林佑昇

林佑昇,男,博士,中山大學電子與信息工程學院副教授。

基本介紹

  • 中文名:林佑昇
  • 職業:教師
  • 畢業院校:中國台灣國立清華大學
  • 學位/學歷:博士
  • 專業方向:納微米機電系統工程等
  • 職稱:副教授
  • 任職院校:中山大學
人物經歷,教育經歷,工作經歷,學術兼職,授課課程,研究方向,學術成果,科研項目,代表論著,

人物經歷

教育經歷

中國台灣國立清華大學納米工程與微系統研究所 工學博士
新加坡國立大學電機與計算機工程系 資深研究員

工作經歷

1. 亞太優勢微系統(股)有限公司(台灣)、負責光學微機電器件設計
2. 聯華電子(股)有限公司(台灣)、負責90 nm CMOS刻蝕製程工藝設計與研發
3. 旺宏電子(股)有限公司(台灣)、負責0.13 μm與0.18 μm 產品線
4. 新加坡國立大學、負責CMOS-MEMS製程平台建成與驗證;CMOS製程工藝技術實現三維可調控超材料;Fabry-Perot光學器件
5. 日月光半導體封裝測試(股)有限公司(上海)、負責APPLE公司i-watch、WIFI模組封裝製程研發、新製程評估與導入
6. 中國科學院蘇州納米技術與納米仿生研究所、負責光學微機電(optical MEMS)晶片與微流控(microfluidic)晶片在生醫領域的集成與套用
7. 中山大學電子與信息工程學院

學術兼職

SCI學術期刊與國際會議論文審稿人: Small,Scientific Reports,Applied Surface Science,IEEE PTL, RSC Advances,Sensors, Surface Science、Optics Letters, Applied Optics, Biomedical Microdevices, Optical MEMS and Nanophotonics, IEEE NEMS 等top期刊與國際會議審稿人。
Reviewer of SCI peer-reviewed journal and international conference papers (SCI indexed and EI indexed): Small, Scientific Reports, Applied Surface Science, IEEE PTL, RSC Advances, Sensors, Surface Science, Optics Letters, Applied Optics, Biomedical Microdevices, IEEE JMEMS, IEEE Optical MEMS and Nanophotonics, IEEE NEMS, etc.
Technical Committee Members:
  1. 2018 IEEE 13th Annual International Conference on Nano/Micro Engineered and Molecular Systems (NEMS), 22-26, April 2018, Singapore.
  2. 2019 IEEE 14th Annual International Conference on Nano/Micro Engineered and Molecular Systems (NEMS), 11-14, April 2019, Bangkok, Thailand.
評審委員:
  • 廣東省科學技術廳專家評審委員。Evaluation Expert of Department of Science and Technology of Guangdong Provincial.
  • 新加坡科技研究局科學與工程研究委員會項目評審委員。Project Reviewer of Science & Engineering Research Council (SERC), Agency for Science, Technology and Research (A*STAR) in Singapore.

授課課程

1 電磁場理論(Electromagnetic Field Theory)
2. 量子力學(Quantum Mechanics)
3. 大學物理實驗(I) (Experiment of College Physics I)
4. 科研學術路線與公司產業路線的通識(Academic Research vs. Company Industrial Development: General Guidelines)-
產業鏈與趨勢分析 (Industrial Chain and Trend Analysis)
公司文化與組織架構 (Corporate Culture and Organizational Structure)
半導體產業 (Semiconductor Industry)
微機電產業 (MEMS Industry)

研究方向

納微米機電系統工程(N/MEMS):
1. 新型納微米機電致動器設計,如電熱式致動器、雙向致動器、梳狀式致動器、抓爬式致動器等實現各種能主動調控的光學器件套用。
2. 光學納微米機電器件,如光開關、可調變光衰減器、可調變濾波器等,實現高效率、高精度且大範圍調控的光學套用。
3. 光學納微米機電器件設計與仿真。
可調控超材料(Tunable Metamaterials) :
1. 可調控超材料結構設計製作,實現在可見光、紅外光與太赫茲光譜範圍能主動調控的濾波器、吸收器與感測器套用。
2. 可調控超材料設計與仿真。
表面電漿光子學(Plasmonics/Photonics) :
1. 表面等離激元與光子晶體於不同基底的設計與製作,實現可主動調控的可見光、紅外光與太赫茲器件。
2. 表面等離激元與光子晶體設計與仿真。

學術成果

科研項目

中山大學“百人計畫”引進人才啟動經費

代表論著

國際期刊論文著作列表(IF: 發表當年度的影響因子):48
2019(15):
  1. Z. Zhang, X. Zhang, Z. Liang, S. Cheng, P. Liu, and Y. S. Lin*, “Reconfigurable Double C-shape Metamaterial (DCM) for Terahertz Resonator,”OSA Continuum, to be published, 2019.
  2. Z. Liang, Y. Wen, Z. Zhang, Z. Liang, Z. Xu, and Y. S. Lin*, “Plasmonic metamaterial using metal-insulator-metal nanogratings for high-sensitive refraction index sensor,” Results Phys., vol.15, pp.102602, 2019. (IF: 3.042)
  3. X. Zhang and Y. S. Lin*, “Actively electromagnetic modulation of IHI-shaped terahertz metamaterial with high-efficiency switching characteristic,” Results Phys., vol.15, pp.120532, 2019. (IF: 3.042)
  4. Z. Xu, Z. Lin, S. Cheng, and Y. S. Lin*, “Reconfigurable and Tunable Terahertz Wrench-Shape Metamaterial Performing Programmable Characteristic,” Opt. Lett., vol.44(16), pp.3944-3947, 2019. (IF: 3.866) (Highlighted as an Editor's Pick)
  5. P. Liu, Z. Liang, Z. Lin, Z. Xu, R. Xu, D. Yao, and Y. S. Lin*, “Actively tunable terahertz chain-link metamaterial with bidirectional polarization-dependent characteristic,” Sci. Rep., vol.9, pp.9917, 2019. (IF: 4.011)
  6. Z. Xu and Y. S. Lin*, “A stretchable terahertz parabolic-shaped metamaterial,” Adv. Opt. Mater., vol.7(12), 1900379, 2019. (IF: 7.125)
  7. S. Cheng, Z. Xu, D. Yao, X. Zhang, Z. Zhang, and Y. S. Lin*, “Electromagnetically induced transparency in terahertz complementary spiral-shape metamaterial,”OSA Continuum, vol.2(7), pp.2137-2144, 2019. (Highlighted as an Editor's Pick)
  8. Z. Liang, Z. Lin, P. Liu, and Y. S. Lin*, “Electromagnetic responses of symmetrical and asymmetrical infrared ellipse-shape metamaterial,” OSA Continuum, vol.2(7), pp.2153-2161, 2019.
  9. Z. Chen, L. Wan, J. Song, J. Pan, Y. Zhu, Z. Yang, W. Liu, J. Li, S. Gao, Y. S. Lin, B. Zhang, and Z. Li, “Optical, mechanical and thermal characterizations of suspended chalcogenide glass microdisk membrane,” Opt. Express, vol.27, pp.15918-15925, 2019. (IF: 3.561)
  10. Y. Yu and Y. S. Lin*, “Multi-functional terahertz metamaterial using symmetrical and asymmetrical electric split-ring resonator,” Results Phys., vol.13, pp.102321,2019. (IF: 3.042)
  11. R. Xu, X. Liu, and Y. S. Lin*, “Tunable Ultra-Narrowband Terahertz Perfect Absorber by Using Metal-Insulator-Metal Microstructures,” Results Phys., vol.13, pp.102176, 2019. (IF: 3.042)
  12. J. Luo and Y. S. Lin*, “High-Efficiency of Infrared Absorption by Using Composited Metamaterial Nanotubes,” Appl. Phys. Lett., vol.114(5), pp.051601, 2019. (IF: 3.512)
  13. W. Yu, S. Gao, Y. S. Lin, M. He, L. Liu, J. Xu, Y. Luo, and X. Cai, “MEMS-Based Tunable Grating Coupler,” IEEE Photon. Technol. Lett., vol.31, pp.161-164, 2019. (IF: 2.553)
  14. Y. S. Lin*†, S. Liao, X. Liu, Y. Tong, Z. Xu, R. Xu, D. Yao, and Y. Yu, “Tunable terahertz metamaterial by using three-dimensional double split-ring resonators,” Opt. Laser Technol., vol.112, pp.215-221, 2019. (IF: 3.319)
  15. Y. S. Lin*, K. Yan, D. Yao, and Y. Yu, “Investigation of electromagnetic response of terahertz metamaterial by using split-disk resonator,” Opt. Laser Technol., vol.111, pp.509-514, 2019. (IF: 3.319)
2018(6):
  1. Z. Xu, R. Xu, J. Sha, B. Zhang, Y. Tong, and Y. S. Lin*, “Infrared metamaterial absorber by using chalcogenide glass material with cyclic ring-disk structure,” OSA Continuum, vol.1(2), pp.573-580, 2018.
  2. R. Xu and Y. S. Lin*, “Characterizations of reconfigurable infrared metamaterial absorbers,” Opt. Lett., vol.43(19), pp.4783-4786, 2018. (IF: 3.589)
  3. D. Yao, K. Yan, X. Liu, S. Liao, Y. Yu, and Y. S. Lin*, “Tunable terahertz metamaterial by using asymmetrical double split-ring resonators (ADSRRs),”OSA Continuum, vol.1(2), pp.349-357, 2018.
  4. R. Xu, J. Luo, J. Sha, J. Zhong, Z. Xu, Y. Tong, and Y. S. Lin*, “Stretchable IR metamaterial with ultra-narrowband perfect absorption,” Appl. Phys. Lett., vol.113, pp.101907, 2018. (IF: 3.495)
  5. Y. S. Lin*, W. Chen, “Perfect meta-absorber by using pod-like nanostructures with ultra-broadband, omnidirectional, and polarization-independent characteristics,” Sci. Rep., vol.8, pp.7150, 2018. (IF: 4.122)
  6. Y. S. Lin*, W. Chen, “A large-area, wide-incident-angle, and polarization-independent plasmonic color filter for glucose sensing,” Opt. Mater., vol.75, pp.739-743, 2018. (IF: 2.238)
2017(4):
  1. Y. S. Lin*, “Complementary Infrared Metamaterials for Volatile Organic Solutions Sensing,” Mater. Lett., vol.195, pp.55-57, 2017. (IF: 2.572)
  2. H. Chen, B. Cao, H. Chen, Y. S. Lin, and J. Zhang, “Combination of antibody-coated, physical-based microfluidic chip with wave-shaped arrays for isolating circulating tumor cells,” Biomed. Microdevices, vol.19, pp.66, 2017. (IF: 2.062)
  3. H. Chen, B. Cao, B. Sun, Y. Cao, K. Yang, Y. S. Lin, and H. Chen, “Highly-sensitive capture of circulating tumor cells using microellipse filters,” Sci. Rep., vol.7, pp.610, 2017. (IF: 4.259)
  4. Y. S. Lin*, W. Liu, and C. Hu, “Investigation of cells migration effects in microfluidic chips,” J. Chromatogr. Sep. Tech., vol.8, pp.1000345, 2017.
2016(1):
  1. C. Hu, Y. S. Lin*, H. Chen*, J. Liu, and F. Nie*, “Concentration gradient generator for H460 lung cancer cell sensitivity to the cytotoxic action of curcumin in microenvironmental pH conditions,” RSC Adv., vol.6, pp.107310-107316, 2016. (†: contributed equally; *: corresponding author, IF: 3.108)
2015(3):
  1. Y. S. Lin, C.-Y. Huang, and C. Lee, “Reconfiguration of Resonance Characteristics for Terahertz U-Shape Metamaterial Using MEMS Mechanism,” IEEE J. Sel. Top. Quantum Electron., vol.21, no. 4, 2700207, 2015. (IF: 3.466)
  2. P. Pitchappa, C. P. Ho, Y. Qian, Y. S. Lin, N. Singh and C. Lee, “MEMS switchable infrared metamaterial absorber,” Proc. SPIE Int. Soc. Opt. Eng., vol.9302, pp.93021I, 2015.
  3. Y. S. Lin, P. Pitchappa, C. P. Ho, and C. Lee, “MEMS tunable terahertz metamaterials using out-of-plane mechanisms,” Proc. SPIE Int. Soc. Opt. Eng., vol.9302, pp.93021J, 2015.
2014(6):
  1. M. Zhu, Y. S. Lin, and C. Lee, “Coupling effect combined with incident polarization to modulate double split-ring-resonator in terahertz frequency range,” J. Appl. Phys., vol.116(17), pp.173106, 2014. (IF: 2.101)
  2. Y. S. Lin and C. Lee, “Tunable Fabry-Perot Filter Using Hybrid Integrated Grating and Slot Microstructures,” IEEE/ASME J. Microelectromech. Syst., vol. 23(5), pp. 1009-1011, 2014. (IF: 1.754)
  3. Y. S. Lin and C. Lee, “Tuning Characteristics of Mirrorlike T-Shape Terahertz Metamaterial Using Out-of-Plane Actuated Cantilevers,” Appl. Phys. Lett., vol. 104(25), pp. 251914, 2014. (IF: 3.302)
  4. F. Ma, Y. S. Lin, X. Zhang, and C. Lee, “Tunable multiband terahertz metamaterials using a reconfigurable electric split-ring resonator array,” Light-Sci. Appl. (nature publisher), vol. 3, no. e171, pp.1-8, 2014. (IF: 14.603)
  5. C. P. Ho, P. Pitchappa, Y. S. Lin, C.-Y. Huang, P. Kropelnicki, and C. Lee, “Electrothermally actuated microelectromechanical systems based omega-ring terahertz metamaterial with polarization dependent characteristics,” Appl. Phys. Lett., vol. 104, no. 16, pp. 161104, 2014. (IF: 3.302)
  6. P. Pitchappa, C. P. Ho, Y. S. Lin, P. Kropelnicki, C.-Y. Huang, N. Singh, and C. Lee, “Micro-electro-mechanically tunable metamaterial with enhanced electro-optic performance,” Appl. Phys. Lett., vol. 104, no. 15, pp. 151104, 2014. (IF: 3.302)
2013(4):
  1. Y. S. Lin, F. Ma, and C. Lee, “Three-Dimensional Movable Metamaterials Using Electric Split-Ring Resonators,” Opt. Lett., vol. 38, no. 16, pp. 3126-3128, 2013. (IF: 3.179)
  2. F. Ma, Y. Qian, Y. S. Lin, H. Liu, X. Zhang, Z. Liu, J. M.-L. Tsai, and C. Lee, “Polarization-sensitive microelectromechanical systems based tunable terahertz metamaterials using three dimensional electric split-ring resonator arrays,” Appl. Phys. Lett., vol. 102, no. 16, pp. 161912, 2013. (IF: 3.515)
  3. Y. S. Lin, Y. Qian, F. Ma, Z. Liu, P. Kropelnicki, and C. Lee, “Development of Stress-Induced Curved Actuators for A Tunable THz Filter Based on Double Split-Ring Resonators,” Appl. Phys. Lett., vol.102, no. 11, pp. 111908, 2013. (IF: 3.515)
  4. Y. S. Lin, C. P. Ho, K. H. Koh, and C. Lee, “Fabry-Perot Filter Using Grating Structures,” Opt. Lett., vol. 38, no. 6, pp. 902-904, 2013. (IF: 3.179)
2012(2):
  1. Y. S. Lin, K. H. Lin, T. Tite, C. Y. Chuang, Y. M. Chang, and J. A. Yeh, “Investigation of Nanopatterned c-plane Sapphire Substrates for Growths of Polar and Nonpolar GaN epilayers,” J. Cryst. Growth, vol. 348, pp. 47-52, 2012. (IF: 1.552)
  2. Y. S. Lin, K. H. Lin, Y. M. Chang, and J. A. Yeh, “Epitaxy of m-plane GaN on nanoscale patterned c-plane sapphire substrates,” Surf. Sci., vol. 606, pp. L1-L4, 2012. (IF: 1.838)
2011(2):
  1. Y. S. Lin and J. A. Yeh, “GaN-Based Light-Emitting Diodes Grown on Nanoscale Patterned Sapphire Substrates with Void-Embedded Cortex-Like Nanostructures,” Appl. Phys. Express, vol. 4, pp. 092103, 2011. (IF: 3.013)
  2. Y. S.Lin, W. C.Hsu, K. C.Huang, and J. A.Yeh, “Wafer-level fabrication and optical characterization of nanoscale patterned sapphire substrates,” Appl. Surf. Sci., vol. 258, pp. 2-6, 2011. (IF: 2.103)
2004(4):
  1. C. K. Lee, and Y. S. Lin, “A New Micromechanism for Transformation of Small Displacements to Large Rotations for a VOA,” IEEE Sens. J., vol. 4, pp. 503-509, 2004. (IF: 1.100)
  2. C. K. Lee, Y. S. Lin, Y. J. Lai, M. H. Tasi, C. C. Chen, and C. Y. Wu, “3-V Driven Pop-up Micromirror for Reflecting Light Toward Out-of-plane Direction for VOA Applications,” IEEE Photonics Technol. Lett., vol. 16, pp. 1044-1046, 2004. (IF: 2.552)
  3. C. K. Lee, Y. J. Lai, Y. S. Lin, C. Y. Wu, C. C. Chen, M. H. Tasi, S. Y. Hung, Y. M. Huang, R. S. Huang, and M. S. Lin, “Development of Surface Micromachined Mechanism for Movement Translation and Displacement Amplification,” Jpn. J. Appl. Phys., vol. 43, pp. 3887-3891, 2004. (IF: 1.142)
  4. C. K. Lee, Y. J. Lai, C. Y. Wu, Y. S. Lin, M. H. Tasi, R. S. Huang, and M. S. Lin, “Scratch Drive Actuator Driven Self-assembled Variable Optical Attenuator,” Jpn. J. Appl. Phys., vol. 43, pp. 3906-3909, 2004. (IF: 1.142)
2003(1):
  1. Y. J. Lai, C. K. Lee, C. Y. Wu, W. C. Chen, C. C. Chen, Y. S. Lin, W. L. Fang, and R. S. Huang, “Development of Electrothermal Actuator with Optimized Motion Characteristics,” Jpn. J. Appl. Phys., vol. 42, pp. 4067-4073, 2003. (IF: 1.171)
國際研討會議論文著作列表:61
  1. Y. Mo, Z. Xu, R. Xu, J. Luo, J. Zhong, R. Fang, and Y. S. Lin*, “Tunable Chevron-Beam Infrared Metamaterial,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.48-49, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  2. J. Zhong, R. Xu, J. Luo, T. Xu, Y. Zhang, Z. Xu, and Y. S. Lin* “Fano-resonance of reshaping infrared cross-shape metamaterial (CSM),” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.46-47, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  3. Z. Liang, Z. Lin, P. Liu, Z. Zhang, X. Zhang, Z. Xu, X. Xu, Z. Liang, Z. Song, C. Tang, J. Lin, Y. Wen, R. Xu, and Y. S. Lin* “Reconfigurable Infrared Ellipse-Shape Metamaterial,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.202-203, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  4. R. Xu, Z. Xu, J. Zhong, T. Xu, Y. Zhang, F. Zhan, and Y. S. Lin* “Multi-functional Infrared Metamaterial Absorber,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.114-115, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  5. F. Lu, H. Ou, F. Zhu, Y. Liao, Z. Li, L. Wu, X. Chen, and Y. S. Lin*, “Terahertz Metamaterial with Active Switching Characteristic,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.54-55, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  6. Z. Zeng, J. Dai, R. Fang, X. Zhang, W. Huang, Y. Ding, and Y. S. Lin*, “Ultrahigh Sensitive Meta-Absorber for Refraction Index Sensor,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.126-127, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  7. D. Zheng, X. Hu, L. Wu, X. Chen, F. Zhu, Y. Liao, and Y. S. Lin*, “Tunable Multi-Bandwidth Terahertz Metamaterial Using Split-Disk Resonator,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.56-57, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  8. J. Dai, Z. Zeng, R. Fang, W. Huang, X. Zhang, Y. Ding, and Y. S. Lin*, “Ultra-Broadband and Polarization-Insensitive Tunable Metasurface Absorber,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.122-123, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  9. S. Cheng, Z. Xu, R. Xu, X. Zhang, Z. Zhang, and Y. S. Lin*, “Active Modulation of Electromagnetically Induced Transparency in Terahertz Spiral Metamaterial,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.118-119, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  10. P. Liu, Z. Liang, Z. Lin, Z. Zhang, X. Zhang, Z. Xu, R. Xu, and Y. S. Lin*, “Tunable Multiband Terahertz Metamaterial with Bidirectional Polarization-Dependent Characteristic,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.42-43, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  11. H. Ou, F. Lu, X. Hu, Y. Liao, D. Zheng, F. Zhu, X. Chen, and Y. S. Lin*, “Tunable Terahertz Resonator Using Complementary Metamaterial for High-Efficiency Switch Application,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.50-51, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  12. X. Hu, D. Zheng, H. Ou, L. Wu, andY. S. Lin*, “Tunable Terahertz Metamaterial with Single-/Dual-Band Switching Characteristic,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.116-117, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  13. Z. Lin, Z. Liang, P. Liu, X. Zhang, Z. Xu, Z. Zhang, Z. Li, T. Chen, Z. Luo, H. Luo, Y. Wen, and Y. S. Lin*, “Asymmetrically Polarization-Dependent Terahertz Metamaterial Resonator,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.148-149, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  14. Z. Xu, R. Xu, S. Chen, X. Xu, Z. Lin, P. Liu, and Y. S. Lin*, “Chalcogenide Glass for Infrared Meta-Absorber,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.52-53, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  15. Z. Xu, S. Cheng, R. Xu, D. Yao, P. Liu, Z. Lin, and Y. S. Lin*, “High-Efficiency Flexible Terahertz Metamaterial,” 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.120-121, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  16. R. Fang, Z. Zeng, J. Dai, X. Zhang, Y. Ding, Z. Fan, and Y. S. Lin*, ‘Enhancement of Photoluminescence Characteristic Using Metasurface-Based Perovskite,’ 2019 International Conference on Optical MEMS and Nanophotonics (IEEE OMN 2019), pp.58-59, Daejeon, Korea, 28 Jul.- 1 Aug., 2019.
  17. Z. Lin, P. Liu, Z. Liang, X. Zhang, Z. Xu, Z. Zhang, and Y. S. Lin*, “High-Sensitive and Tunable Terahertz Metamaterial for Polarization Switch,” 24th OptoElectronics and Communications Conference/International Conference on Photonics in Switching and Computing 2019 (OECC/PSC 2019), Fukuoka, Japan, 07-11 Jul. 2019.
  18. Z. Zhang, X. Zhang, Z. Liang, P. Liu, D. Yao, and Y. S. Lin*, “Tunable Double C-shape Metamaterial (DCM) for Terahertz Resonator,” 24th OptoElectronics and Communications Conference/International Conference on Photonics in Switching and Computing 2019 (OECC/PSC 2019), Fukuoka, Japan, 07-11 Jul. 2019.
  19. Y. Mo and Y. S. Lin*, “Chevron-Beam Metamaterial with Active Tunability in Near-Infrared Wavelength Range,” 24th OptoElectronics and Communications Conference/International Conference on Photonics in Switching and Computing 2019 (OECC/PSC 2019), Fukuoka, Japan, 07-11 Jul. 2019.
  20. D. Yao, K. Yan, X. Liu, S. Liao, Y. Yu, W. Chen, J. Sha, R. Xu, J. Luo, J. Zhong, S. Yang, Y. Tong, Z. Xu, and Y. S. Lin*, “Characterizations of Tunable Terahertz Metamaterial by Using Asymmetrical Double Split-Ring Resonators (ADSRRs),” 2018 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2018), pp. 52-53, École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland, 29 Jul-02 Aug. 2018.
  21. J. Sha, W. Chen, K. Yan, J. Luo, R. Xu, D. Yao, S. Liao, J. Zhong, S. Yang, Y. Yu, Y. Tong, Z. Xu, X. Liu, and Y. S. Lin*, “Tunable Metamaterial IR Emitter By Using MEMS Microheater,” 2018 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2018), pp. 88-89, École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland, 29 Jul-02 Aug. 2018.
  22. W. Chen, J. Sha, K. Yan, J. Luo, R. Xu, D. Yao, X. Liu, S. Liao, J. Zhong, S. Yang, Y. Yu, Y. Tong, Z. Xu, Y. S. Lin*, and T. S. Kao*, “Improvement of perovskite photoluminescence characteristics by using a lithography-free metasurface,” 2018 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2018), pp. 82-83, École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland, 29 Jul-02 Aug. 2018.
  23. R. Xu, J. Sha, W. Chen, K. Yan, J. Luo, Y. Yu, S. Liao, J. Zhong, S. Yang, D. Yao, X. Liu, Y. Tong, Z. Xu, and Y. S. Lin*, “A Large-Scale, Omnidirectional, and Polarization-Independent Metamaterial-Based Chemical Sensor,” 2018 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2018), pp. 48-49, École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland, 29 Jul-02 Aug. 2018.
  24. J. Luo, R. Xu, W. Chen, J. Sha, K. Yan, D. Yao, X. Liu, S. Liao, J. Zhong, S. Yang, Y. Yu, Y. Tong, Z. Xu, and Y. S. Lin*, “An ultra-sensitive glucose sensor by using metamaterial-based microfluidic chip,” 2018 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2018), pp.44-45, École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland, 29 Jul-02 Aug. 2018.
  25. Y. S. Lin*, R. Xu, K. Yan, J. Sha, W. Chen, J. Luo, X. Liu, S. Yang, D. Yao, J. Zhong, S. Liao, Y. Yu, Z. Xu, and Y. Tong, “Metamaterial-based label-free chemical sensors for the detection of volatile organic solutions,” The 18th IEEE International Conference on Nanotechnology (IEEE NANO 2018), Tyndall National Institute, Cork, Ireland, 23-26 Jul. 2018.
  26. Y. S. Lin*, R. Xu, Y. Tong, J. Luo, K. Yan, W. Chen, Z. Xu, X. Liu, S. Yang, D. Yao, J. Sha, J. Zhong, S. Liao, and Y. Yu, “A large-scale lithography-free plasmonic color filter for effectively glucose sensing,” The 18th IEEE International Conference on Nanotechnology (IEEE NANO 2018), Tyndall National Institute, Cork, Ireland, 23-26 Jul. 2018.
  27. Y. S. Lin* and C. Hu, “Effectively Anticancer Drug Concentration Gradients by Using 3D Microfluidic Chip,” 2017 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2017), pp.81-82, Courtyard Marriott Santa Fe, New Mexico, USA, 13-17 Aug. 2017.
  28. Y. S. Lin* and J. Liu, “CD-Like Centrifugal Microfluidic Device for Organophosphorus Pesticides (OPP) Sensing,” 2017 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2017), pp.83-84, Courtyard Marriott Santa Fe, New Mexico, USA, 13-17 Aug. 2017.
  29. Y. S. Lin, “Near-UV-Enhanced Sensitivity of Plasmonic Nanotextured Device for Volatile Organic Sensing,” The 12th Conference on Lasers and Electro-Optics Pacific Rim (CLEO-PR); The 22nd OptoElectronics and Communications Conference (OECC); The 5th Photonics Global Conference 2017 (PGC), Marina Bay Sands, Singapore, 31 Jul.-4 Aug. 2017.
  30. P. Pitchappa, C. P. Ho, Y. Qian, Y. S. Lin, N. Singh and C. Lee, “Enhanced controllability in MEMS metamaterial,” The 28th IEEE Intern. Conference on Micro Electro Mechanical Systems (IEEE MEMS 2015), Estoril, Portugal, pp. 1032-1035, 18-22 Jan. 2015.
  31. Y. S. Lin, P. Pitchappa, C. P. Ho, and C. Lee, “MEMS tunable terahertz metamaterials using out-of-plane mechanisms,” The intern. Conf. on Experimental Mechanics in conjunction with the 13th Asian Conf. on Experimental Mechanics 2014 (icEM2014-ACEM13), Holiday Inn Atrium, Singapore, 15-17 Nov. 2014.
  32. P. Pitchappa, C. P. Ho, Y. Qian, Y. S. Lin, N. Singh, and C. Lee, “MEMS switchable infrared metamaterial absorber,” The intern. Conf. on Experimental Mechanics in conjunctionwith the 13th Asian Conf. on Experimental Mechanics 2014 (icEM2014-ACEM13), Holiday Inn Atrium, Singapore, 15-17 Nov. 2014.
  33. Y. S. Lin and C. Lee, “MEMS-Based High-Q Fabry-Perot Filters,” 2014 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2014), pp.115-116, Glasgow, Scotland, 17-21 Aug. 2014.
  34. P. Pitchappa, C. P. Ho, Y. S. Lin, and C. Lee, “Enhanced Electro-optic Switching Characteristics Using MEMS Based Terhertz Metamaterial,” 2014 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2014), pp.37-38, Glasgow, Scotland, 17-21 Aug. 2014.
  35. C. P. Ho, P. Pitchappa, Y. S. Lin, and C. Lee, “Electrothermally Actuated MEMS Terhertz Metamaterial,” 2014 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2014), pp.111-112, Glasgow, Scotland, 17-21 Aug. 2014.
  36. Y. S. Lin, M. Zhu, and C. Lee, “Novel Terahertz Chemical Sensor Using Symmetric T-Shape Metamaterial,” The 6th International Symposium on Microchemistry and Microsystems 2014 (ISMM 2014), Singapore, Jul. 30-Aug. 1, 2014.
  37. Y. S. Lin and C. Lee, “A Tunable 3-D Metamaterials Terahertz Filter,” The 7th Asia-Pacific Conference on Transducers and Micro/Nano Technologies (APCOT 2014), Daegu, Korea, 29 Jun.-2 Jul. 2014.
  38. Y. S. Lin and C. Lee, “An Electrically Tunable THz Filter Using Three-Dimensional Metamaterials,” Optics & Photonics Taiwan, International Conference 2013 (OPTIC 2013), pp. S0104-O001, National Central University, Taiwan, 5-7 Dec. 2013.
  39. Y. S. Lin, F. Ma, and C. Lee, “A 3-D Movable Metamaterials Filter Using Surface Micromachining Process,” 2013 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2013), pp. 169-170, Kanazawa Bunka Hall, Japan, 18-22 Aug. 2013.
  40. Y. S. Lin, C. P. Ho, P. Pitchappa, F. Ma, Y. Qian, P. Kropelnicki, and C. Lee, “Tunable THz Filter Using 3-D Split-Ring Resonators,” 2013 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2013), pp.167-168, Kanazawa Bunka Hall, Japan, 18-22 Aug. 2013.
  41. F. Ma, Y. S. Lin, Y. Qian, C. P. Ho, P. Pitchappa, and C. Lee, “Development of Tunable 3-D eSRR for THz Applications,” 2013 IEEE International Conf. on Optical MEMS and Nanophotonics (IEEE OMN 2013), pp. 141-142, Kanazawa Bunka Hall, Japan, 18-22 Aug. 2013.
  42. Y. S. Lin, F. Ma, Y. Qian, P. Kropelnicki, Z. Liu, and C. Lee, “A Three-Dimensional THz Metamaterials Using Double Split-Ring Resonators,” the 10 Conference on Lasers and Electro-Optics Pacific Rim (CLEO-PR) & the 18OptoElectronics and Communications Conference/Photonics in Switching (OECC/PS), WC4-5, Kyoto, Japan, 30 Jun.-4 Jul. 2013.
  43. Y. S. Lin, F. Ma, and C. Lee, “A MEMS-Based 3-D Movable Metamaterials,” the 10 Conference on Lasers and Electro-Optics Pacific Rim (CLEO-PR) & the 18OptoElectronics and Communications Conference/Photonics in Switching (OECC/PS), ThL1-2, Kyoto, Japan, 30 Jun.-4 Jul. 2013.
  44. F. Ma, Y. Qian, Y. S. Lin, H. Liu, X. Zhang, and C. Lee. “Development of MEMS Electric Split-ring Resonator Arrays as Tunable THz Filters,” the 10 Conference on Lasers and Electro-Optics Pacific Rim (CLEO-PR) & the 18OptoElectronics and Communications Conference/Photonics in Switching (OECC/PS), WC4-6, Kyoto, Japan, 30 Jun.-4 Jul. 2013.
  45. Y. S. Lin and J. A. Yeh, “Nanoscale Patterned Sapphire Substrates with Cortex-Like Nanostructures for GaN-Based LEDs,” 2011 IEEE International Conf. Optical MEMS and Nanophotonics (IEEE OMN 2011), pp.63-64, Istanbul, Turkey, 8-11 Aug. 2011.
  46. Y. S. Lin and J. A. Yeh, “Wafer-Level Fabrication of Nanoscale Patterned Sapphire Substrates with Broadband Optical Transmittance,” the 16th International Conference on Solid-State Sensors, Actuators and Microsystems (Transducer’ 11), pp.641-644, Beijing, China, 5-9 Jun. 2011.
  47. K. H. Lin, C. Y. Chuang, Y. M. Chang, J. Y. Chyan, Y. S. Lin, and J. A. Yeh, “Blue-Green Emission from Aged Porous Silicon,” 2011 annual meeting of the physical society of ROC, Taipei, Taiwan, 25-27 Jan. 2011.
  48. Y. S. Lin and J. A. Yeh, “Improvement of GaN Crystalline Quality on Nanoscale Patterned Sapphire Substrates,” 2010 IEEE International Conf. Optical MEMS and Nanophotonics (IEEE OMN 2010), pp. 153-154, Sapporo, Japan, 9-12 Aug. 2010.
  49. Y. S. Lin and J. A. Yeh, "GaN-Based LEDs of High Brightness Grown on Wafer-Level Nanoscale Patterned Sapphire Substrates," Nano and Micro Systems (NAMIS) Workshop, 17-19 Dec. 2010.
  50. Y. S. Lin, E. H. Chang, W. C. Hsu, K. C. Huang, and J. A. Yeh, “The Optical Characterization of Nanoscale Patterned Sapphire Substrates,” the 14 Nano & Microsystem Technology, Kaohsiung , Taiwan, 2-3 Sep. 2010.
  51. C. K. Lee, Y. J. Lai, Y. S. Lin, R. S. Huang, and M. S. Lin, “Development of Novel Micromechanism for Movement Translation and Out-of-plane Displacement Amplification,” 5th Pacific Rim Conference on Lasers and Electro-Optics co-sponsored by Optical Society of America, IEEE/LEOS, pp.601, Taipei, Taiwan, 15-19 Dec. 2003.
  52. Y. J. Lai, C. Y. Wu, C. K. Lee, Y. S. Lin, W. C. Chen, C. C. Chen, R. S. Huang, and M. S. Lin, “Design and characterization of electrothermal actuator from reliability and robust aspects,” 5th Pacific Rim Conference on Lasers and Electro-Optics co-sponsored by Optical Society of America, IEEE/LEOS, pp.100, Taipei, Taiwan, 15-19 Dec. 2003.
  53. C. K. Lee and Y. S.Lin, “Novel Micromechanism of Transferring In-plane Displacement into Out-of-plane Motion for Optical MEMS,” 7th International Conf. on Mechatronics Technology (ICMT 2003), Taipei, Taiwan, 2-6 Dec. 2003.
  54. C. K. Lee, Y. J. Lai, C. Y. Wu, Y. S. Lin, M. H. Tasi, and R. S. Huang, “Self-assembled Continuously Movable MEMS Shutter and Corrugated Curved Beam Electrostatic Actuator for Variable Optical Attenuator Application,” 7th International Conference on Mechatronics Technology (ICMT 2003), Taipei, Taiwan, 2-6 Dec. 2003.
  55. Y. J. Lai, C. K. Lee, C. Y. Wu, Y. S. Lin, M. H. Tasi, R. S. Huang, and M. S. Lin, “Fabrication of Corrugated Curved Beam Type Electrostatic Actuator and SDA Driven Self-assembled Mechanism for VOA Applications,” Digest of Microprocesses& Nanotechnology 2003. 2003 International Microprocesses and Nanotechnology Conference, pp.286-287, Tokyo, Japan, 28-31 Oct. 2003.
  56. C. K. Lee, Y. S. Lin, Y. J. Lai, M. H. Tsai, C. C. Chen, C. Y. Wu, and R. S. Huang, “New Out-of-plane Light Attenuation Scheme Based on Surface Micromachined Pop-up Mirror and Movement Translation Micromechanism,” Digest of Papers Microprocesses and Nanotechnology 2003. 2003 International Microprocesses and Nanotechnology Conference, pp.174-175, Tokyo, Japan, 28-31 Oct. 2003.
  57. Y. J. Lai, C. K. Lee, C. Y. Wu, Y. S. Lin, and M. H. Tsai, “Self-assembled Axial Type Variable Optical Attenuator Using Continuously Movable Pop-up MEMS Mirror,” 9th Microoptics Conf., Tokyo, Japan, 29-31 Oct. 2003.
  58. Y. J. Lai, C. K. Lee, C. Y. Wu, M. H. Tasi, and Y. S.Lin, “Self-assembled out-of-plane movable vane for variable optical attenuator application,” IEEE Conf. On Lasers and Electro Optics 2003, CLEO 2003, Baltimore, USA, 3-5 Jun. 2003.
  59. Y. J. Lai, C. Y. Wu, C. Lee, Y. S. Lin, W. C. Chen, C. C. Chen, R. S. Huang, and M. S. Lin, “Design and Characterization of Electrothermal Actuator from Reliability and Robust Aspects,” IEEE Conference on Lasers and Electro-Optics Pacific Rim 2003 (CLEO-PR 2003), pp.100, Taipei, Taiwan, 15-19 Dec. 2003.
  60. Y. J. Lai, C. Y. Wu, C. Lee, Y. S. Lin, W. C. Chen, C. C. Chen, M. H. Tsai, R. S. Huang, and M. S. Lin, “Out-of-Plane MEMS Shutter with Continuous Motion Capability for VOA Application,” IEEE Conference on Lasers and Electro-Optics Pacific Rim 2003 (CLEO-PR 2003), pp. 141, Taipei, Taiwan, 15-19 Dec. 2003.
  61. C. Lee, Y. J. Lai, Y. S. Lin, R. S. Huang, and M. S. Lin, “Development of Novel Micromechanism for Movement Translation and Out-of-Plane Displacement Amplification,” EEE Conference on Lasers and Electro-Optics Pacific Rim 2003 (CLEO-PR 2003), pp.601, Taipei, Taiwan, 15-19 Dec. 2003.
國際新聞雜誌: 3
  1. Semiconductor Today, Sep./Oct., 2011.
  2. EQE increased 2.4-fold with void-embedded cortex nano-patterned LED”, Semiconductor Today, Vol.6, Issue 7, page 118-119, September/October, 2011.
  3. “Patterned sapphire for nitride enhancements”, Semiconductor Today, Vol.6, Issue 7, page 120-124, September/October, 2011.

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