Faculty Lineup

https://scholar.google.com/citations?hl=en&user=tvTyhaUAAAAJ&view_op=list_works&sortby=pubdate

Liquid crystal and Photonics Devices
1. Y. Lu, S.-C. Jeng*, Applying Tamm plasmon polaritons for determining the birefringence of a thin film, Opt. Lett. (accepted, 2020).
2. T.-C. Hou, S.-C. Jeng*, “Application of Bombyx mori Silk Fibroin Films for Liquid-Crystal Devices”, ACS Appl. Bio Mater. Vol. 3. 8575 (2020).
3. J.-J. Gao, J.-W. Pan*, S.-C. Jeng*, Low-aberration liquid crystal lens with positive and negative focal length, Opt. Lett. Vol. 45, 5077 (2020).
4. S.-C. Jeng*, “Applications of Tamm plasmon-liquid crystal devices”, Liq. Cryst. Vol. 47, 1223 (2020). (invited review paper)
5. V. Gdovinová, N. Tomašovičová, S.-C. Jeng, K. Zakutanská, P. Kula, P. Kopčanský, “Memory effect in nematic phase of liquid crystal doped with magnetic and non-magnetic nanoparticles,”J. Mol. Liquids, Vol. 282, 286 (2019).
6. H.-C. Cheng, C.-Y. Kuo, Y.-J. Hung, K.-P. Chen, and S.-C. Jeng*, “Liquid crystal active Tamm plasmon devices,” Phys. Rev. Appl., Vol. 9, 064034 (2018).
7. M.-Z. Chen, S.-H. Yang, S.-C. Jeng*, “Growth of ZnO Nanorods and Their Applications for Liquid Crystal Devices,” ACS Appl. Nano Mater., Vol. 1, 1879 (2018).
8. C.-W. Huang, and S.-C. Jeng*, “Polyhedral Oligomeric Silsesquioxane Films for Liquid Crystal Alignment,” Colloids Interfaces, Vol. 2, 9 (2018).
9. S.-G. Huang, K.-P. Chen, and S.-C. Jeng*, “Phase sensitive sensor on Tamm plasmon devices,” Opt. Mater. Express, Vol. 7, 1267-1273 (2017).
10. J.-W. Hu, S.-H. Yang, S.-C. Jeng*, “Annealed zinc oxide films for controlling the alignment of liquid crystals,” J. Mater. Sci., Vol. 52, 9539 (2017).
11. J.-W. Hu, S.-H. Yang, S.-C. Jeng*, “UV-treated ZnO films for liquid crystal alignment,” RSC Advances, Vol. 6, 52095 (2016).
12. Y.-F. Chung, M.-Z. Chen, S.-H. Yang and S.-C. Jeng* (2015)“Tunable surface wettability of ZnO nanoparticle arrays for controlling the alignment of liquid crystals,” ACS Appl. Mater. Interfaces, Vol. 7, 9619-9624.
13. J.-W. Hu, T.-A. Chen and S.-C. Jeng*, “Broadband cholesteric liquid crystal devices with poly(N-vinyl carbazole) microstructures”, Liq. Cryst. Vol. 42, 52-56 (2015).
14. M.-Z. Chen, W.-S. Chen, S.-C. Jeng*, S.-H. Yang and Y.-F. Chung (2013), “Liquid crystal alignment on zinc oxide nanowire arrays for LCDs applications”, Opt. Express, Vol. 21, 29277-29282.
15. C.-E. Lee and S.-C. Jeng* (2013), “Bistable liquid crystal devices with nanoparticle-coated polyimide alignment films”, Opt. Lett. Vol. 38, 1013-1015.
16. H.-S. Liu and S.-C. Jeng* (2013), “Liquid crystal alignment by polyhedral oligomeric silsesquioxane (POSS)–polyimide nanocomposites”, Opt. Mat. Vol. 35, 1418-1421.
17. S.-J. Hwang, T.-A. Chen, and K.-R. Lin, and S.-C. Jeng*, (2012), “Ultraviolet light treated polyimide alignment layers for polarization-independent liquid crystal Fresnel lenses”, Appl. Phys. B. Vol. 107, 151-155.
18. S.-C. Jeng, S.-J. Hwang, J.-S. Horng, and K.-R. Lin (2010), “Electrically switchable liquid crystal Fresnel lens using UV-modified alignment film”, Opt. Express, Vol. 18, 26325.
19. S.-C. Jeng, S.-J. Hwang, Y.-H. Hung, and S.-C. Chen (2010), “Cholesteric liquid crystal devices with nanoparticles aggregation”, Opt. Express, Vol. 18, 22572.
20. S.-J. Hwang, S.-C. Jeng*, I.-M. Hsieh (2010), “Nanoparticle-doped polyimide for controlling the pretilt angle of liquid crystals devices”, Opt. Express, Vol. 18, 16507.
21. W.-Y. Teng, S.-C. Jeng, C.-W. Kuo, J.-M. Ding, and W.-K. Chin (2010), “Flexible Homeotropic Liquid Crystal Displays Using Low-Glass-Transition-Temperature Poly(ethylene terephthalate) Substrates”, Jpn. J. Appl. Phys., Vol. 49, 010205
22. Y.-H. Lin*, J.-M Yang, C.-H. Lo, Y.-R. Lin, S. -C. Jeng, and C. -C. Liao, “Polarizer-Free Gradient Dye-Doped Liquid Crystal Gels”, Molecular Crystals and Liquid Crystals, Vol. 511, 1779-1788 (2009)..
23. S.-C. Jeng, S.-J. Hwang, C.-Y. Yang (2009), “Tunable Pretilt Angles Based on Nanoparticles-Doped Planar Liquid Crystal Cells”, Opt. Lett., Vol. 34, 455-457.
24. S.-J. Hwang, S.-C. Jeng*, C.-Y. Yang, C.-W. Kuo, and C.-C. Liao (2009), “Characteristics of nanoparticles-doped homeotropic liquid crystal devices”, J. Phys. D: Appl. Phys., Vol. 42, 025102.
25. Y.-H. Lin*, J.-M Yang, Y.-R. Lin, S. -C. Jeng, and C. -C. Liao, “A polarizer-free flexible and reflective display using dye-doped liquid crystal gels”, Optics Express, Vol. 16, 1777-1785 (2008).
26. W.-Y. Teng, S.-C. Jeng*, C.-W. Kuo, Y.-R. Lin, C. -C. Liao, and W.-K. Chin (2008), “Nanoparticles-doped guest-host liquid crystal displays”, Opt. Lett., Vol. 33, 1663-1665.
27. C.-W. Kuo, S.-C. Jeng, H.-L. Wang, and C.-C Liao (2007), “Application of nanoparticles-induced vertical alignment in hybrid-aligned nematic liquid crystal cell”, Appl. Phys. Lett., Vol. 91, 141103.
28. S.-C. Jeng*, C.-W. Kuo, H.-L. Wang, and C.-C Liao (2007), “Nanoparticles-induced vertical alignment in liquid crystal cell”, Appl. Phys. Lett., Vol. 91, 061112.
29. S.-C. Jeng*, L.-P. Hsin, Y.-R. Lin, J.-M. Ding, and C.-C. Liao, “A substrate with low glass transition temperature for film-like liquid crystal display”, Japanese Journal of Applied Physics, Vol. 45, 6340-6341 (2006).
30. S.-C Jeng*, L.-P. Hsin, Y.-A. Sha, J.-M. Ding, H.-L. Wang, Y.-C. Hung, and C.-C. Liao, “Film-like liquid crystal displays”, Japanese Journal of Applied Physics, Vol. 44, L159-L160 (2005).
31. S.-C. Jeng*, K.-H. Chang, J.-M. Ding, L.-P. Hsin, C.-Y. Lin, Y.-R. Lin, and K.-H. Liu, and C.-C. Liao, “Technologies toward flexible liquid-crystal displays”, Journal of the Society for Information Display, Vol. 13, 475-479 (2005).

Human Factors of Electronic Papers
32. Y.-T. Lin*, S.-L. Hwang, S.-C. Jeng, and R.J. Koubek, “Minimum ambient illumination requirement for legible electronic-paper display”, Displays, Vol. 32, 8-16 (2011).
33. A.-H. Wang*, S.-L. Hwang, H.-T. Kuo, and S.-C. Jeng, “Effects of ambient illuminance and electronic displays on users' visual performance for young and elderly users”, Journal of the Society for Information Display, Vol. 18, 629-634 (2010).
34. Y.-T. Lin*, P.-H. Lin, S.-L. Hwang, S.-C. Jeng, and C.-C. Liao, “Investigation of legibility and visual fatigue for simulated flexible electronic paper under various surface treatments and ambient illumination conditions”, Applied Ergonomics, Vol. 40, 922-928 (2009).
35. A.-H. Wang*, H.-T. Kuo, and S.-C. Jeng (2009/08), “Effects of ambient illuminance on users' visual performance using various electronic displays”, Journal of the Society for Information Display, Vol. 17, 665-669 (2009).
36. Y.-T. Lin*, P.-H. Lin, S.-L. Hwang, and S.-C. Jeng, “Surface treatment, reflectance, and age effects on electronic paper reading performance”, Journal of the Society for Information Display, Vol. 16, 1051-1062 (2008).
37. Y.-T. Lin*, P.-H. Lin, S.-L. Hwang, S.-C. Jeng, and Y.-R. Lin, “Ergonomic Evaluation of Electronic Papers: Influences of Anti-reflection Surface Treatment, Illumination, and Curvature on Legibility and Visual Fatigue”, Journal of the Society for Information Display, Vol. 16, 91-99 (2008).
38. A.-H. Wang*, C.-C. Tseng, S.-C. Jeng, and K.-I Huang, “Effects of electronic book display and inclination on users’ comprehension under various ambient illuminance conditions”, Journal of the Society for Information Display, Vol. 16, 101-106 (2008).
39. P.-H. Lin*, Y.-T. Lin, S.-L. Hwang, S.-C. Jeng and C.-C. Liao, “Effects of anti-glare surface treatment, ambient illumination and bending curvature on legibility and visual fatigue of electronic papers”, Displays, Vol. 29, 25-32 (2008).
40. D.-S. Lee, K.-K. Shieh, S.-C. Jeng and I-H. Shen*, “Effect of character size and lighting on legibility of electronic papers”, Displays, Vol. 29, 10-17 (2008).
41. A.-H. Wang*, C.-C. Tseng, and S.-C. Jeng, “Effects of bending curvature and text/background color-combinations of e-paper on subjects’ visual performance and subjective preferences under various ambient illuminance conditions”, Displays, Vol. 28, 161-166 (2007).

Neutrino Physics
42. S.-C. Jeng, W.M. Fairbank*, Jr., and M. Miyajima, “Measurements of the mobility of alkaline earth ions in liquid xenon”, Journal of Physics D: Applied Physics, Vol. 42, 035302 (2009).
43. D.S. Leonard, et al. (EXO collaboration), “Systematic study of trace radioactive impurities in candidate construction materials for EXO-200”, Nuclear Instruments and Methods in Physics Research, Section A, Vol. 591, 490-509 (2008).
44. F. Leport, et al. (EXO collaboration), “A liquid xenon ionization chamber in an all-fluoropolymer vessel”, Nuclear Instruments and Methods in Physics Research, Section A, Vol. 578, 409-420 (2007).
45. K. Wamba, et al. (EXO collaboration), “Mobility of thorium ions in liquid xenon”, Nuclear Instruments and Methods in Physics Research, Section A, Vol .555, 205-210 (2005).

C. Book Chapter
1. S.-C. Jeng*, and S.-J. Hwang, “Controlling the alignment of polyimide for liquid crystal devices,” in " High Performance Polymers – Polyimides Based – From Chemistry to Applications", ISBN 978-953-51-0899-3, InTech, Croatia (2012).

1. DISPLAY DEVICE AND METHOD FOR FABRICATING DISPLAY DEVICE, US 7,440,071

2. Transflective electrophoretic display and manufacturing method thereof, US 7,339,716

3.Transflective electrophoretic display device, US 7,248,394

4.Method and system for inspecting flexible devices,
US 7,181,979

5.Method and apparatus for inspecting flexible display medium layer, US 7,486,101

6.Apparatus for automatically adjusting display parameters relying on visual performance and method, US 7,583,253

7. Liquid crystal device, US 7,550,094