( ) S. Link, M. B. Mohamed, and M. A. El-Sayed, “Simulation of the Optical Absorption Spectra of Gold Nanorods as a Function of Their Aspect Ratio and the Effect of the Medium
Dielectric Constant,” J. Phys. Chem. B, vol. , no. , pp. – , Apr. .
(2) H. Chen, L. Shao, Q. Li, and J. Wang, “Gold nanorods and their plasmonic properties,” Chem.
Soc. Rev., vol. , no. , pp. – , Apr. .
(3) X. Huang and M. A. El-Sayed, “Gold nanoparticles: Optical properties and implementations in cancer diagnosis and photothermal therapy,” J. Adv. Res., vol. , no. , pp. – , . (4) G. Baffou, R. Quidant, and C. Girard, “Heat generation in plasmonic nanostructures:
Influence of morphology,” Appl. Phys. Lett., vol. 94, no. 15, p. 153109, Apr. 2009.
( ) G. Baffou and R. Quidant, “Thermo-plasmonics: using metallic nanostructures as nano-sources of heat,” Laser Photon. Rev., vol. , no. , pp. – , Mar. .
( ) S. Link et al., “Laser-Induced Shape Changes of Colloidal Gold Nanorods Using Femtosecond and Nanosecond Laser Pulses,” J. Phys. Chem. B, vol. , no. , pp. – , Jul. . (7) Y. Horiguchi, K. Honda, Y. Kato, N. Nakashima, and Y. Niidome, “Photothermal Reshaping of Gold Nanorods Depends on the Passivating Layers of the Nanorod Surfaces,” Langmuir, vol. , no. , pp. – , Oct. .
( ) G. González-Rubio et al., “Femtosecond laser reshaping yields gold nanorods with
ultranarrow surface plasmon resonances,” Science (80-. )., vol. , no. , pp. – , Nov. .
( ) Z. L. Wang, M. B. Mohamed, S. Link, and M. A. El-Sayed, “Crystallographic facets and shapes of gold nanorods of different aspect ratios,” Surf. Sci., vol. , no. – , pp. L – L , Oct. .
( ) N. Sumimoto, K. Nakao, T. Yamamoto, K. Yasuda, S. Matsumura, and Y. Niidome, “In situ observation of structural transformation of gold nanorods under pulsed laser irradiation in an HVEM,” Microscopy, vol. , no. , pp. – , Aug. .
(11) Y. Gan and S. Jiang, “Ultrafast laser-induced premelting and structural transformation of gold nanorod,” J. Appl. Phys., vol. 113, no. 7, p. 073507, 2013.
(12) Y. Wang and C. Dellago, “Structural and Morphological Transitions in Gold Nanorods: A Computer Simulation Study,” J. Phys. Chem. B, vol. , no. , pp. – , Sep. 2003.
(13) G. Opletal, G. Grochola, Y. H. Chui, I. K. Snook, and S. P. Russo, “Stability and
Transformations of Heated Gold Nanorods,” J. Phys. Chem. C, vol. , no. , pp. – , Mar. .
(14) Y. Wang, S. Teitel, and C. Dellago, “Surface-Driven Bulk Reorganization of Gold Nanorods,”
Nano Lett., vol. , no. , pp. – , Nov. .
(15) X. Ben and H. S. Park, “Strain engineering enhancement of surface plasmon polariton propagation lengths for gold nanowires,” Appl. Phys. Lett., vol. , no. , p. , Jan.
.
(16) “YAMAKIN株式会社 本⽇の地⾦相場 (2019年12⽉20⽇).” [Online]. Available:
https://www.yamakin-gold.co.jp/prdct_precious/souba/souba.html.
(17) G. J. K. Acres and G. A. Hards, “Electrocatalysts for fuel cells,” Philos. Trans. R. Soc. A Math. Phys. Eng. Sci., vol. , no. , pp. – , .
( ) J. K. Nørskov et al., “Origin of the Overpotential for Oxygen Reduction at a Fuel-Cell
Cathode,” J. Phys. Chem. B, vol. , no. , pp. – , Nov. .
( ) P. Strasser et al., “Lattice-strain control of the activity in dealloyed core–shell fuel cell catalysts,” Nat. Chem., vol. , no. , pp. – , .
( ) W. Martienssen and H. Warlimont, Eds., Springer Handbook of Condensed Matter and Materials Data, vol. . Springer Berlin Heidelberg, .
(21) B. Hammer and J. K. Norskov, “Why gold is the noblest of all the metals,” Nature, vol. , no. , pp. – , Jul. .
(22) N. Saliba, D. H. Parker, and B. E. Koel, “Adsorption of oxygen on Au( ) by exposure to ozone,” Surf. Sci., vol. , no. – , pp. – , .
(23) M. Haruta, T. Kobayashi, H. Sano, and N. Yamada, “Novel Gold Catalysts for the Oxidation of Carbon Monoxide at a Temperature far Below °C,” Chem. Lett., vol. , no. , pp. –
, Feb. .
( ) M. Haruta, N. Yamada, T. Kobayashi, and S. Iijima, “Gold catalysts prepared by coprecipitation for low-temperature oxidation of hydrogen and of carbon monoxide,” J.
Catal., vol. , no. , pp. – , .
( ) T. Fujita et al., “Atomic origins of the high catalytic activity of nanoporous gold,” Nat.
Mater., vol. , no. , pp. – , Sep. .
( ) ⽶澤徹, 朝倉清⾼, and 幾原雄⼀, Eds., ナノ材料解析の実際. 講談社, 2016.
(27) S. Morishita, R. Ishikawa, Y. Kohno, H. Sawada, N. Shibata, and Y. Ikuhara, “Attainment of . pm spatial resolution using kV scanning transmission electron microscope equipped with fifth-order aberration corrector,” Microscopy, vol. , no. , pp. – , .
( ) T. Akashi et al., “Aberration corrected . -MV cold field-emission transmission electron microscope with a sub- -pm resolution,” Appl. Phys. Lett., vol. , no. , pp. – , . ( ) S. J. Pennycook and P. D. Nellist, Impact of Electron and Scanning Probe Microscopy on
Materials Research. Dordrecht: Springer Netherlands, .
( ) P. D. Nellist and S. J. Pennycook, “The principles and interpretation of annular dark-field Z-contrast imaging,” in Advances in Imaging and Electron Physics, vol. , no. C, , pp.
– .
( ) M. Varela et al., “Materials Characterization in the Aberration-Corrected Scanning
Transmission Electron Microscope,” Annu. Rev. Mater. Res., vol. , no. , pp. – , Aug.
.
(32) W. J. Huang, R. Sun, J. Tao, L. D. Menard, R. G. Nuzzo, and J. M. Zuo, “Coordination-dependent surface atomic contraction in nanocrystals revealed by coherent diffraction,” Nat.
Mater., vol. , no. , pp. – , Apr. .
(33) R. Smoluchowski, “Anisotropy of the Electronic Work Function of Metals,” Phys. Rev., vol.
, no. , pp. – 4, Nov. 1941.
( ) C. L. Johnson et al., “Effects of elastic anisotropy on strain distributions in decahedral gold nanoparticles,” Nat. Mater., vol. , no. , pp. – , Feb. .
( ) ⼭崎貴司 and 渡辺和⼈, “STEM像の解釈( ),” 顕微鏡, vol. , no. , pp. – , 2008.
(36) L. Jones and P. D. Nellist, “Identifying and Correcting Scan Noise and Drift in the Scanning Transmission Electron Microscope,” Microsc. Microanal., vol. , no. , pp. – , Aug. .
( ) K. Kimoto, T. Asaka, X. Yu, T. Nagai, Y. Matsui, and K. Ishizuka, “Local crystal structure analysis with several picometer precision using scanning transmission electron microscopy,”
Ultramicroscopy, vol. , no. , pp. – , Jun. .
( ) A. B. Yankovich, B. Berkels, W. Dahmen, P. Binev, and P. M. Voyles, “High-precision scanning transmission electron microscopy at coarse pixel sampling for reduced electron dose,” Adv. Struct. Chem. Imaging, vol. 1, no. 1, p. 2, Dec. 2015.
( ) N. Mevenkamp, P. Binev, W. Dahmen, P. M. Voyles, A. B. Yankovich, and B. Berkels,
“Poisson noise removal from high-resolution STEM images based on periodic block matching,” Adv. Struct. Chem. Imaging, vol. 1, no. 1, p. 3, 2015.
( ) A. B. Yankovich et al., “Picometre-precision analysis of scanning transmission electron microscopy images of platinum nanocatalysts,” Nat. Commun., vol. , no. May, p. , Jun.
.
( ) 坂公恭, 結晶電⼦顕微鏡学 ー材料研究者のためのー. 内⽥⽼鶴圃, 1997.
( ) ⽇本表⾯学会, Ed., 透過型電⼦顕微鏡(表⾯分析技術選書). 丸善株式会社, 2009.
(43) J. M. Cowley, “IMAGE CONTRAST in a TRANSMISSION SCANNING ELECTRON MICROSCOPE,” Appl. Phys. Lett., vol. , no. , pp. – , .
(44) J. M. Lebeau, S. D. Findlay, L. J. Allen, and S. Stemmer, “Standardless Atom Counting in Scanning Transmission Electron Microscopy,” no. , pp. – , .
( ) R. Ishikawa, A. R. Lupini, S. D. Findlay, T. Taniguchi, and S. J. Pennycook, “Three-Dimensional Location of a Single Dopant with Atomic Precision by Aberration-Corrected Scanning Transmission Electron Microscopy,” Nano Lett., vol. , no. , pp. – , Apr.
.
(46) P. E. Batson, “Electron microscopy: Hydrogen brightens up.,” Nat. Mater., vol. , no. , pp.
– , .
(47) R. Ishikawa, E. Okunishi, H. Sawada, Y. Kondo, F. Hosokawa, and E. Abe, “Direct imaging of hydrogen-atom columns in a crystal by annular bright-field electron microscopy.,” Nat.
Mater., vol. , no. , pp. – , .
(48) D. E. Jesson and S. J. Pennycook, “Incoherent Imaging of Thin Specimens Using Coherently Scattered Electrons,” Proc. R. Soc. A Math. Phys. Eng. Sci., vol. , no. , pp. – ,
.
(49) M. Tanaka, “ナノビーム電⼦線を⽤いた極微細構造解析とイメージング(2),” 電⼦顕
微鏡, vol. , no. , pp. – , .
(50) Y. Sato, R. Miyauchi, M. Aoki, S. Fujinaka, R. Teranishi, and K. Kaneko, “Large Electric-Field-Induced Strain Close to the Surface in Barium Titanate Studied by Atomic-Scale In Situ Electron Microscopy,” Phys. Status Solidi - Rapid Res. Lett., vol. , pp. – , . (51) A. De Backer, K. H. W. van den Bos, W. Van den Broek, J. Sijbers, and S. Van Aert,
“StatSTEM: An efficient approach for accurate and precise model-based quantification of atomic resolution electron microscopy images,” Ultramicroscopy, vol. , pp. – , Dec.
.
(52) J. Shi and J. Malik, “Normalized cuts and image segmentation,” IEEE Trans. Pattern Anal.
Mach. Intell., vol. , no. , pp. – , .
(53) M. Schmidbauer, A. Kwasniewski, and J. Schwarzkopf, “High-precision absolute lattice parameter determination of SrTiO , DyScO and NdGaO single crystals,” Acta Crystallogr. Sect. B Struct. Sci., vol. , no. , pp. – , Feb. .
( ) C. E. Rasmussen and C. K. I. Williams, Gaussian processes for machine learning., vol. , no. . .
(55) T. T. Hines and E. A. Hetland, “Revealing transient strain in geodetic data with Gaussian process regression,” Geophys. J. Int., vol. , no. , pp. – , .
(56) N. Braidy, Y. Le Bouar, S. Lazar, and C. Ricolleau, “Correcting scanning instabilities from images of periodic structures,” Ultramicroscopy, vol. , pp. – , .
( ) J. C. H. Spence, “High-Resolution Electron Microscopy,” vol. , .
(58) A. Toprak and I. Güler, “Impulse noise reduction in medical images with the use of switch mode fuzzy adaptive median filter,” Digit. Signal Process. A Rev. J., vol. , no. , pp. –
, .
(59) A. Maeland and T. B. Flanagan, “LATTICE SPACINGS OF GOLD–PALLADIUM ALLOYS,”
Can. J. Phys., vol. , no. , pp. – , Nov. .
(60) H. Wang and M. Li, “Ab initio calculations of second-, third-, and fourth-order elastic constants for single crystals,” Phys. Rev. B, vol. 79, no. 22, p. 224102, Jun. 2009.
(61) L. Vitos, A. V. Ruban, H. L. Skriver, and J. Kollár, “The surface energy of metals,” Surf. Sci., vol. , no. – , pp. – , Aug. .
(62) W. R. Tyson and W. A. Miller, “Surface free energies of solid metals: Estimation from liquid surface tension measurements,” Surf. Sci., vol. , no. , pp. – , Jan. .
( ) A. G. Khachaturyan, Theory of structural transformations in solids. . (64) “Interatomic Potentials Repository.” [Online]. Available:
https://www.ctcms.nist.gov/potentials/system/Au/.
(65) G. P. P. Pun, “to be published (the EAM potential is available on the website of Interatomic Potentials Repository).”
(66) D. J. Wales and J. P. K. Doye, “Global Optimization by Basin-Hopping and the Lowest Energy Structures of Lennard-Jones Clusters Containing up to Atoms,” J. Phys. Chem. A, vol. , no. , pp. – , Jul. .
(67) M. W. Finnis and V. Heine, “Theory of lattice contraction at aluminium surfaces,” J. Phys. F Met. Phys., vol. , no. , pp. L –L , Mar. .
(68) K. P. Bohnen and K. M. Ho, “Structure and dynamics at metal surfaces,” Surf. Sci. Rep., vol.
, no. – , pp. – , Dec. .
(69) Z. L. Wang, R. P. Gao, B. Nikoobakht, and M. a. El-Sayed, “Surface Reconstruction of the Unstable { } Surface in Gold Nanorods,” J. Phys. Chem. B, vol. , no. , pp. – , Jun. .
(70) H. A. Keul, M. Möller, and M. R. Bockstaller, “Structural evolution of gold nanorods during controlled secondary growth,” Langmuir, vol. , no. , pp. – , .
(71) H. L. Skriver and N. M. Rosengaard, “Surface energy and work function of elemental metals,”
Phys. Rev. B, vol. , no. , pp. – , .
(72) A. S. Barnard, “Modeling the impact of alkanethiol SAMs on the morphology of gold nanocrystals,” Cryst. Growth Des., vol. , no. , pp. – , .
(73) K. C. Jha, H. Liu, M. R. Bockstaller, and H. Heinz, “Facet recognition and molecular ordering of ionic liquids on metal surfaces,” J. Phys. Chem. C, vol. , no. , pp. – , . (74) N. Almora-Barrios, G. Novell-Leruth, P. Whiting, L. M. Liz-Marzán, and N. López,
“Theoretical description of the role of halides, silver, and surfactants on the structure of gold nanorods,” Nano Lett., vol. , no. , pp. – , .
( ) B. Goris et al., “Atomic-scale determination of surface facets in gold nanorods,” Nat. Mater.,