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永續科技碩士學位學程
Sustainable Technology Master Program

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林建宏教授

林建宏教授

林建宏 教授 兼 主任

學術專長
奈米碳材料、觸媒設計及催化反應、儲能碳材料、生質廢棄物材料高值化再利用、 超電容、鈉電池、二氧化碳捕捉再利用(CCU)、生質氫能

林建宏教授為國立中山大學化學博士,也是本學院永續科技學位學程主任,在過去近30年間, 曾服務於業界—台灣中橡公司研發部共11年,負責新型態奈米碳材料的開發, 並與法國米其林輪胎公司共同研發低滾阻節能輪胎。

林教授亦開發出獨步全球的熱裂解氣相層析質譜法(Pyrolysis GC-MS), 成功被國內輪胎產業導入應用。其後轉任國立臺南大學材料科學系, 發展非傳統銅觸媒製備奈米碳管,突破既有成長機制。

近年投入儲能電池與超級電容材料研究,以咖啡渣、木屑、稻殼、廢塑膠等 生質與環境廢棄物為原料,衍生高效能碳材料, 儲能容量可提升約3–5倍,具高度商業化潛力。

近年並以二氧化碳為原料,轉化為天然氣與奈米碳材料, 成立 CCU(二氧化碳捕捉再利用)研究團隊, 推動新世代儲能技術發展。

林教授投入碳材料領域逾30年,主持多項國家型計畫, 並於2017年發起成立「臺灣碳材料學會」, 2023年籌辦首屆國際碳材料學術研討會, 為國內碳材料研究的重要推手。

期刊論文(僅列重要著作)
  1. J. H. Lin* "Identification of the surface characteristics of carbon blacks by pyrolysis GC–MASS" Carbon 2002, 40, 183-187.
  2. C. S. Chen*, J. H. Lin, J. H. You and C. R. Chen " Properties of Cu(thd)2 as a Precursor to Prepare Cu/SiO2 Catalyst Using the Atomic Layer Epitaxy Technique" J. Am. Chem. Soc. 2006, 128, 15950-15951.
  3. J. H. Lin*, C. S. Chen, H. L. Ma, C. Y. Hsu and H. W. Chen “Synthesis of MWCNTs on CuSO4/Al2O3 using chemical vapor deposition from methane” Carbon 2007, 45(1), 223-225.
  4. C.S. Chen*, J. H. Lin, S. J. Lin, H. T. Huang and H. L. Ma " Synthesis of Carbon Nanofibers from CO2 on Ni-K/Al2O3 catalysts" Carbon 2008, 46, 369-317.
  5. J. H. Lin*, Nanoscale, 2010, 2, 2835–2840.
  6. J. H. Lin*, C. S. Chen, H. L. Ma, C. Y. Hsu and H. W. Chen "Self-Assembly of multi-walled carbon nanotubes on a porous carbon surface by catalyst-free chemical vapor deposition" Carbon 2008, 46, 1619-1623.
  7. C. S. Chen*, J. H. Lin, J. H. You and K. H. Yang "The effects of potassium on Ni-K/Al2O3 catalysts in the synthesis of carbon nanofibers by catalytic hydrogenation of CO2". J. Phys. Chem. A. 2010, 114, 3773-3781.
  8. M. H. Rümmeli, A. Bachmatiuk, A. Scott, F. Börrnert, J. H. Warner,V. Hoffmann, J. H. Lin, G. Cuniberti, B. Büchner "Low temperature graphene via non-metal catalytic chemical vapor deposition" ACS Nano 2010, 4(7), 4206-4210.
  9. J. H. Lin*, C. S. Chen, M. H. Rümmeli and Z. Y. Zeng "Self-assembly of multi-walled carbon nanotubes on gold surfaces" Nanoscale 2010, 2(12), 2835-2840.
  10. J. H. Lin*, C. S. Chen, Z. Y. Zeng, H. L. Ma and H. W. Chen "The growth of carbon nanotubes on defect-rich graphite surfaces" Chem. Mater. 2011, 23, 1637-1639.
  11. J. H. Lin*, C. S. Chen, Z. Y. Zeng, C. W. Chang and H. W. Chen "Sulfate-activated growth of bamboo-like carbon nanotubes over copper catalysts" Nanoscale 2012, 4, 4757-4764.
  12. H. C. Wu, Y. C. Chang, J. H. Wu, J. H. Lin, I. K. Lin and C. S. Chen "Methanation of CO2 and reverse water gas shift reactions on Ni/SiO2 catalysts: the influence of particle size on selectivity and reaction pathway" Catal. Sci. Technol. 2015, 5, 4154-416.
  13. J. H. Lin* and S. B. Wang “An effective route to transform scrap tire carbons into highly-pure activated carbons with a high adsorption capacity of ethylene blue through thermal and chemical treatments” Environ. Technol. Inno. 2017, 8, 17-27.
  14. C. H. Hsiao and J. H. Lin* "Growth of a Superhydrophobic Multi-walled Carbon Nanotube Forest on quartz Using Flow-vapor-Deposited Copper Catalysts" Carbon 2017, 124, 637-641.
  15. M. D. Liao, C. Peng, S. P. Hou, J. Chen*, X. G. Zeng, H. L. Wang, J. H. Lin* "Large-scale synthesis of nitrogen-doped activated carbon fibers with high specific surface area for high-performance supercapacitors" Energy Technol. 2020, 8, 1901477.
  16. C.-H. Chiang, J. Chen, J. H. Lin* "Preparation of pore-size tunable activated carbon derived from waste coffee grounds for high adsorption capacities of organic dyes" J. Environ. Chem. Eng. 2020, 8(4), 103929.
  17. C. Peng, M. D. Liao, X. L. Lv, L. Chen, S. P. Hou, D. Min, J. Chen*, H. L. Wang and J. H. Lin* "Large-scale synthesis of highly structural-connecting carbon nanospheres as an anodes material for lithium-ion batteries with high-rate capacity" Chem. Eng. J.-Adv. 2020, 2, 100014.
  18. T. H. Hsieh, H. L. Wang, G. T. Yu, G. M. Huang, J. H. Lin* "Meso-pore dominant activated carbon from spent coffee grounds for high- performance electrochemical capacitors in organic electrolyte", J. Environ. Chem. Eng. 2021, 9, 106418.
  19. J. H. Lin* and C. Y. Chen "Thickness-controllable coating on graphite surface as anode materials using glucose-based suspending solutions for Lithium-ion Battery" Surf. Coating Technol. 2022, 436, 128270.
  20. G. T. Yu, T. H. Hsieh,* Y.- H. Lin, J. H. Lin* " Porous Carbon Nanosheets Derived from Spent Coffee Grounds for Highly Stable Electric Double-Layer Capacitors Enabled by Structurally Complementary Carbons", ACS Sustainable Resour. Manage. 2024, 1, 76-87.
  21. T. H. Hsieh, T. J. Chang, Y.- H. Lin, J. H. Lin* “One-step generation of hollow graphitic carbon nanospheres with suitable oxygenated structures as conductive additives for water-soluble binder in highly stable supercapacitor electrodes” Electrochimica Acta 2024, 483, 144050.
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