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林資榕

姓名職稱 林資榕 特聘教授 林資榕
研究室 機械系館A棟314室
電 話 (02) 2462 2192 ext. 3265
傳 真 (02) 2462-9803
E-mail trlin@ntou.edu.tw
研究室資料 微奈米光電與力學實驗室
機械系館A棟210室、418室
(02) 2462 2192 ext. 3236
學 歷 國立臺灣大學應用力學博士, 2006
經 歷 國立臺灣大學 博士後研究員, 2006-2007
美國伊利諾大學香檳校區 博士後研究員, 2007-2009
美國伊利諾大學香檳校區 訪問學者, 200906-200909, 201006-201009
國立臺灣海洋大學機械系暨光電所 助理教授, 2009-2014
國立臺灣海洋大學機械系暨光電所 副教授, 2014-2017
國立臺灣海洋大學機械系暨光電所 教授, 2017--
研究主題 半導體表面電漿子奈米雷射
光機械晶體聲光電交互作用
表面電漿波生物感測器
太陽能光電元件
榮譽獎項 國立臺灣海洋大學教學優良獎 (2013)
國立臺灣海洋大學學術優良獎 (2014, 2018)
美律電聲新銳獎 (2014)
國立臺灣海洋大學學術研究進步獎 (2016, 2018)
國立臺灣海洋大學特聘教授 (2018-- )
重要研究成果 2016年,在半導體表面電漿子奈米雷射的研究上獲得突破性的成果,寫下了世界上最小體積、最高操作溫度的奈米雷射新紀錄。科技部列研究成果為105年度光電工程學門的重要成果。
相關報導:科技部新聞報導
教學課程 研究所:微固體力學、半導體光學、電磁波與光電
大學部:材料力學、奈米材料力學導論、電磁學(一)、電磁學(二)
學術社團 臺灣物理學會(TPS)會員
臺灣奈米生醫學會(TNS)終身會員
中華民國光電學會(TPS)會員
中華民國力學學會(STAM)終身會員
美國電機電子工程師學會(IEEE)會員
美國機械工程師協會(ASME)會員
美國光學學會(OSA)會員
學術研究 研究計畫 │Recent 5-years Publications │ High Cited Publications │ News and Awards

 研究計畫

  1. 高效能的單晶鈣鈦礦表面電漿子奈米雷射之研究,科技部108-109-110 (三年) 年度計畫,MOST 108-2221-E-019-057-MY3。
  2. 散射效應對表面電漿子奈米雷射特性之影響,科技部108-109-110 (三年) 年度計畫,MOST 108-2221-E-019-055-MY3。
  3. 可調式石墨烯電漿光子晶體奈米生物感測器之研究,科技部105-106-107(三年)年度計畫,MOST 105-2221-E-019-049-MY3。
  4. 電漿光聲子晶體奈米雷射之研究,科技部103-104-105(三年)年度計畫,MOST 103-2221-E-019-028-MY3。
  5. 半導體電漿奈米雷射的理論模擬與設計 (II),科技部102年度計畫,NSC 102-2221-E-019-050。
  6. 半導體電漿奈米雷射的理論模擬與設計(I),科技部101年度計畫,NSC 101-2221-E-019-002。

 Recent 5-years Publications

  1. H. Li, J.-H. Li, K.-B. Hong, M.-W. Yu, Y.-C. Chung, C.-Y. Hsu, J.-H. Yang, C.-W. Cheng, Z.-T. Huang, K.-P. Chen, T.-R. Lin, S. Gwo, and T.-C. Lu*, 2019, Optical enhancement of plasmonic nanolasers enabled by hybrid graphene-insulator-metal structures, Nano Letters. (SCI: 2017 IF = 12.080; Rank 9 of 146 (6.16%) in Category: Physics, Applied)
  2. T.-R. Lin, C.-C. Chang, and J.-C. Hsu*, 2019, Strong optomechanical coupling of light and highly confined acoustic phonons in slot dual-beam phoxonic crystal cavities, Journal of Applied Physics, accepted. (SCI: 2017 IF = 2.176; Rank 58 of 146 (39.73%) in Category: Physics, Applied)
  3. Y.-H. Chou, C.-J. Chang, T.-R. Lin, and T.-C. Lu*, 2018, Surface plasmon polariton nanolasers: Coherent light sources for new applications, Chinese Physics B, Vol. 27(11), 114208-1–114208-11. (SCI: 2017 IF = 1.321; Rank 45 of 78 (57.69%) in Category: Physics)
    [http://dx.doi.org/10.1088/1674-1056/27/11/114208]
  4. P.-J. Cheng, Z.-T. Huang, J.-H. Li, B.-T. Chou, Y.-H. Chou, W.-C. Lo, K.-P. Chen, T.-C. Lu, and T.-R. Lin*, 2018, High-performance plasmonic nanolasers with a nanotrench defect cavity for sensing applications, ACS Photonics, Vol. 5(7), 2638-2644. (SCI: 2017 IF = 6.880, Rank 7 of 94 (7.45%) in Category: Optics).
    [http://dx.doi.org/10.1021/acsphotonics.8b00337]
  5. P.-J. Cheng, C.-K. Chiang, B.-T. Chou, Z.-T. Huang, Y.-C. Ku, M.-K. Kuo, J.-C. Hsu, and T.-R. Lin*, 2018, Hybrid photonic-plasmonic crystal nanocavity sensors, Applied Physics A, Vol. 124(2), 113-1–113-8. (SCI: 2017 IF = 1.604; Rank 83 of 146 (56.8%) in Category: Physics, Applied)
    [http://dx.doi.org/10.1007/s00339-017-1504-2]
  6. Y.-H. Chou, K.-B. Hong, C.-T. Chang, T.-C. Chang, Z.-T. Huang, P.-J. Cheng, J.-H. Yang, M.-X. Lin, T.-R. Lin, K.-P. Chen, S. Gwo, and T.-C. Lu*, 2018, Ultracompact pseudowedge plasmonic lasers and laser arrays, Nano Letters, Vol. 18(2), 747–753. (SCI: 2017 IF = 12.080; Rank 9 of 146 (6.16%) in Category: Physics, Applied).
    [http://dx.doi.org/10.1021/acs.nanolett.7b03956]
  7. Y.-H. Chou, K.-B. Hong, Y.-C. Chung, C.-T. Chang, B.-T. Chou, T.-R. Lin, S. M. Arakelian, A. P. Alodjants, and T.-C. Lu*, 2017, Metal for Plasmonic Ultraviolet laser: Al or Ag? , IEEE Journal of Selected Topics in Quantum Electronics, Vol. 23(6), 4601907‑1–4601907‑7. (SCI: 2016 IF = 3.971; Rank 11 of 92 (11.95%) in Category: Optics)
    [http://dx.doi.org/10.1109/JSTQE.2017.2748521]
  8. J.-C. Hsu, J.-H. Shih, and T.-R. Lin*, 2017, Deep-subwavelength plasmonic-photonic hybrid band gap opening by acoustic Lamb waves, Applied Physics Letters, Vol. 111(2), 021904‑1–021904‑5. (SCI: 2016 IF = 3.411; Rank 28 of 147 (19%) in Category: Physics, Applied)
    [http://dx.doi.org/10.1063/1.4993757]
  9. David J.-Y. Feng, Y.-J. Lin, Y.-C. Ku, H.-Y. Jhang, T.-R. Lin*, and M.-K. Kuo*, 2017, GaAsSb spacer effect in quasi-type-II InAs coupled-QDs for intraband absorption enhancement, Optical Materials Express, Vol. 7(4), 1351-1364. (SCI: 2015 IF = 2.657; Rank 19 of 90 (21%) in Category: Optics)
    [http://dx.doi.org/10.1364/OME.7.001351]
  10. Y.-C. Chung, P.-J. Cheng, Y.-H. Chou, B.-T. Chou, K.-B. Hong, J.-H. Shih, S.-D. Lin, T.-C. Lu*, T.-R. Lin*, 2017, Surface roughness effects on aluminium-based ultraviolet plasmonic nanolasers, Scientific Reports, Vol. 7, 39813‑1–39813‑9. (SCI: 2015 IF = 5.228; Rank 7 of 63 (11%) in Category: Multidisciplinary Sciences)
    [http://dx.doi.org/10.1038/srep39813]
  11. C.-H. Lee, S.-C. Liao, T.-R. Lin*, S.-H. Wang*, D.-Y. Lai, P.-K. Chiu, J.-W. Lee, and W.-F. Wu, 2016, Boosted photocatalytic efficiency through plasmonic field confinement with bowtie and diabolo nanostructures under LED irradiation, Optics Express, Vol. 24(16), 17541-17552. (SCI: 2015 IF = 3.148; Rank 14 of 90 (16%) in Category: Optics)
    [http://dx.doi.org/10.1364/OE.24.017541]
  12. Y.-H. Chou, Y.-M. Wu, K.-B. Hong, B.-T. Chou, J.-H. Shih, Y.-C. Chung, P.-Y. Chen, T.-R. Lin, C.-C. Lin, S.-D. Lin, and T.-C. Lu*, 2016, High-operation-temperature plasmonic nanolasers on single-crystalline aluminum, Nano Letters, Vol. 16(5), 3179–3186. (SCI: 2015 IF = 13.779; Rank 8 of 271 (3%) in Category: Materials Sciences, Multidisciplinary)
    [http://dx.doi.org/10.1021/acs.nanolett.6b00537]
  13. B.-T. Chou, Y.-H. Chou, Y.-M. Wu, Y.-C. Chung, W.-J. Hsueh, S.-W Lin, T.-C. Lu, T.-R. Lin, S.-D. Lin*, 2016, Single-crystalline aluminum film for ultraviolet plasmonic nanolasers, Scientific Reports (Nature Publishing Group), Vol. 6, 19887‑1–19887‑9. (SCI: 2014 IF = 5.578; Rank 5 of 56 (9%) in Category: Multidisciplinary Sciences)
    [http://dx.doi.org/10.1038/srep19887]
  14. J.-C. Hsu, T.-Y. Lu, and T.-R. Lin*, 2015, Acousto-optic coupling in phoxonic crystal nanobeam cavities with plasmonic behavior, Optics Express, Vol. 23(20), 25814–25826. (SCI: 2014 IF = 3.488; Rank 9 of 86 (10%) in Category: Optics)
    [http://dx.doi.org/10.1364/OE.23.025814]
  15. T.-R. Lin, C.-H. Lin, and J.-C. Hsu*, 2015, Strong optomechanical interaction in hybrid plasmonic-photonic crystal nanocavities with surface acoustic waves, Scientific Reports (Nature Publishing Group), Vol. 5, 13782‑1–13782‑11. (SCI: 2014 IF = 5.578; Rank 5 of 56 (9%) in Category: Multidisciplinary Sciences)
    [http://dx.doi.org/10.1038/srep13782]
  16. B.-T. Chou, Y.-H. Chou, C.-K. Chiang, Y.-M. Wu, T.-R. Lin, S.-D. Lin, and T.-C. Lu*, 2015, Realization of UV plasmonic nanolasers with extremely small mode volume, IEEE Journal of Selected Topics in Quantum Electronics, Vol. 21(6), 1503106‑1–1503106‑6. (SCI: 2014 IF = 2.828; Rank 25 of 249 (10%) in Category: Engineering, Electrical & Electronic)
    [http://dx.doi.org/10.1109/JSTQE.2015.2448651]
  17. T.-R. Lin, Y.-C. Huang, and J.-C. Hsu*, 2015, Optomechanical coupling in phoxonic-plasmonic slab cavities with periodic metal strips, Journal of Applied Physics, Vol. 117(17), 173105‑1–173105‑9. (SCI: 2014 IF = 2.183; Rank 41 of 143 (29%) in Category: Physics, Applied)
    [http://dx.doi.org/10.1063/1.4919754]
  18. Y.-H. Chou, B.-T. Chou, C.-K. Chiang, Y.-Y. Lai, C.-T. Yang, H. Li, T.-R. Lin, C.-C. Lin, H.-C. Kuo, S.-C. Wang, and T.-C. Lu*, 2015, Ultrastrong mode confinement in ZnO surface plasmon nanolasers, ACS Nano, Vol. 9(4), 3978–3983. (SCI: 2014 IF = 12.881; Rank 10 of 259 (4%) in Category: Materials Science & Multidisciplinary)
    榮獲第十四屆有庠科技論文獎
    [http://dx.doi.org/10.1021/acsnano.5b01643]
  19. P.-J. Cheng, C.-K. Chiang, Y.-C. Chung, C.-H. Tien, and T.-R. Lin*, 2014, Coupled nanowire-based hybrid plasmonic nanocavities on thin substrates, Nanoscale Research Letters, Vol. 9(1), 641‑1–641‑7. (SCI: 2014 IF = 2.779; Rank 24 of 143 (17%) in Category: Physics, Applied)
    [http://dx.doi.org/10.1186/1556-276X-9-641]
  20. J.-C. Hsu, C.-H. Lin, Y.-C. Ku, and T.-R. Lin*, 2013, Photonic band gaps induced by submicron acoustic plate waves in dielectric slab waveguides, Optics Letters, Vol. 38(20), 4050–4053. (SCI: 2014 IF = 3.292; Rank 10 of 86 (12%) in Category: Optics)
    [http://dx.doi.org/10.1364/OL.38.004050
  21. P.-J. Cheng, C.-Y. Weng, S.-W. Chang, T.-R. Lin*, and C.-H. Tien, 2013, Plasmonic gap-mode nanocavities with metallic mirrors in high-index cladding, Optics Express, Vol. 21(11), 13479–13491. (SCI: 2014 IF = 3.488; Rank 9 of 86 (10%) in Category: Optics)
    [http://dx.doi.org/10.1364/OE.21.013479]
  22. P.-J. Cheng, C.-Y. Weng, S.-W. Chang, T.-R. Lin*, and C.-H. Tien, 2013, Cladding effect on hybrid plasmonic nanowire cavity at telecommunication wavelengths, IEEE Journal of Selected Topics in Quantum Electronics, Vol. 19(3), 4800306‑1–4800306‑6. (SCI: 2014 IF = 2.828; Rank 25 of 249 (10%) in Category: Engineering, Electrical & Electronic)
    [http://dx.doi.org/10.1109/JSTQE.2012.2231404
  23. T.-R. Lin, C.-H. Lin, and J.-C. Hsu*, 2013, Enhanced acousto-optic interaction in two-dimensional phoxonic crystals with a line defect, Journal of Applied Physics, Vol. 113(5), 053508‑1–053508‑8. (SCI: 2014 IF = 2.183; Rank 41 of 143 (29%) in Category: Physics, Applied)
    [http://dx.doi.org/10.1063/1.4790288]

 High Cited Publications (Max Times 10 based on Google Scholar by 2018/11)

  1. S.-W. Chang, T.-R. Lin, and S. L. Chuang*, 2010, Theory of plasmonic Fabry-Perot nanolasers, Optics Express, Vol. 18(14), 15039–15053. (Times Cited: 70)
  2. T.-R. Lin, S.-W. Chang, S. L. Chuang*, Z. Zhang, and P. J. Schuck, 2010, Coating effect on optical resonance of plasmonic nanobowtie antennas, Applied Physics Letters, Vol. 97(6), 063106‑1–063106‑3. (Times Cited: 40)
  3. Y.-H. Chou, B.-T. Chou, C.-K. Chiang, Y.-Y. Lai, C.-T. Yang, H. Li, T.-R. Lin, C.-C. Lin, H.-C. Kuo, S.-C. Wang, and T.-C. Lu*, 2015, Ultrastrong mode confinement in ZnO surface plasmon nanolasers, ACS Nano, Vol. 9(4), 3978–3983. (Times Cited: 40)
  4. T.-R. Lin, C.-H. Lin, and J.-C. Hsu*, 2013, Enhanced acousto-optic interaction in two-dimensional phoxonic crystals with a line defect, Journal of Applied Physics, Vol. 113(5), 053508‑1–053508‑8. (Times Cited: 33)
  5. Y.-H. Chou, Y.-M. Wu, K.-B. Hong, B.-T. Chou, J.-H. Shih, Y.-C. Chung, P.-Y. Chen, T.-R. Lin, C.-C. Lin, S.-D. Lin, and T.-C. Lu*, 2016, High-operation-temperature plasmonic nanolasers on single-crystalline aluminum, Nano Letters, Vol. 16(5), 3179–3186. (Times Cited: 32)
  6. M.-K. Kuo*, T.-R. Lin, P.-L. Liu, and T.-T. Wu, 1998, Locating the crack-tip of a surface-breaking crack. Part I. line crack, Ultrasonics, Vol. 36, 803–811. (Times Cited: 30)
  7. B.-T. Chou, Y.-H. Chou, Y.-M. Wu, Y.-C. Chung, W.-J. Hsueh, S.-W Lin, T.-C. Lu, T.-R. Lin, S.-D. Lin*, 2016, Single-crystalline aluminum film for ultraviolet plasmonic nanolasers, Scientific Reports, Vol. 6, 19887‑1–19887‑9. (Times Cited: 24)
  8. M.-K. Kuo*, T.-R. Lin, K.-B. Hong, B.-T. Liao, H.-T. Lee, and C.-H. Yu, 2006, Two-step strain analysis of self-assembled InAs/GaAs quantum dots, Semiconductor Science and Technology, Vol. 21, 626–632. (Times Cited: 23)
  9. M.-K. Kuo*, T.-R. Lin, B.-T. Liao, and C.-H. Yu, 2005, Strain effects on optical properties of pyramidal InAs/GaAs quantum dots, Physica E-Low-Dimensional Systems & Nanostructures, Vol. 26, 199–202. (Times Cited: 16)
  10. T.-R. Lin, C.-H. Lin, and J.-C. Hsu*, 2015, Strong optomechanical interaction in hybrid plasmonic-photonic crystal nanocavities with surface acoustic waves, Scientific Reports (Nature Publishing Group), Vol. 5, 13782‑1–13782‑11. (Times Cited: 15)
  11. P.-J. Cheng, C.-Y. Weng, S.-W. Chang, T.-R. Lin*, and C.-H. Tien, 2013, Plasmonic gap-mode nanocavities with metallic mirrors in high-index cladding, Optics Express, Vol. 21(11), 13479–13491. (Times Cited: 11)

 News and Awards

  1. 全國力學會議論文獎 (2009, 2013, 2014)
  2. 臺灣光電國際年會論文獎 (2012, 2013, 2016)
  3. 臺灣物理年會論文獎 (2014)
  4. 臺灣化工學會年會論文獎 (2014)
  5. 美律電聲論文獎 (2014)
  6. 中華民國光電學會碩士論文獎 (2014, 2018)
  7. 臺灣物理學會研究生優良論文獎 (2014)
  8. 臺灣物理學會大專生優良論文獎 (2015, 2016, 2018) 
  9. 有庠科技論文獎 (2016)
  10. 中華民國微系統暨奈米科技協會論文獎 (2016)
  11. 國際表面電漿光子學研討會論文獎 (2017)
  12. 國際智慧感測器研討會論文獎 (2018)
  13. 國際微光學研討會論文獎 (2018)