Functionalizing of single molecules on surfaces has manifested great potential for bottom-up construction of complex devices on a molecular scale. We discuss the growth mechanism for the initial layers of polycyclic aromatic hydrocarbons on metal surfaces and we review our recent progress on molecular machines, and present a molecular rotor with a fixed off-center axis formed by chemical bonding. These results represent important advances in molecular-based nanotechnology.
References
[1]
Barth, JV; Costantini, G; Kern, K. Engineering atomic and molecular nanostructures at surfaces. Nature?2005, 437, 671–679.
[2]
Gao, H-J; Gao, L. Scanning tunneling microscopy of functional nanostructures on solid surfaces: Manipulation, self-assembly, and applications. Prog Surf Sci?2009.
[3]
Gao, H-J; Ji, W; Feng, M. Structural and conductance transitions of rotaxane based nanostructures and application in nanorecording. J. Comput. Theory Nano?2006, 3, 970–981.
[4]
Shi, DX; Ji, W; Lin, X; He, XB; Lian, JC; Gao, L; Cai, JM; Lin, H; Du, SX; Lin, F; Seidel, C; Chi, LF; Hofer, WA; Fuchs, H; Gao, H-J. Role of lateral alkyl chains in modulation of molecular structure on metal surfaces. Phys Rev Lett?2006, 96, 226101:1–226101:4.
[5]
Du, SX; Gao, H-J; Seidel, C; Tsetseris, L; Ji, W; Kopf, H; Chi, LF; Fuchs, H; Pennycook, SJ; Pantelides, ST. Selective nontemplated adsorption of organic molecules on nanofacets and the role of bonding patterns. Phys Rev Lett?2006, 97, 156105:1–156105:4.
[6]
Wang, YL; Ji, W; Shi, DX; Du, SX; Seidel, C; Ma, YG; Gao, H-J; Chi, LF; Fuchs, H. Structural evolution of pentacene on a Ag(110) surface. Phys Rev B?2004, 69, 075408:1–075408:5.
[7]
Gao, L; Deng, ZT; Ji, W; Lin, X; Cheng, ZH; He, XB; Shi, DX; Gao, H-J. Understanding and controlling the weakly interacting interface in perylene/Ag(110). Phys Rev B?2006, 73, 075424:1–075424:6.
[8]
Gao, L; Sun, JT; Cheng, ZH; Deng, ZT; Lin, X; Du, SX; Gao, H-J. Structural evolution at the initial growth stage of perylene on Au(111). Surf. Sci?2007, 601, 3179–3185.
[9]
Cheng, ZH; Gao, L; Deng, ZT; Liu, Q; Jiang, N; Lin, X; He, XB; Du, SX; Gao, H-J. Epitaxial growth of iron phthalocyanine at the initial stage on Au(111) surface. J. Phys. Chem. C?2007, 111, 2656–2660.
[10]
Cheng, ZH; Gao, L; Deng, ZT; Jiang, N; Liu, Q; Shi, DX; Du, SX; Guo, HM; Gao, H-J. Adsorption behavior of iron phthalocyanine on Au(111) surface at submonolayer coverage. J. Phys. Chem. C?2007, 111, 9240–9244.
[11]
Deng, ZT; Lin, H; Ji, W; Gao, L; Lin, X; Cheng, ZH; He, XB; Lu, JL; Shi, DX; Hofer, WA; Gao, H-J. Selective analysis of molecular states by functionalized scanning tunneling microscop tips. Phys Rev Lett?2006, 96, 156102:1–156102:4.
[12]
Deng, ZT; Guo, HM; Guo, W; Gao, L; Cheng, ZH; Shi, DX; Gao, H-J. Structural properties of tetra-tert-butyl zinc(II) phthalocyaine isomers on a Au(111) surface. J. Phys. Chem. C?2009, 113, 11223–11227.
[13]
He, XB; Cai, JM; Shi, DX; Wang, Y; Gao, H-J. Epitaxial growth of quinacridone derivative on Ag(110) studied by scanning tunneling microscopy. J. Phys. Chem. C?2008, 112, 7138–7144.
[14]
Guo, W; Du, SX; Zhang, YY; Hofer, WA; Seidel, C; Chi, LF; Fuchs, H; Gao, H-J. Electrostatic field effect on molecular structures at metal surfaces. Surf. Sci?2009, 603, 2815–2819.
Binnig, G; Rohrer, H; Gerber, Ch; Weibel, E. Surface studies by scanning tunneling microscopy. Phys. Rev. Lett?1982, 49, 57–61.
[17]
B?hringer, M; Morgenstern, K; Schneider, WD; Berndt, R; Mauri, F; De Vita, A; Car, R. Two-dimensional self-assembly of supramolecular clusters and chains. Phys. Rev. Lett?1999, 83, 324–327.
[18]
Lukas, S; Witte, G; W?ll, C. Novel mechanism for molecular self-assembly on metal substrates: Unidirectional rows of pentacene on Cu(110) produced by a substrate-mediated repulsion. Phys Rev Lett?2002, 88, 028301:1–028301:4.
[19]
Seidel, C; Ellerbrake, R; Gross, L; Fuchs, H. Structural transitions of perylene and coronene on silver and gold surfaces: A molecular-beam epitaxy LEED study. Phys Rev B?2001, 64, 195418:1–195418:10.
[20]
Chen, Q; Rada, T; McDowall, A; Richardson, NV. Epitaxial growth of a crystalline organic semiconductor: perylene/Cu{110}. Chem. Mater?2002, 14, 743–749.
[21]
Taborski, J; V?terlein, P; Dietz, H; Zimmermann, U; Umbach, E. NEXAFS investigations on ordered adsorbate layers of large aromatic molecules. J. Electron Spectrosc?1995, 75, 129–147.
[22]
Witte, G; H?nel, K; S?hnchen, S; W?ll, C. Growth and morphology of thin films of aromatic molecules on metals: the case of perylene. Appl. Phys. A?2006, 82, 447–455.
[23]
H?nel, K; S?hnchen, S; Lukas, S; Beernink, G; Birkner, A; Strunskus, T; Witte, G; W?ll, Ch. Organic molecular-beam deposition of perylene on Cu(110): Results from near-edge x-ray absorption spectroscopy, X-ray photoelectron spectroscopy, and atomic force microscopy. J. Mater. Res?2004, 19, 2049–2056.
[24]
Witte, G; W?ll, Ch. Growth of aromatic molecules on solid substrates for applications in organic electronics. J. Mater. Res?2004, 19, 1889–1916.
Ma, LP; Song, YL; Gao, H-J; Zhao, WB; Chen, HY; Xue, ZQ; Pang, SJ. Nanometer-scale recording on an organic-complex thin film with a scanning tunneling microscope. Appl. Phys. Lett?1996, 69, 3752–3753.
[28]
Shi, DX; Song, YL; Zhang, HX; Jiang, P; He, ST; Xie, SS; Pang, SJ; Gao, H-J. Direct observation of a local structural transition for molecular recording with scanning tunneling microscopy. Appl. Phys. Lett?2000, 77, 3203–3205.
[29]
Shi, DX; Song, YL; Zhu, DB; Zhang, HX; Xie, SS; Pang, SJ; Gao, H-J. Recording at the nanometer scale on p-nitrobenzonitrile thin films by scanning tunneling microscopy. Adv. Mater?2001, 13, 1103–1105.
[30]
Wu, HM; Song, YL; Du, SX; Liu, HW; Gao, H-J; Jiang, L; Zhu, DB. Nanoscale data recording on an organic monolayer film. Adv. Mater?2003, 15, 1925–1929.
[31]
Wen, YQ; Song, YL; Zhao, DB; Ding, KL; Yuan, WF; Lin, X; Gao, H-J; Jiang, L; Zhu, DB. Crystalline thin films formed by supramolecular assembly for ultrahigh-density data storage. Adv. Mater?2004, 16, 2018–2021.
[32]
Feng, M; Guo, XF; Lin, X; He, XB; Ji, W; Du, SX; Zhang, DQ; Zhu, DB; Gao, H-J. Stable, reproducible nanorecording on rotaxane thin films. J. Am. Chem. Soc?2005, 127, 15338–15339.
[33]
Feng, M; Gao, L; Deng, ZT; Ji, W; Guo, XF; Du, SX; Shi, DX; Zhang, DQ; Zhu, DB; Gao, H-J. Reversible, erasable, and rewritable nanorecording on an H2 rotaxane thin film. J. Am. Chem. Soc?2007, 129, 2204–2205.
[34]
Cai, L; Feng, M; Guo, HM; Ji, W; Du, SX; Chi, LF; Fuchs, H; Gao, H-J. Reversible and reproducible conductance transition in a polyimide thin film. J. Phys. Chem. C?2008, 112, 17038–17041.
[35]
Zhao, A; Li, Q; Chen, L; Xiang, H; Wang, W; Pan, S; Wang, B; Xiao, X; Yang, J; Hou, JG; Zhu, Q. Controlling the Kondo effect of an adsorbed magnetic ion through its chemical bonding. Science?2005, 309, 1542–1544.
[36]
Gao, L; Ji, W; Hu, YB; Cheng, ZH; Deng, ZT; Liu, Q; Jiang, N; Lin, X; Guo, W; Du, SX; Hofer, WA; Xie, XC; Gao, H-J. Site-specific Kondo effect at ambient temperatures in iron-based molecules. Phys Rev Lett?2007, 99, 106402:1–106402:4.
[37]
Wahl, P; Diekh?ner, L; Wittich, G; Vitali, L; Schneider, MA; Kern, K. Kondo effect of molecular complexes at surfaces: ligand control of the local spin coupling. Phys Rev Lett?2005, 95, 166601:1–166601:4.
[38]
Tsukahara, N; Noto, K; Ohara, M; Shiraki, S; Takagi, N; Takata, Y; Miyawaki, J; Taguchi, M; Chainani, A; Shin, S; Kawai, M. Adsorption-induced switching of magnetic anisotropy in a single iron(II) phthalocyanine molecule on an oxidized Cu(110) surface. Phys Rev Lett?2009, 102, 167203:1–167203:4.
[39]
Chen, X; Fu, YS; Ji, SH; Zhang, T; Cheng, P; Ma, XC; Zou, XL; Duan, WH; Jia, JF; Xue, QK. Probing superexchange interaction in molecular magnets by spin-flip spectroscopy and microscopy. Phys Rev Lett?2008, 101, 197208:1–197208:4.
[40]
Stipe, BC; Rezaei, MA; Ho, W. Single-molecular vibrational spectroscopy and microscopy. Science?1998, 280, 1732–1735.
[41]
Stipe, BC; Rezaei, MA; Ho, W. Inducing and viewing the rotational motion of a single molecule. Science?1998, 279, 1907–1909.
[42]
Gimzewski, JK; Joachim, C; Schlittler, RR; Langlais, V; Tang, H; Johannsen, I. Rotation of a single molecule within a supramolecular bearing. Science?1998, 281, 531–533.
[43]
Gao, L; Liu, Q; Zhang, YY; Jiang, N; Zhang, HG; Cheng, ZH; Qiu, WF; Du, SX; Liu, YQ; Hofer, WA; Gao, H-J. Constructing an array of anchored single-molecule rotors on gold surfaces. Phys Rev Lett?2008, 101, 197209:1–197209:4.
[44]
Eigler, DM; Lutz, CP; Rudge, WE. An atomic switch realized with the scanning tunneling microscope. Nature?1991, 352, 600–603.
[45]
Park, H; Park, J; Lim, AKL; Anderson, EH; Alivisatos, AP; McEuen, PL. Nanomechanical oscillations in a single C60 transistor. Nature?2000, 407, 57–60.
[46]
Schliwa, M. Molecular Motors; Wiley-VCH: Weinheim, Germany, 2003.
Chiaravalloti, F; Gross, L; Rieder, K-H; Stojkovic, SM; Gourdon, A; Joachim, C; Moresco, F. A rack-and-pinion device at the molecular scale. Nat. Mater?2007, 6, 30–33.
[51]
Grill, L; Rieder, K-H; Moresco, F; Rapenne, G; Stojkovic, S; Bouju, X; Joachim, C. Rolling a single molecular wheel at the atomic scale. Nat. Nanotech?2007, 2, 95–98.
[52]
Shirai, Y; Osgood, AJ; Zhao, Y; Kelly, KF; Tour, JM. Directional control in thermally driven single-molecule nanocars. Nano Lett?2005, 5, 2330–2334.
[53]
Maksymovych, P; Sorescu, DC; Yates, JT. Gold-adatom-mediated bonding in self-assembled short-chain alkanethiolate species on the Au(111) surface. Phys Rev Lett?2006, 97, 146103:1–146103:4.
[54]
Perdew, JP; Chevary, JA; Vosko, SH; Jackson, KA; Pederson, MR; Singh, DJ; Fiolhais, C. Atoms, molecules, solids, and surfaces: Applications of the generalized gradient approximation for exchange and correlation. Phys. Rev. B?1992, 46, 6671–6687.
Kresse, G; Joubert, D. From ultrasoft pseudopotentials to the projector augmented-wave method. Phys. Rev. B?1999, 59, 1758–1775.
[57]
Kresse, G; Furthmüller, J. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys. Rev. B?1996, 54, 11169–11186.
[58]
Kresse, G; Hafner, J. Ab initio molecular dynamics for liquid metals. Phys. Rev. B?1993, 47, R558–R561.
[59]
Limot, L; Kr?ger, J; Berndt, R; Garcia-Lekue, A; Hofer, WA. Atom transfer and single-adatom contacts. Phys Rev Lett?2005, 94, 126102:1–126102:4.
[60]
W?ll, C; Chiang, S; Wilson, RJ; Lippel, PH. Determination of atom positions at stacking-fault dislocations on Au(111) by scanning tunneling microscopy. Phys. Rev. B?1989, 39, 7988–7991.
[61]
Barth, JV; Brune, H; Ertl, G. Scanning tunneling microscopy observations on the reconstructed Au(111) surface: Atomic structure, long-range superstructure, rotational domains, and surface defects. Phys. Rev. B?1990, 42, 9307–9318.
