參考文獻 |
Chapter 1 References
[1] M. Haruta, Size-and support-dependency in the catalysis of gold. Catalysis today. 36(1): p. 153-166, 1997.
[2] M. S. Chen and D. W. Goodman, The structure of catalytically active gold on titania. science. 306(5694): p. 252-255, 2004.
[3] T.-C. Hung, T.-W. Liao, Z.-H. Liao, P.-W. Hsu, P.-Y. Cai, H. Lee, Y.-L. Lai, Y.-J. Hsu, H.-Y. Chen, J.-H. Wang, and M.-F. Luo, Dependence on size of supported Rh nanoclusters in the decomposition of methanol. ACS Catalysis. 5(7): p. 4276-4287, 2015.
[4] A. S. Ansari, Z.-Y. Chern, P.-Y. Cai, Y.-W. Huang, G.-J. Liao, J.-H. Wang, and M.-F. Luo, Distinct dependence on size of Pt and Rh nanoclusters on graphene/Pt (111) in the decomposition of methanol-d4. The Journal of Chemical Physics. 151(22), 2019.
[5] J. Zhou and D. R. Mullins, Rh-promoted methanol decomposition on cerium oxide thin films. The Journal of Physical Chemistry B. 110(32): p. 15994-16002, 2006.
[6] X. Zhou, Q. Shen, K. Yuan, W. Yang, Q. Chen, Z. Geng, J. Zhang, X. Shao, W. Chen, G. Xu, X. Yang, and K. Wu, Unraveling charge state of supported Au single-atoms during CO oxidation. Journal of the American Chemical Society. 140(2): p. 554-557, 2018.
[7] I. X. Green, W. Tang, M. Neurock, and J. T. Yates Jr, Spectroscopic observation of dual catalytic sites during oxidation of CO on a Au/TiO2 catalyst. Science. 333(6043): p. 736-739, 2011.
Chapter 2 References
[1] G. Ertl, Untersuchung von oberflächenreaktionen mittels beugung langsamer elektronen (LEED): I. Wechselwirkung von O_2und N_2 O mit (110)-,(111)-und (100)-Kupfer-Oberflächen. Surface Science. 6(2): p. 208-232, 1967.
[2] B. G. Briner, M. Doering, H.-P. Rust, and A. M. Bradshaw, Mobility and trapping of molecules during oxygen adsorption on Cu(110). Physical review letters. 78(8): p. 1516, 1997.
[3] D. J. Coulman, J. Wintterlin, R. Behm, and G. Ertl, Novel mechanism for the formation of chemisorption phases: The (2×1)O-Cu(110) ‘‘added row’’ reconstruction. Physical review letters. 64(15): p. 1761, 1990.
[4] L. D. Sun, M. Hohage, R. Denk, and P. Zeppenfeld, Oxygen adsorption on Cu(110) at low temperature. Physical Review B. 76(24): p. 245412, 2007.
[5] J. F. Wendelken, The chemisorption of oxygen on Cu(110) studied by EELS and LEED. Surface Science. 108(3): p. 605-616, 1981.
[6] K. Kern, H. Niehus, A. Schatz, P. Zeppenfeld, J. Goerge, and G. Comsa, Long-range spatial self-organization in the adsorbate-induced restructuring of surfaces: Cu{100}-(2×1)O. Physical review letters. 67(7): p. 855, 1991.
[7] F. M. Chua, Y. Kuk, and P. J. Silverman, Oxygen chemisorption on Cu(110): An atomic view by scanning tunneling microscopy. Physical review letters. 63(4): p. 386, 1989.
[8] L. D. Sun, M. Hohage, and P. Zeppenfeld, Oxygen-induced reconstructions of Cu(110) studied by reflectance difference spectroscopy. Physical Review B. 69(4): p. 045407, 2004.
[9] R. Feidenhans’l and I. Stensgaard, Oxygen-adsorption induced reconstruction of Cu(110) studied by high energy ion scattering. Surface science. 133(2-3): p. 453-468, 1983.
[10] F. Jensen, F. Besenbacher, E. Lægsgaard, and I. Stensgaard, Surface reconstruction of Cu(110) induced by oxygen chemisorption. Physical Review B. 41(14): p. 10233, 1990.
[11] Q. Liu, L. Li, N. Cai, W. A. Saidi, and G. Zhou, Oxygen chemisorption-induced surface phase transitions on Cu(110). Surface science. 627: p. 75-84, 2014.
[12] S. Kishimoto, M. Kageshima, Y. Naitoh, Y. J. Li, and Y. Sugawara, Study of oxidized Cu(110) surface using noncontact atomic force microscopy. Surface science. 602(13): p. 2175-2182, 2008.
[13] A. P. Baddorf and J. F. Wendelken, High coverages of oxygen on Cu(110) investigated with XPS, LEED, and HREELS. Surface science. 256(3): p. 264-271, 1991.
[14] K. Moritani, M. Okada, Y. Teraoka, A. Yoshigoe, and T. Kasai, Kinetics of oxygen adsorption and initial oxidation on Cu(110) by hyperthermal oxygen molecular beams. The Journal of Physical Chemistry A. 113(52): p. 15217-15222, 2009.
[15] X. Duan, O. Warschkow, A. Soon, B. Delley, and C. Stampfl, Density functional study of oxygen on Cu(100) and Cu(110) surfaces. Physical Review B. 81(7): p. 075430, 2010.
[16] S. Y. Liem, G. Kresse, and J.H.R. Clarke, First principles calculation of oxygen adsorption and reconstruction of Cu(110) surface. Surface science. 415(1-2): p. 194-211, 1998.
[17] L. Li, Q. Liu, J. Li, W. A. Saidi, and G. Zhou, Kinetic barriers of the phase transition in the oxygen chemisorbed Cu(110)-(2×1)-O as a function of oxygen coverage. The Journal of Physical Chemistry C. 118(36): p. 20858-20866, 2014.
[18] Y. Li, H. Chen, W. Wang, W. Huang, Y. Ning, Q. Liu, Y. Cui, Y. Han, Z. Liu, and F. Yang, and X. Bao, Crystal-plane-dependent redox reaction on Cu surfaces. Nano Research. 13: p. 1677-1685, 2020.
[19] M.-C. Wu and P. J. Møller, Growth of ultrathin Cu layers on Cu_2 O/Cu(110) and CuO/Cu(110): Sandwich electronic and epitaxial structures. Physical Review B. 40(9): p. 6063, 1989.
[20] M. Li, M. T. Curnan, W. A. Saidi, and J. C. Yang, Uneven oxidation and surface reconstructions on stepped Cu(100) and Cu(110). Nano Letters. 22(3): p. 1075-1082, 2022.
[21] R. Feidenhans’l, F. Grey, M. Nielsen, F. Besenbacher, F. Jensen, E. Laegsgaard, I. Stensgaard, K. W. Jacobsen, J. K. Nørskov, and R. L. Johnson, Oxygen chemisorption on Cu(110): A model for the c(6×2) structure. Physical review letters. 65(16): p. 2027, 1990.
[22] X. Zhou, Q. Shen, K. Yuan, W. Yang, Q. Chen, Z. Geng, J. Zhang, X. Shao, W. Chen, G. Xu, X. Yang, and K. Wu, Unraveling charge state of supported Au single-atoms during CO oxidation. Journal of the American Chemical Society. 140(2): p. 554-557, 2018.
[23] J. Zhou, J. Pan, Y. Jin, Z. Peng, Z. Xu, Q. Chen, P. Ren, X. Zhou, and K. Wu, Single-cation catalyst: Ni cation in monolayered CuO for CO oxidation. Journal of the American Chemical Society. 144(19): p. 8430-8433, 2022.
[24] P. Stone, S. Poulston, R. A. Bennett, N. J. Price, and M. Bowker, An STM, TPD and XPS investigation of formic acid adsorption on the oxygen-precovered c(6×2) surface of Cu(110). Surface science. 418(1): p. 71-83, 1998.
[25] T.-C. Hung, T.-W. Liao, Z.-H. Liao, P.-W. Hsu, P.-Y. Cai, H. Lee, Y.-L. Lai, Y.-J. Hsu, H.-Y. Chen, J.-H. Wang, and M.-F. Luo, Dependence on size of supported Rh nanoclusters in the decomposition of methanol. ACS Catalysis. 5(7): p. 4276-4287, 2015.
[26] A. Cavallin, M. Pozzo, C. Africh, A. Baraldi, E. Vesselli, C. Dri, G. Comelli, R. Larciprete, P. Lacovig, S. Lizzit, and D. Alfè, Local electronic structure and density of edge and facet atoms at Rh nanoclusters self-assembled on a graphene template. ACS nano. 6(4): p. 3034-3043, 2012.
[27] M. Haruta, Size-and support-dependency in the catalysis of gold. Catalysis today. 36(1): p. 153-166, 1997.
[28] M. F. Luo, H. W. Shiu, M. H. Ten, S. D. Sartale, C. I. Chiang, Y. C. Lin, and Y. J. Hsu, Growth and electronic properties of Au nanoclusters on thin-film Al_2 O_3/NiAl(100) studied by scanning tunnelling microscopy and photoelectron spectroscopy with synchrotron radiation. Surface science. 602(1): p. 241-248, 2008.
[29] M. S. Chen and D. W. Goodman, The structure of catalytically active gold on titania. science. 306(5694): p. 252-255, 2004.
[30] M. S. Chen and D. W. Goodman, Catalytically active gold on ordered titania supports. Chemical Society Reviews. 37(9): p. 1860-1870, 2008.
[31] M. S. Chen, K. Luo, D. Kumar, W. T. Wallace, C.-W. Yi, K. K. Gath, and D. W. Goodman, The structure of ordered Au films on TiO_x. Surface science. 601(3): p. 632-637, 2007.
[32] R. Nünthel, J. Lindner, P. Poulopoulos, and K. Baberschke, The influence of substrate preoxidation on the growth of Ni on Cu (1 1 0). Surface science. 566: p. 100-104, 2004.
[33] C. Sorg, N. Ponpandian, A. Scherz, H. Wende, R. Nünthel, T. Gleitsmann, and K. Baberschke, The magnetism of ultrathin Ni films grown with O surfactant. Surface science. 565(2-3): p. 197-205, 2004.
Chapter 3 References
[1] 蘇青森等編著,真空技術與應用,行政院國家科學委員會精密儀器發展中心,台灣新竹市,2001。
[2] A. N. Chaika, S. S. Nazin, V. N. Semenov, S. I. Bozhko, O. Lübben, S. A. Krasnikov, K. Radican, and I. V. Shvets, Selecting the tip electron orbital for scanning tunneling microscopy imaging with sub-ångström lateral resolution. Europhysics Letters. 92(4): p. 46003, 2010.
[3] A. C. Phillips, Introduction to quantum mechanics., John Wiley & Sons., 2013.
[4] Y. Kuk and P. J. Silverman, Scanning tunneling microscope instrumentation. Review of scientific instruments. 60(2): p. 165-180, 1989.
[5] R. J. Behm, et al., Scanning tunneling microscopy and related methods., Springer-Verlag, New York, USA, 1990.
[6] P. K. Hansma and J. Tersoff, Scanning tunneling microscopy. Journal of Applied Physics. 61(2): p. R1-R24, 1987.
[7] User’s guide of RHK-UHV 300
[8] S. Hasegawa, Reflection high-energy electron diffraction. Characterization of Materials. 97: p. 1925-1938, 2012.
[9] C. Kittel and P. McEuen, Introduction to solid state physics., John Wiley & Sons., 2018.
[10] J. Chastain and R. C. King Jr, Handbook of X-ray photoelectron spectroscopy., Perkin-Elmer Corporation., 40: p. 221, 1992.
[11] 國家同步輻射研究中心中心簡介,取自https://www.nsrrc.org.tw/chinese/img/pdf/info.pdf。
Chapter 4 References
[1] W. Moritz and D. Wolf, Structure determination of the reconstructed Au (110) surface. Surface Science. 88(2-3): p. L29-L34, 1979.
[2] H. Niehus, Analysis of the Pt (110)-(1× 2) surface reconstruction. Surface Science. 145(2-3): p. 407-418, 1984.
[3] 劉冠辰,The Effect of Au and Rh Nanoclusters on Methanol Decomposition on CuO/Cu(110),國立中央大學,碩士論文,桃園市,民國102年。
[4] L. D. Sun, M. Hohage, R. Denk, and P. Zeppenfeld, Oxygen adsorption on Cu(110) at low temperature. Physical Review B. 76(24): p. 245412, 2007.
[5] D. J. Coulman, J. Wintterlin, R. Behm, and G. Ertl, Novel mechanism for the formation of chemisorption phases: The (2×1)O-Cu(110) ‘‘added row’’ reconstruction. Physical review letters. 64(15): p. 1761, 1990.
[6] J. F. Wendelken, The chemisorption of oxygen on Cu(110) studied by EELS and LEED. Surface Science. 108(3): p. 605-616, 1981.
[7] K. Kern, H. Niehus, A. Schatz, P. Zeppenfeld, J. Goerge, and G. Comsa, Long-range spatial self-organization in the adsorbate-induced restructuring of surfaces: Cu{100}-(2×1)O. Physical review letters. 67(7): p. 855, 1991.
[8] F. M. Chua, Y. Kuk, and P. J. Silverman, Oxygen chemisorption on Cu(110): An atomic view by scanning tunneling microscopy. Physical review letters. 63(4): p. 386, 1989.
[9] L. D. Sun, M. Hohage, and P. Zeppenfeld, Oxygen-induced reconstructions of Cu(110) studied by reflectance difference spectroscopy. Physical Review B. 69(4): p. 045407, 2004.
[10] R. Feidenhans’l and I. Stensgaard, Oxygen-adsorption induced reconstruction of Cu(110) studied by high energy ion scattering. Surface science. 133(2-3): p. 453-468, 1983.
[11] F. Jensen, F. Besenbacher, E. Lægsgaard, and I. Stensgaard, Surface reconstruction of Cu(110) induced by oxygen chemisorption. Physical Review B. 41(14): p. 10233, 1990.
[12] Q. Liu, L. Li, N. Cai, W. A. Saidi, and G. Zhou, Oxygen chemisorption-induced surface phase transitions on Cu(110). Surface science. 627: p. 75-84, 2014.
[13] S. Kishimoto, M. Kageshima, Y. Naitoh, Y. J. Li, and Y. Sugawara, Study of oxidized Cu(110) surface using noncontact atomic force microscopy. Surface science. 602(13): p. 2175-2182, 2008.
[14] A. P. Baddorf and J. F. Wendelken, High coverages of oxygen on Cu(110) investigated with XPS, LEED, and HREELS. Surface science. 256(3): p. 264-271, 1991.
[15] K. Moritani, M. Okada, Y. Teraoka, A. Yoshigoe, and T. Kasai, Kinetics of oxygen adsorption and initial oxidation on Cu(110) by hyperthermal oxygen molecular beams. The Journal of Physical Chemistry A. 113(52): p. 15217-15222, 2009.
[16] X. Duan, O. Warschkow, A. Soon, B. Delley, and C. Stampfl, Density functional study of oxygen on Cu(100) and Cu(110) surfaces. Physical Review B. 81(7): p. 075430, 2010.
[17] S. Y. Liem, G. Kresse, and J.H.R. Clarke, First principles calculation of oxygen adsorption and reconstruction of Cu(110) surface. Surface science. 415(1-2): p. 194-211, 1998.
[18] L. Li, Q. Liu, J. Li, W. A. Saidi, and G. Zhou, Kinetic barriers of the phase transition in the oxygen chemisorbed Cu(110)-(2×1)-O as a function of oxygen coverage. The Journal of Physical Chemistry C. 118(36): p. 20858-20866, 2014.
[19] M. Li, M. T. Curnan, W. A. Saidi, and J. C. Yang, Uneven oxidation and surface reconstructions on stepped Cu(100) and Cu(110). Nano Letters. 22(3): p. 1075-1082, 2022.
[20] Y. Li, H. Chen, W. Wang, W. Huang, Y. Ning, Q. Liu, Y. Cui, Y. Han, Z. Liu, and F. Yang, and X. Bao, Crystal-plane-dependent redox reaction on Cu surfaces. Nano Research. 13: p. 1677-1685, 2020.
[21] M.-C. Wu and P. J. Møller, Growth of ultrathin Cu layers on Cu_2 O/Cu(110) and CuO/Cu(110): Sandwich electronic and epitaxial structures. Physical Review B. 40(9): p. 6063, 1989.
[22] G. Ertl, Untersuchung von oberflächenreaktionen mittels beugung langsamer elektronen (LEED): I. Wechselwirkung von O_2und N_2 O mit (110)-,(111)-und (100)-Kupfer-Oberflächen. Surface Science. 6(2): p. 208-232, 1967.
[23] R. Feidenhans’l, F. Grey, M. Nielsen, F. Besenbacher, F. Jensen, E. Laegsgaard, I. Stensgaard, K. W. Jacobsen, J. K. Nørskov, and R. L. Johnson, Oxygen chemisorption on Cu(110): A model for the c(6×2) structure. Physical review letters. 65(16): p. 2027, 1990.
[24] T.-C. Hung, T.-W. Liao, Z.-H. Liao, P.-W. Hsu, P.-Y. Cai, H. Lee, Y.-L. Lai, Y.-J. Hsu, H.-Y. Chen, J.-H. Wang, and M.-F. Luo, Dependence on size of supported Rh nanoclusters in the decomposition of methanol. ACS Catalysis. 5(7): p. 4276-4287, 2015.
[25] M. Sterrer, T. Risse, U. M. Pozzoni, L. Giordano, M. Heyde, H.-P. Rust, G. Pacchioni, and H.-J. Freund, Control of the charge state of metal atoms on thin MgO films. Physical review letters. 98(9): p. 096107, 2007.
[26] G. Pacchioni, L. Giordano, and M. Baistrocchi, Charging of metal atoms on ultrathin MgO/Mo (100) films. Physical review letters. 94(22): p. 226104, 2005.
[27] R. Nünthel, J. Lindner, P. Poulopoulos, and K. Baberschke, The influence of substrate preoxidation on the growth of Ni on Cu (1 1 0). Surface science. 566: p. 100-104, 2004. |