Invited book chapter:

  1. S-Y. Park, “Chapter 14 – Optofluidic Devices and Their Applications” in Optical MEMS, Nanophotonics, and Their Applications, edited by G. Zhou and C. Lee, Taylor & Francis Books, Inc., 2017

Journal papers:

  1. Y. Lee, Y-H. Cheng, and S.-Y. Park*, “Electrowetting-driven solar indoor lighting (e-SIL) system for constant interior illumination,” to be submitted to Applied Energy
  2. Y. Lee and S.-Y. Park*, “Dielectrowetting-driven tunable liquid prism for enhanced beam steering,” to be submitted to Sensors & Actuators B: Chemical
  3. Y. Lee and S.-Y. Park*, “Frequency-dependent dielectrowetting control of a dielectric liquid droplet,” to be submitted to Langmuir
  4. M. A. Islam and S.-Y. Park*, “Optimizing optical dielectrophoretic (ODEP) performance: Position- and size-dependent droplet manipulation in an open-chamber oil medium,” Micromachines, 15, 119, 2024
  5. Y. Lee, C.-H. Lee, and S.-Y. Park*, “An arrayed optofluidic system for three-dimensional (3D) focal control via electrowetting,” Optics Express, 31, 17677-17694, 2023
  6. A. Janev, J. S. Kang, and S.-Y. Park*, “A smartphone integrated paper (SIP)-based platform for rapid and on-site screening of urinary tract infections,” Sensors & Actuators B: Chemical, 382, 133498, 2023
  7. S. Thio and S.-Y. Park*, “A review of optoelectrowetting (OEW): from fundamentals to lab-on-a-smartphone (LOS) applications to environmental sensors,” Lab on a Chip, 22, 3987-4006, 2022, (Selected as Lab on a Chip HOT Article, 2022)
  8. S. Thio and S.-Y. Park*, “Optical dielectrophoretic (DEP) manipulation of oil-immersed aqueous droplets on a plasmonic-enhanced photoconductive surface,” Micromachines, 13, 112, 2022 (Article selected as the Feature Paper)
  9. S. Thio, S. Bae, and S.-Y. Park*, “Lab on a Smartphone (LOS): a smartphone-integrated, plasmonic-enhanced optoelectrowetting (OEW) platform for on-chip water quality monitoring through LAMP assays,” Sensors & Actuators B: Chemical, 358, 131543, 2022
  10. T. Lee and S.-Y. Park*,“Capacitance effects of a hydrophobic-coated ion gel dielectric on AC electrowetting,” Micromachines, 12, 320, 2021 (Invited paper)
  11. B. Namgung, T. Lee, J. Tan, D. Poh, S. Park, K. Chng, R. Agrawal, S.-Y. Park, H. L. Leo, and S. Kim, “Vibration motor-integrated low-cost, miniaturized system for rapid quantification of red blood cell aggregation,” Lab on a Chip, 20, 3930-3937, 2020 (Article selected as the BACK COVER of Issue 21, Lab on a Chip)
  12. Q. Chen, S. Oh, M. Burhan, and S-Y Park*, “Design and optimization of a novel electrowetting-driven solar indoor lighting system,” Applied Energy, 269, 115128, 2020
  13. S. Thio, S. Bae, and S.-Y. Park*, “Plasmonic nanoparticle-enhanced optoelectrowetting (OEW) for effective light-driven droplet manipulation,” Sensors and Actuators B: Chemical, 308, 127704, 2020
  14. S. Lee, S. Thio, S.-Y. Park, and S. Bae, “An automated 3D-printed smartphone platform integrated with optoelectrowetting (OEW) microfluidic chip for on-chip monitoring of viable algae in water,” Harmful Algae, 88, 101638, 2019
  15. S. Thio and S.-Y. Park*, “Dispersive optical systems for highly-concentrated solar spectrum splitting: concept, design, and performance analyses,” Energies, 12, 4719, 2019
  16. S. Lee, V. K. S. Ling, T. Lee, S.-Y. Park, and S. Bae, “Rapid and in-situ detection of fecal indicator bacteria in water using simple DNA extraction and portable loop-mediated isothermal amplification (LAMP) PCR methods,” Water Research, 160, 371-379, 2019
  17. S. Thio, D. Jiang, and S.-Y. Park*, “Electrowetting-driven solar indoor lighting (e-SIL): An optofluidic approach towards sustainable buildings,” Lab on a Chip, 18, 1725-1735, 2018 (Article selected as the BACK COVER of Issue 12, 2018)
  18. D. Jiang, S. Lee, S. Bae, and S.-Y. Park*, “Smartphone integrated optoelectrowetting (SiOEW) for on-chip sample processing and microscopic detection of water quality,” Lab on a Chip, 18, 532-539, 2018 (Research highlighted on the Lab on a Chip Promotional Flyer, 2018)
  19. C. Clement, S. Thio, and S.-Y. Park*, “An optofluidic tunable Fresnel lens for spatial focal control based on electrowetting-on-dielectric (EWOD),” Sensors and Actuators B: Chemical, 240, 909-915, 2017
  20. S.-Y. Park* and Y. Nam, “Single-sided digital microfluidic (SDMF) devices for effective coolant delivery and enhanced two-phase cooling,” Micromachines, 8, 3, 2017 (Invited paper)
  21. J. K. S. Tan, S.-Y. Park, H. L. Leo, and S. Kim, “Continuous sheathless separation of white blood cells from whole blood using viscoelastic effects,” IEEE Transactions on Biomedical Circuits and Systems, 11, 1431-1437, 2017
  22. C. Clement, D. Jiang, S. Thio, and S.-Y. Park*, “A study of dip-coatable, high-capacitance ion gel dielectrics for 3D EWOD device fabrication,” Materials, 10, 41, 2017 (Invited paper)
  23. C. Clement and S.-Y. Park*, “High-performance beam steering using an electrowetting-driven liquid prism fabricated by a simple dip-coating method,” Applied Physics Letters, 108, 191601, 2016
  24. D. Jiang and S.-Y. Park*, “Light-driven 3D droplet manipulation on flexible optoelectrowetting devices fabricated by a simple spin-coating method,” Lab on a Chip, 16, 1831-1839, 2016 (Article selected as the Back Cover of Issue 10, 2016)
  25. V. Narasimhan, D. Jiang and S.-Y. Park*, “Design and optical analyses of an arrayed microfluidic tunable prism panel for enhancing solar energy collection,” Applied Energy, 162, 450-459, 2016
  26. B. Namgung, J. Tan, P. A. Wong, S.-Y. Park, H. L. Leo, and S. Kim, “Biomimetic precapillary flow patterns for enhancing blood plasma separation: A preliminary study,” Sensors, 16, 1543, 2016
  27. V. Narasimhan and S.-Y. Park*, “An ion gel as a low-cost, spin-coatable and high-capacitance dielectric for electrowetting-on-dielectric (EWOD),” Langmuir, 31, 8512-8518, 2015
  28. J. Cheng, S.-Y. Park, and C.-L. Chen, “Optofluidic solar concentrators using electrowetting tracking: concept, design, and characterization,” Solar Energy, 89, 152-161, 2013
  29. T.-H. Wu, Y. Chen, S.-Y. Park, J. Hong, T. Teslaa, J. Zhong, D. Carlo, M. Teitell and P.-Y. Chiou “Pulsed laser triggered high speed microfluidic fluorescence activated cell sorter,” Lab on a Chip, 12, 1378-1383, 2012 (Research highlighted in Nature Photonics)
  30. S.-Y. Park and P.-Y. Chiou, “Light-driven droplet manipulation technologies for lab-on-a-chip applications,” Advances in OptoElectronics, Vol. 2011, Article ID: 909174, 2011 (Invited paper for “Optofluidics for Lab on a Chip”)
  31. S.-Y. Park, T.-H. Wu, Y. Chen, M. Teitell, and P.-Y. Chiou, “High-speed droplet generation on demand driven by pulse laser-induced cavitation,” Lab on a Chip, 11, 1010-1012, 2011 (Research highlighted as a Lab on a Chip HOT Articles)
  32. S.-Y. Park, M. Teitell, and P.-Y. Chiou, “Single-sided continuous optoelectrowetting (SCOEW) for droplet manipulation with light patterns,” Lab on a Chip, 10, 1655-1661, 2010 (Article selected as the COVER PAPER of Issue 13)
  33. S.-Y. Park, S. Kalim, C. Callahan, M. Teitell, and P.-Y. Chiou, “A light-induced dielectrophoretic droplet manipulation platform,” Lab on a Chip, 9, 3228-3235, 2009
  34. P.-Y. Chiou, S.-Y. Park, and M. C. Wu, “Continuous optoelectrowetting for picoliter droplet manipulation,” Applied Physics Letters, 93, 221110, 2008 (Research highlighted in Nature Photonics)
  35. S.-Y. Park, C. Pan, T.-H. Wu, C. Kloss, S. Kalim, C. Callahan, M. Teitell, and P.-Y. Chiou, “Floating electrode optoelectronic tweezers (FEOET): light-driven dielectrophoretic droplet manipulation in electrically insulating oil medium,” Applied Physics Letters, 92, 151101, 2008 (Research highlighted in Nature Photonics)
  36. X. Zhu, M. Minor, and S.-Y. Park, “Distributed robust control of compliant framed wheeled modular mobile robots,” Journal of Dynamic Systems, Measurement, and Control, 128, 489-498, 2006