当前位置: X-MOL首页全球导师 国内导师 › 唐述中

个人简介

學歷 1.美國田納西大學納克斯維爾校區博士(1995/09~2002/12) 2.私立淡江大學物理系學士 (1989/09-1993/06) 現職與經歷 現職:國立清華大學物理系教授(2014/08-) 經歷 : 國立清華大學物理系副教授(2010/08-2014/07) 國立清華大學物理系助理教授 (2006/08- 2010/07) 美國伊利諾大學香檳分校博士後研究(2003/03- 2006/07) 榮譽與獎項: 2011 清華大學新進人員研究獎。 研究興趣與成果 Updated on September 3, 2006 我在博士階段時,有對幾個不同的金屬表面及薄膜系統做過研究。其中,我最致力的是對Be 表面電子與聲子偶合的研究,鈹(Beryllium)是一個非常有趣的金屬,因為它是一個半金屬且在整個brillouin zone裏有一個很大的energy gap,然而其晶體表面卻展現自由電子的性質,並存在著非常局部的表面電子態,這些局部的表面電子態的行為跟在鈹晶體面的電子態完全不一樣。在鈹的表面,電子和聲子偶合的力量是在晶體裏面偶合力量的三倍。從表面態的光電子能譜,我成功的經由自我能量的虛部對溫度的變化及自我能量實部對能量的變化來取得與表面電子態偶合最主要的聲子態密度結構。我現在進一步想走的方向為研究表面電子態與晶體表面的晶格行為(如表面舒張及表面熱量伸縮)互相間之關係。 在我做博士後研究時,我主要是研究在半導體基底上金屬薄膜(如Ag/Ge(111))的量子井態。薄膜一直是很廣泛地應用在元件設計上。例如,如果薄膜是磁性材料所做成,量子井態就很密切地與磁性薄膜的重要性質,如:oscillatory magnetic coopling及Giant Magnetoresistare(GMR)相關連。而這兩種重要的磁性性質都已應用在硬碟的資料儲存元件上。我在Ag/Ge(111)系統上的研究有兩個重要的發現。 一、在某種特定蒸鍍及加熱條件下,有原子精確度的二維平整Ag薄膜可長在Ge(111)的基底上。 二、基底可強烈的改變薄膜的電子結構。 這兩種發現當然是非常重要,且有可能導致一些特定在應用上重要的薄膜性質大輻提昇。我主要使用的實驗技術為光電子能譜。它是用來偵測電子能帶結構及行為的最好工具。我目前和台灣同步輻射中心(NSRRC)合作來從事光電子能譜的實驗。在未來我還計劃使用低能量電子顯微鏡(LEEM)來研究表面的形態演變及薄膜的生長。 目前並與日本千葉大學的教授石井久夫合作研究有機薄膜在金屬上的介面態及分子軌域態。目標是在原子精確度的二維平整金屬薄膜上長出有晶格序列的有機薄膜。

研究领域

1.實驗表面物理 2.光電子能譜 3.低能量電子顯微鏡 4.金屬表面,金屬薄膜及有機薄膜的電子結構

近期论文

查看导师新发文章 (温馨提示:请注意重名现象,建议点开原文通过作者单位确认)

1.Surface-state Coulomb repulsion accelerates a metal-insulator transition in topological semimetal nanofilms, S. Ito,M. Arita, J. Haruyama, B. Feng, W.-C. Chen, H. Namatame, M. Taniguchi, C.-M. Cheng, G. Bian, S.-J. Tang, T.-C. Chiang, O. Sugino, F. Komori and I. Matsuda, Sci. Adv. 6, eaaz5015 (2020). 2.Using irradiation effect to study the disparate anchoring stabilities of polarorganic molecules adsorbed on bulk and thin-film metal surfaces, Kowsalya Arumugama, Hong-Ming Chena, Jing-Huan Daia, Mau-Fu Gaoa, Abhishake Goyala, Meng-Kai Lin, Yasuo Nakayama, Tun-Wen Pi, Sebastian Metz, Theodoros A. Papadopoulos, Horng-Tay Jenga, S.-J. Tang*, Appl. Surf. Sci. 493 (2019) 1090–1097 3. Substrate-mediated umklapp scattering at the incommensurate interface of a monatomic alloy layer, Santosh Chiniwar, Angus Huang, Ting-Yu Chen, Chung-Huang Lin, Cheng-Rong Hsing, Wei-Chuan Chen, Cheng-Maw Cheng, H.-T. Jeng, C. M. Wei, Woei Wu Pai, and S.-J. Tang Phys. Rev. B 99, 155408 (2019) 4.Monatomic Two-Dimensional Layers: Modern Experimental Approaches for Structure, Properties, and Industrial Use (Micro and Nano Technologies), S.-J. Tang*, I. Matsuda#, Book chapter 3: Interplay of two dimensional lattices of atomic layers at the junction,1st Edition, Elsevier (2018) 5.Alkali-metal induced band structure deformation investigated by angle-resolved photoemission spectroscopy and first-principles calculations S. Ito, B. Feng, M. Arita, T. Someya, W.-C. Chen, A. Takayama, T. Iimori, H. Namatame, M. Taniguchi, C.-M. Cheng, S.-J. Tang, F. Komori, and I. Matsuda, Phys. Rev. B 97 155423 (2018) 6.Single-layer Dual Germanene Phases on Ag(111), Chung-Huang Lin, Angus Huang, Woei Wu Pai, Wei-Chuang Chen, Tay-Rong Chang, Ryu Yukawa, Cheng-Maw Cheng, H -T Jeng*, Chung-Yu Mou, Iwao Matsuda, T.-C. Chiang, S. -J. Tang*, Phys. Rev. Materials 2, 024003 (2018). 7.Control of the dipole layer of polar organic molecules on metal surfaces via different charge-transfer channels, Meng-Kai Lin, Yasuo Nakayama, Ying-Jie Zhuang, Kai-Jun Su, Chin-Yung Wang, Tun-Wen Pi, Sebastian Metz, Theodoros A. Papadopoulos,T. -C. Chiang, Hisao Ishii, and S.-J. Tang*, Phys. Rev. B 95, 085425 (2017) 8. Proving Nontrivial Topology of: Pure Bismuth by Quantum Confinements. S.Ito, B. Feng, M. Arita, A. Takayama, R. -Y. Liu, T. Someya, W. -C. Chen, T. Iimori, H. Namatame, M. Taniguchi, C. -M. Cheng, S. -J. Tang, F. Komori, K. Kobayashi,T. -C. Chiang, and I. Matsuda, Phys. Rev. Lett, 117, 236402 (2016), Editor’s suggestion and highlighted by Nature physics. http://www.nature.com/nphys/journal/v13/n1/full/nphys4014.html 9. Deeper insight into phase relations in ultrathin Pb films, Ro-Ya Liu, Angus Huang, Chien-Chung Huang, Chang-Yeh Lee, Chung-Huang Lin, Cheng-Maw Cheng, Ku-Ding Tsuei, Horng-Tay Jeng, Iwao Matsuda, and S.-J. Tang*, Phys. Rev. B 92, 115415 (2015) 10.Significantly enhanced giant Rashba splitting in a thin film of binary alloy, Wei-Chuan Chen, Tay-Rong Chang, Sun-Ting Tsai, S Yamamoto, Je-Ming Kuo, Cheng-Maw Cheng, Ku-Ding Tsuei, Koichiro Yaji, Hsin Lin, H-T Jeng, Chung- Yu Mou, Iwao Matsuda and S.-J. Tang*, New J. Phys. 17, 083015 (2015). 11.Rashba effects within the space charge layer of a semiconductor, Chung-Huang Lin, Tay-Rong Chang, Ro.-Ya. Liu, Cheng-Maw Cheng, Ku-Ding Tsuei, H.-T. Jeng, Chung-Yu Mou, Iwao Matsuda, S.-J. Tang*, New J. Phys.16 (2014) 045003 (Focus issue on the Rashba effect). 12. Non-linear kinetic model for oscillatory relaxation of the photovoltage effect on a Si(111)7×7 surface, M. Ogawa, R.-Y. Liu, C.-H. Lin, S. Yamamoto, R.Yukawa, R. Hobara, S.-J. Tang, and I. Matsuda, Surf. Sci., 624, (2014), 70-75. (Impact factor: 1.838) 13.Tuning gap states at organic-metal interface by quantum size effects, Meng-Kai Lin, Yasuo Nakayama, Chin-Hung Chen, Chin-Yung Wang, Shin-ichi Machida, H.-T. Jeng, Tun-Wen Pi, Hisao Ishii, S.-J. Tang*, Nature Communications 4, 2925 (2013). 14.Relaxations of the surface photovoltage effect on the atomically controlled semiconductor surfaces studied by time-resolved photoemission spectroscopy, M. Ogawa, S. Yamamoto, K. Fujikawa, R. Hobara, R. Yukawa, Sh. Yamamoto, S. Kitagawa, D. Pierucci, M. G. Silly, C.-H. Lin, R.-Y. Liu, H. Daimon, F. Sirotti, S.-J. Tang, and I. Matsuda, Phys. Rev. B 88, 165313 (2013) 15.Oscillatory relaxation of surface photovoltage on a silicon surface, M. Ogawa, S. Yamamoto, R. Yukawa, R. Hobara, C.-H. Lin, R.-Y. Liu, S.-J. Tang, and I. Matsuda, Phys. Rev. B 87, 235308 (2013) 16.Controlling the Topology of Fermi Surfaces in Metal Nanofilms, M. Ogawa, A. Gray, P. M. Sheverdyaeva, P. Moras, H. Hong, L.-C. Huang, S.-J. Tang, K. Kobayashi, C. Carbone, T.-C. Chiang, and I. Matsuda, Phys. Rev. Lett. 109, 026802 (2012). 17.Interfacial properties at the organic-metal interface probed using quantum-well states, Meng-Kai Lin,Yasuo Nakayama, Chin-Youg Wang, Che-Chia Hsu, Shinichi Machida , Tun-Wen Pi, Hisao Ishii, S. -J. Tang*, Phys. Rev. B 86, 155453 (2012). 18. Experimental Determination of Electron Affinities for InN and GaN Polar Surfaces, Shih-Chieh Lin, Cheng-Tai Kuo, Xiaoge Liu, Li-Yen Liang, Ching- Hung Cheng, Chung-Huang Lin, Shu-Jung Tang, Lo-Yueh Chan, Chia-Hao Chen, and Shangjr Gwo, Applied Physics Express 5, 031003(2012). 19.Interface Electronic Structure of Zinc-Phthalocyanine on the Silver Thin-Film Quantum-Well, Yasuo Nakayama, Meng-Kai Lin and Chin-Yung Wang, Tun- Wen Pi, Hisao Ishii, and S.-J. Tang, e-J. Surf. Sci. Nanotech. 10, 149-152, (2012). 20.Consonant diminution of lattice and electronic coupling between a film and a substrate: Pb on Ge(100), Pei-Wen Chen, Yu-Hsuan Lu, Chi-Bin Wang, Tay- Rong Chang, Cheng-Maw Cheng, Ku-Ding Tsuei, H.-T. Jeng, S. -J. Tang*, Phys. Rev. B. 84, 205401 (2011). 21.Electronic versus Lattice Match for Metal-Semiconductor Epitaxial Growth: Pb on Ge(111), S. -J. Tang*, Chang-Yeh Lee, Chien-Chung Huang, Tay-Rong Chang, Cheng-Maw Cheng, Ku-Ding Tsuei, H.-T. Jeng,V. Yeh, and Tai-Chang Chiang, Phys. Rev. Lett., 107, 066802 (2011). 22.Is electron accumulation universal at InN polar surfaces? Cheng-Tai Kuo (郭承 泰), Shih-Chieh Lin (林詩傑)1, Kai-Kuen Chang (張凱焜), Hung-Wei Shiu (許 紘瑋), Lo-Yueh Chang (張羅嶽), Chia-Hao Chen (陳家浩), Shu-Jung Tang (唐述中), and Shangjr Gwo (果尚志), Appl. Phys. Lett. 98, 052101 (2011). 23.Interface electronic structures of 2-amino-4,5-imidazoledicarbonitrile on Ag and Al surfaces, Yasuo Nakayama, Yen-Hao Huang, Ching-Hsuan Wei, Shinichi Machida, Takuya Kubo, Tun-Wen Pi, S. -J. Tang, Yutaka Noguchi, and Hisao Ishii, J. Appl. Phys. 108, 053702 (2010). (Impact factor 2.072) 24.Photoemission study on the electronic structures of 2-amino-4,5- imidazoledicarbonitrile (AIDCN)-metal interfaces as a model of an organic nonvolatile memory device, Yasuo Nakayama, Yen-Hao Huang, Ching-Hsuan Wei, Takuya Kubo, Shinichi Machida, Tun-Wen Pi, Shu-Jung Tang, Yutaka Noguchi, and Hisao Ishii, J. Surf. Sci. Soc. Jpn. 31(9), 434-440 (2010). 25.Dispersive resonance bands within the space charge layer of metal- semiconductor junction, S. -J. Tang*, T. -R. Chang, Chien-Chung Huang, Chang-Yeh Lee, Cheng-Maw Cheng, Ku-Ding Tsuei, H. -T. Jeng, Chung-Yu Mou, Phys. Rev. B. 81, 245406 (2010). (Impact factor 3.322) 26.Bilayer oscillation of subband effective masses in Pb/Ge(111) thin-film quantum wells, S. -J. Tang*, Chang-Yeh Lee, Chien-Chung Huang, Tay- Rong Chang, Cheng-Maw Cheng, Ku-Ding Tsuei, and H. -T. Jeng, Appl. Phys. Lett. 96, 103106 (2010). (citations: 7) (Impact factor 3.726) 27.Surface electronic band structure and temperature dependence of the surface state at A bar on Mg(1010) surface, S. -J. Tang*, H.-T. Jeng, Ismail, P. T. Sprunger, and E. W. Plummer, Phys. Rev. B 80, 085419 (2009). (citations: 3) (Impact factor 3.322) 28.Interface-induced complex electronic interference structures in Ag films on Ge(111), Y. Liu, N. J. Speer, S.-J. Tang, T. Miller, and T.-C. Chiang, Phys. Rev. B 78, 035443 (2008). (citations: 10) (Impact factor 3.322) 29.Enhancement of subband effective mass in Ag/Ge(111) thin film quantum wells, S.-J. Tang*, Wen-Kai Chang, Yu-Mei Chiu, Hsin-Yi Chen, Cheng-Maw Cheng, Ku-Ding Tsuei, T. Miller, and T.-C. Chiang, Phys. Rev. B 78, 245407 (2008). (citations: 25) (Impact factor 3.322) 30.Surface state influence on the surface lattice structure in Be (10 1 0) , S. -J. Tang*, H.-T. Jeng, Chen-Shiung Hsue, Ismail, P.T. Sprunger, and E. W. Plummer, Phys. Rev. B 77, 045405 (2008). (citations: 3) (Impact factor 3.322) 31.Coherent Electronic Fringe Structure in Incommensurate Silver-SiliconQuantum Wells, N. J. Speer, S.-J. Tang, T. Miller, T.-C. Chiang, Science, 314, 804 (2006). (citations: 24) (Impact factor: 30.028) 32.Umklapp-mediated Quantization of Electronic States in Ag Films on Ge(111), S.-J. Tang*, Y. R. Lee, S. -L. Chang, T. Miller, and T. -C. Chiang, Phys. Rev. Lett. 96, 216803 (2006). Selected for the Virtual Journal of Nanoscale Science & Technology 13 (23) 2006. (citations: 16) (Impact factor: 7.180) 33.Sublimation of Atomic Layers from a Chromium Surface, S. -J. Tang*, S. Kodambaka, W. Swiech, I. Petrov, T. -C. Chiang, Phys. Rev. Lett. 96, 126106 (2006). (citations: 8 ) (Impact factor: 7.180) 34.Modification of Surface States in Ultrathin Films via Hybridization with the Substrate – a Study of Ag on Ge, S. -J. Tang*, T. Miller, and T.-C. Chiang, Phys. Rev. Lett. 96, 036802 (2006). Selected for the Virtual Journal of Nanoscale Science & Technology 13 (5) 2006.(citations: 25) (Impact factor:7.180) 35.Breakup of Quasiparticles in Thin-Film Quantum Wells, S. -J. Tang*, L. Basile, T. Miller, and T.-C. Chiang, Phys. Rev. Lett. 93, 216804 (2004). Selected for the Virtual Journal of Nanoscale Science & Technology 10 (22) 2004. (citations:26) (Impact factor: 7.180) 36.A spectroscopic view of electron phonon coupling at metal surfaces, S. -J. Tang, Junren Shih, B. Wu, et al, Physica Status Solidi (b), 241, 2345 (2004). (citations: 4 ) (Impact factor: 0.873) 37.Direct extraction of the Eliashberg function for electron-phonon coupling: A case study of Be (10 1 0) . Junren Shih, S.-J. Tang, B. Wu, et al, Phys Rev Lett. 92, 186401 (2004) (citations: 37) (Impact factor: 7.180) 38.Enhanced electron-phonon coupling at metal surfaces. E.W. Plummer, Junren Shih, S. -J. Tang, et al. Progress in Surface Science, 74, 251-268, (2003). (citations: 19) (Impact factor: 5.592) 39.The investigation of the growth and thin film morphological structure of Be on Si(111)-(7 x 7) by STM and UPS. D. A. Hite, S.-J. Tang , P. T. Sprunger, Chemical physics letters, 367, (2003), 129-135. (citations: 3) (Impact factor: 2.341) 40.The electron phonon coupling and the temperature dependent initial energy shifts of the surface states on Be (10 1 0) , S. -J. Tang, Ismail, P. T. Sprunger, E. W. Plummer, Phys Rev B 65, 235428 (2002). (citations: 33) (Impact factor: 3.322) 41.Electronic structure of a surface quantum-wire array, K. Yoo, S. J. Tang, P. T Sprunger, I. Benito, J. Ortega, F. Flores, P.C. Snijders, M.C. Demeter, H.H. Weitering, Surf. Sci. 514, (2002), 100-107. (citations: 3) (Impact factor: 1.731) 42.Photoemission band symmetries and dipole active modes of crystalline film of vinyidene fluoride(70%) with trifluoroethylene(30%) across the ferroelectric transitions, Jaewu Choi, S. -J. Tang, P.T Sprunger, P.A Dowben , J. Phys.Condens. Matter 12, (2000), 4735. (citations: 20) (Impact factor: 1.900) 43.Electronic Structure and Molecular Orientation of Well-ordered Polyethylene Oligomer (n-C44H90) on Cu(100) and Au(111) Surfaces Studied by UV Photoemission and Low Energy Electron Diffraction, H. Ishii, E. Morikawa, S. J. Tang, et al, Journal of Electron Spectroscopy and related Phenomena, 101-103, (1999), 559-564. (citations: 16) (Impact factor: 1.076)

推荐链接
down
wechat
bug