and E.S. Kim, “Microfluidic Mixer and Transporter Based on PZT Self-Focusing Acoustic Transducers,\u201d IEEE\/ASME Journal of Microelectromechanical Systems, Volume: 15, Issue: 4, pp 1015-1024, 2006<\/li>\n
  129. Zhang, W. Pang, H. Yu and E.S. Kim, \u201cHigh-tone Bulk Acoustic Resonators on Sapphire, Crystal Quartz, Fused Silica and Silicon Substrates,\u201d Journal of Applied Physics, Volume: 99, Issue: 12, Article number: 124911, 2006<\/li>\n
  130. Pang, L. Yan, H. Zhang, H. Yu, E.S. Kim and W.C. Tang, \u201cFemtogam Mass Sensing Platform Based on Lateral-extensional-mode (LEM) Piezoelectric Resonator,\u201d Applied Physical Letters, Volume: 88, Issue: 24, Article number: 243503, 2006<\/li>\n
  131. Yu, J.W. Kwon and E.S. Kim, “Chembio Extraction on a Chip by Nanoliter Droplet Ejection,\u201d Lab on a Chip, Volume: 5, Issue: 3, pp 344 \u2013 349, 2005<\/li>\n
  132. W. Kwon, H. Yu and E.S. Kim, “Film Transfer and Bonding Techniques for Covering Single-Chip Ejector Array with Microchannels and Reservoirs,\u201d Journal of Microelectromechanical Systems, Volume: 14, Issue: 6, pp1399-1408, 2005<\/li>\n
  133. Pang, H. Zhang, J.J. Kim, H. Yu and E.S. Kim, “High-Tone Bulk Acoustic Resonator Integrated with Surface Micromachined FBAR Filter on a Single Chip,\u201d Transducers ’05, IEEE International Conference on Solid-State Sensors and Actuators, Seoul, Korea, pp 2057-2060, 2005<\/li>\n
  134. J. Kim, H. Zhang, W. Pang, H. Yu and E.S. Kim, “Low Phase Noise, FBAR-Based Voltage Controlled Oscillator without Varactor,\u201d Transducers ’05, IEEE International Conference on Solid-State Sensors and Actuators, Seoul, Korea, pp 1063-1066, 2005<\/li>\n
  135. Zhang, J.J. Kim, W. Pang, H. Yu and E.S. Kim, “5GHz Low-phase-noise Oscillator Based on FBAR with Low TCF,\u201d Transducers ’05, IEEE International Conference on Solid-State Sensors and Actuators, Seoul, Korea, pp 1100-1101, 2005<\/li>\n
  136. Pang, H. Yu, H. Zhang and E.S. Kim, “Electrically Tunable and Temperature Compensated FBAR,\u201d IEEE MTT-S 2005 International Microwave Symposium, Long Beach, California) Technical Digest (ISBN:0-7803-8846-1), 2005<\/li>\n
  137. Pang, H. Zhang, J.J. Kim, H. Yu and E.S. Kim, “High-Tone Bulk Acoustic Resonator Integrated with FBAR Filter on a Single Chip,\u201d IEEE MTT-S 2005 International Microwave Symposium (Long Beach, California), Technical Digest (ISBN:0-7803-8846-1), 2005<\/li>\n
  138. Yu, W. Pang, H. Zhang and E.S. Kim, “Film Bulk Acoustic Resonator at 4.4 GHz with Ultra Low Temperature Coefficient of Resonant Frequency,\u201d IEEE International Micro Electro Mechanical Systems Conference, Miami, Florida, pp 28-31 2005<\/li>\n
  139. Soundararajan, M. Rouhanizadeh, H. Yu, L. Demaio, E. S. Kim and T. K Hsiai, \u201cMEMS Shear Stress Sensors for Microcirculation,\u201d Sensors and Actuators A-Physical, Volume: 118, Issue: 1 pp 25-32, 2005<\/li>\n
  140. Pang, H. Yu, H. Zhang and E. S. Kim, \u201cTemperature-compensated film bulk acoustic resonator above 2 GHz,\u201d IEEE electron device letters, Volume: 26, Issue: 6, pp 369-371, 2005<\/li>\n
  141. Pang, H. Zhang, H. Yu and E.S. Kim, \u201cElectrically Tunable and Switchable Film Bulk Acoustic Resonator,\u201d IEEE International Ultrasonics Symposium, Montreal, Canada, pp 22-26, 2004<\/li>\n
  142. Pang, H. Yu, H. Zhang and E.S. Kim, \u201cSelf-Aligned Lateral Field Excitation Film Acoustic Resonator with Very Large Electromechanical Coupling,\u201d IEEE International Ultrasonics Symposium, Montreal, Canada pp 558-561, 2004<\/li>\n
  143. Yu and E.S. Kim, “Ultrasonic Underwater Thruster,\u201d IEEE International Micro Electro Mechanical Systems Conference, Maastricht, Netherlands, pp 486-489, 2004<\/li>\n
  144. Yu and E.S. Kim, “Liquid Separation for Chemical Extraction by Large Droplet Ejection and Millimeter High Liquid Fountain,\u201d Transducers ’03, IEEE International Conference on Solid-State Sensors and Actuators, Boston, MA, pp 611-614, 2003<\/li>\n
  145. Yu and E.S. Kim, “Micropropulsion of Air and Liquid Jet by Acoustic Streaming,\u201d IEEE International Micro Electro Mechanical Systems Conference, Kyoto, Japan, pp 76-79, 2003<\/li>\n
  146. Yu and E.S. Kim, “Large Area Microfluidic Mixer Integrated with Linear Fluidic Transporters and Reservoirs,\u201d Solid-State Sensor and Actuator Workshop, Hilton Head Island, SC, pp 362-365, 2002<\/li>\n
  147. Yu and E.S. Kim, “Noninvasive Acoustic-Wave Microfluidic Driver,\u201d IEEE International Micro Electro Mechanical Systems Conference, Las Vegas, Nevada, pp 125-128, 2002.<\/li>\n<\/ol>\n

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