簡介

學歷

• 國立交通大學 光電工程研究所 博士 2002年

現職及經歷

現職

• 國立台北科技大學 光電工程系 教授  2015年 ~        
• 國立台北科技大學 研發處研究企劃組  組長  2014年 ~

經歷

• 國立台北科技大學 光電工程系 副教授        
• 國立台北科技大學 光電工程系 助理教授
• 國立交通大學 光電工程系 博士後研究

授課課程

• 光電工程研究所:
  • 超快光學與應用  (上學期)
  • 非線性光纖光學與應用  (下學期)
• 大學部:
  • 顯示面板與實務

研究領域

• 新穎光電半導體製作與非線性光學量測

  • 氧化鋅/氧化鎂鋅多層量子井受激輻射與超快載子動態
  • 全無機鈣鈦礦量子點製作與受激輻射產生
  • 變溫螢光光譜與時間解析螢光光譜
  • 三階非線性光學量測

• 微奈米光電元件與隨機雷射產生與應用

  • 液晶光電元件製作與光電物理特性量測
  • 可調液晶光電元件之隨機雷射產生
  • 奈米二氧化矽小球與奈米銀製作與表面電漿共振
  • 新穎雷射染料結合有機高分子薄膜與電紡絲之隨機雷射產生
  • 蝴蝶翅膀與絲蛋白等生物性材料之隨機雷射產生

• 光纖短脈衝雷射與生醫檢測

  • 摻鐿與摻餌光纖短脈衝雷射產生
  • 光纖雷射光孤子動態與超連續光譜產生
  • 二維奈米材料製作檢測與應用
  • 拉曼光譜量測
  • 皮膚非破壞性光學診測

研究計畫

   目前執行之計畫

        科技部計畫

• 利用短脈衝雷射進行新穎光電材料激子動態與非線性光學之研究   2019/08/01 至 2020/07/31               
• 摻染料金屬修飾絲蛋白之電漿隨機雷射動力學研究  2019/09/01 至 2020/07/31

​    產學合作計畫

• 可攜式拉曼光譜儀之改善 (昇航股份有限公司)   2019/09/01 至 2020/12/31
• 全正色散鎖模光纖雷射光孤子之建構與分析(工研院)  2020/01/01 至 2020/11/30

  校際合作計畫

• 利用似噪音脈衝搭配非線性光學顯微鏡進行皮膚之檢測(長庚醫院)  2020/01/01 至 2020/12/31
• 基於黑磷材料的智慧鎖模雷射器研究 (深圳大學)  2020/01/01 至 2020/12/31

歷年計畫(已結案)

   科技部計畫

• 極化與非極化氧化鋅之載子動態與同調聲學聲子振盪研究  2016/08/01 至 2019/07/31
• 氧化鋅微結構之載子與聲子動力學研究     2013/08/01 至 2016/07/31
• 高強度光脈衝雷射在微奈米週期結構光電材料之非線性光學特性研究 2010/08/01 至 2013/07/31
• 高強度雙纖殼摻鐿光子晶體光纖雷射的研究與全光纖白光光源的產生 2008/08/01 至 2010/07/31
• 飛秒短脈衝雷射在奈米結構光電材料之非線性光學研究 2007/11/01 至 2010/07/31

校際合作計畫

• 可攜式拉曼光譜儀在皮膚癌檢測之應用(長庚醫院)   2019/01/01 至 2019/12/31
• 基於二維材料的大能量孤子脈衝光纖雷射器研究(深圳大學) 2019/01/01 至 2019/12/31
• 近紅外短脈衝光源在肌膚表面檢測之應用(長庚醫院)   2018/01/01 至 2018/12/31

台北科技大學重點特色計畫

• 利用新穎光電材料與原件研發近紅外至中紅外光纖短脈衝雷射   2015/01/01 至 2016/12/31
• 新穎液晶元件開發與應用   2012/01/01 至 2014/12/31

研究成果殊榮

     個人得獎                

• 104學年度 國立台北科技大學電資學院   傑出研究獎
• 103學年度 國立台北科技大學           年輕學者研究獎
• 101學年度 國立台北科技大學電資學院   傑出研究獎
• 97 學年度 國立台北科技大學電資學院   傑出研究獎

國際期刊論文(近十年選錄)

        Physical property and nonlinear optical measurement of novel semiconductor materials

1. K. Uma , N. Arjun , S. Chandra Mohan , G.-T. Pan , K. Jothivenkatachalam, Thomas C.-K. Yang*, J.-H. Lin,* “In-situ DRIFT-IR investigation of photocatalytic redox reactivity of the SiO2@α-Fe2O3 core-shell decorated RGO nanocomposite,” has been accepted by the Sci. Rep.
2. W.-R. Liu,* J.-H. Lin,* J.-S, Chen, H.-M. Cheng, S.-J. Li, H.-R. Chen, C.-H. Hsu and W.-F. Hsieh, “Saturation and beating of acoustic phonon oscillations excited near the exciton resonance of strained polar ZnO/Zn_0.8Mg_0.2O multiple quantum wells,” RSC Adv., 8, 7980, February (2018).
3. J.-H. Lin,* Yu-Kai Shen, Wei-Rein Liu, Chia-Hui Lu, Yao-Hui Chen, Chun-peng Chang, Wei-Chin Lee, Minghwei Hong, Jueinai-Raynien Kwo, Chia-Hung Hsu, and Wen-Feng Hsieh, “Coherent acoustic phonon oscillation accompanied with backward acoustic pulse below exciton resonance in a ZnO epilm on oxide-buered Si(111),” J. Phys. D., 49, 325102, July (2016).
4. J.-H. Lin,* W.-R. Liu, Y.-C. Lin, H.-J. Su, H.-R. Chen, C.-Y. Tsai, Y.-H. Chen, and W.-F. Hsieh, “Room temperature excitonic dynamics of non-polar a-plane ZnO epifilms,” AIP advances 6, 095222, Sept (2016).
5. J.-H. Lin,* H.-J. Su, C.-H. Lu, C.-P. Chang, W.-R. Liu, and Wen-Feng Hsieh, “Pump polarization dependent ultrafast carrier dynamics and two-photon absorption in an a-plane ZnO epitaxial film,” Appl. Phys. Lett. 107, 142107 (2015).
6. T.-C. Lin,* M.-H. Li, C.-Y. Liu, J.-H. Lin, Y.-K. Shen and Y.-H. Lee “Synthesis and two-photon properties of a novel multi-branched chromophore with an unsymmetrically substituted scaffold derived from functionalized quinoxalinoid heterocycles,” J. Mater. Chem. C 1, 2764 (2013).
7. T.-C. Lin,* Y.-H. Lee, C.-Y. Liu, B.-R. Huang, M.-Y. Tsai, and Yu-Jhen Huang, Ja-Hon Lin,* Yu-Kai Shen, and Cheng-Yu Wu “Synthesis and Two-photon Absorption Property Characterizations of Small Dendritic Chromophores Containing Functionalized Quinoxaliniod Heterocycles,” Chem. Eur. J 19, 749 (2013).
8. P.-C. Ou, J.-H. Lin,* and W.-F. Hsieh, “Spectral dependence of transient reflectance in a ZnO epitaxial film at room temperature,” Appl. Phys. B, 106, 339 (2012).
9. P. C. Ou. W.-R. Liu, H.-J. Ton, J. H. Lin,* and W.-F. Hsieh, “Ultrafast relaxation and absorption saturation at near exciton resonance in a thin ZnO epilayer,” J. Appl. Phys. 109, 013102 (2011)
10. P.-C. Ou, J.-H. Lin,* C.-A. Chang, W.-R. Liu and W.-F. Hsieh, “Thickness effect on ultrafast thermalization of carriers in above-band-gap states in ZnO epitaxial films,” J. Phys. D: Appl. Phys. 43 (2010).

        Liquid crystal device and nano-structurel and organic luminescence material and random laser

1. W.-C. Chen, J.-H. Shiao, T.-L. Tsai , D.-H. Jiang , L.-C. Chen , C.-H. Chang , B.-H. Lin, J.-H. Lin,* and C.-C. Kuo,* “Multiple Scattering from Electrospun Nanofibers with Embedded Silver Nanoparticles of Tunable Shape for Random Lasers and White-Light-Emitting Diodes,” ACS Appl. Mater. Interfaces, 12, 2783 (2020).
2. J.-H. Hsiao, S.-W. Chen, B.-Y. Hung, K. Uma, W.-C. Chen, and C.-C. Kuo,* J. H. Lin,* “Resonant energy transfer and light scattering enhancement of plasmonic random laser with silver nanoplates,” RSC. Adv. 10, 7551 (2020).
3. J-H Lin,* Y-H Li, S.-H. Lin, and B.-H. Nguyen, “Configuration dependent output characteristics with Fabry–Perot and random lasers from dye-doped liquid crystals within glass cells,” Photonics Res., 6, 403, May (2018).
4. J-H Lin,* J.-W. Huang, J.J. Wu, S.-Y. Tsay, and Y.-H. Chen, “Electrically controllable random lasing from dye-doped nematic liquid crystal within a capillary fiber,” Opt. Mater. Express, 8, 2910 August (2018).
5. J.-H. Lin,* S.-C. Chang, Y.-H. Li, C.-Y. Chien, C.-H. Chen, Y.-C. Lin, J.-J. Wu,* Shwu-Yun Tsay, and Yao-Hui Chen, “Investigation of laser speckle noise suppression by using polymer-stabilized liquid crystals within twisted nematic cell,” Appl. Phys. Express, 10, 031701 (2017).
6. S.-H. Lin, P.-Y. Chen, Y.-H. Li, C.-H. Chen, J.-H. Lin, * Y.-H. Chen, S.-Y. Tsay, and Jin-Jei Wu, “Manipulation of Polarized Random Lasers from Dye-Doped Twisted Nematic Liquid Crystals Within Wedge Cells,” IEEE PJ, 9, 1502208, April (2017).
7. J.-H. Lin,* K.-C. Liao, L.-H. Jian, S.-Y. Tsay, J.-J. Wu, and Y.-G. Duann, “Spatially tunable emissions of dye-doped liquid crystal lasers between the cholesteric and smectic phases,” Opt. Mater. Express, 5, 2142, Sep (2015).
8. J.-H. Lin,* Y.-L. Hsiao, B.-Y. Ciou, S.-H. Lin, Y.-H. Chen, and J.-J. Wu, “Manipulation of Random Lasing Action From Dye-Doped Liquid Crystals Infilling Two-Dimensional Confinement Single Core Capillary,” IEEE Photon. J. 7, 1501809 June (2015).
9. J.-H. Lin,* and Y.-L. Hsiao, “Manipulation of the resonance characteristics of random lasers from dye-doped polymer dispersed liquid crystals in capillary tubes,” Opt. Mater. Express 4, 1555, Aug (2014).
10. J.-H. Lin,* P.-Y. Chen, and J.-J. Wu  “Mode Competition of Two Band-edge Lasing from Dye-Doped Cholesteric Liquid Crystal Laser,” Opt. Express 22, 9932 (2014).

        Passive mode-locked fiber laser and biomedicine diagnosis of human skin

1. J.-H. Lin,* T.-Y. Liao, C.-Y. Yang, D.-G. Zhang, C.-Y. Yang,* Y.-W. Lee, S. Das, A. Dhar, and M. Chandra Paul, “Noise-like pulse generation around 1.3-μm based on cascaded Raman scattering,” Opt. Express. 28, 12252, Apr. (2020).
2. J.-H. Lin,* G.-H. Huang, C.-H. Ou, K.-C. Che, W.-R. Liu, S.-Y. Tasy, and Y.-H. Chen, “Q-Switched Pulse and Mode-Locked Pulse Generation From a Yb3+-Doped Fiber Laser Based on Bi₂Se₃,” IEEE Photon. J, 10, 1502410, June (2018).
3. W.-C. Chang, J.-H. Lin,* T.-Yu. Liao, and C.-Y. Yang,* “Characteristics of noise-like pulse with broad bandwidth based on cascaded Raman scattering,” Opt. Express, 9, 31808 October (2018).
4. W.-C. Chang, Y.-S. Lin, Y.-W. Lee, C.-H. Chen, J.-H. Lin,* P. H. Reddy, S. Das, A. Dhar, and M. C. Paul, “Investigation of Q-Switched and Mode-Locked Pulses From a Yb³⁺-Doped Germano-Zirconia Silica Glass Based Fiber Laser (2017), “IEEE Photon. J, 9, 7104708, August.
5. J.-H. Lin,* C. L. Chen, C.-W. Chan and Y.-H. Chen, “Investigation of noise-like pulses from a net normal Yb-doped fiber laser based on a nonlinear polarization rotation mechanism,” Opt. Lett. 41, 5310, Nov (2016).
6. J.-H. Lin,* C.-W. Chan, H.-Y. Lee, and Y.-H. Chen (2015), “Bound States of Dispersion-Managed Solitons From Single-Mode Yb-Doped Fiber Laser at Net-Normal Dispersion,” IEEE Photon. J. 7, 7102409
7. J.-H. Lin,* B.-C. Lai, and Y.-W. Lee, “High energy rectangular pulse generated in a low repetition rate all normal-dispersion Yb³⁺-doped fiber laser,” Laser Phys. 25, 045101, April (2015).
8. J.-H. Lin, Y. W. Lee, * T.-C. Lin, B.-C. Lai, M. Pal, S. Das, A. Dhar, and M. C. Paul, “Near-infrared supercontinnum generation in single -mode nonlinear Yb3+-doped fiber amplifier,” Opt. Express. 13, 16130, Jun (2014).
9. J.-H. Lin,* J.-L. Jhu, S.-S. Jyu, T.-C. Lin, and Y. Lai, “Characteristics of low repetition rate passively mode-locked Yb-doped fiber laser in all normal dispersion cavity,”  Laser Phys. 23, 025103 (2013).
10. J.-H. Lin,* D. Wang, and K. H. Lin, “High energy pulses generation with giant spectrum bandwidth and submegahertz repetition rate from a passively mode-locked Yb-doped fiber laser in all normal dispersion cavity,” Laser Phys. Lett. 8, 66-70 (2011).

專利

• "雷射腔體結構",中華民國專利,新型第 M463928 號

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