Scanning tunneling microscopic image

Weiss P S and Eigler D M 1993 Site dependence of the apparent shape of a molecule in scanning tunnelling microscope images benzene on Pt(111) Rhys. Rev. Lett. 71 3139... 

Fisher A J and Bldchl P E 1993 Adsorption and scanning-tunneling-microscope Imaging of benzene on graphite and M0S2 Phys. Rev. Lett. 70 3263-6... 

Figure 11.1. Scanning tunnelling microscope image of a periodic array of Fe islands nucleated on the regular dislocation network of a Cu bilayer deposited on a platinum (111) face (after Urune...

Figure 12.17 Representation of a scanning tunneling microscope image of Ru spontaneously deposited on aPt(lll) surface [Crown et al., 2002], The Ru coverage was about 0.2 ML. (Ru is in white on the figure and inset.) The inset indicates that monoatomic Ru deposition predominates diatomic deposition is found only with 10% of the Ru deposit.

Lawunmi, D., and Payne, M. C. (1990). Theoretical investigation of the scanning tunneling microscope image of graphite. J. Phys. Condens. Matter. 2, 3811-3821. 

Mate, C. M., Erlandsson, R., McClelland, G. M., and Chiang, S. (1989). Direct measurement of forces during scanning tunneling microscope imaging of graphite. Surface Science 208, 473-486. 

Tersoff, J. (1990). Role of tip electronic structure in scanning tunneling microscope images. Phys. Rev. B 41, 1235-1238. 

Fig. 26a. Scanning tunneling microscopic image of a 310nmx310nm area of bare Au film epitaxially grown on a mica substrate (Au mica) measured in air constant current mode bias (Vb) of + 50 mV, tunneling current (I,) of 10 nA. b STM image of a 3.5 nm x 3.5 nm area of a bare Au/mica film constant current mode Vb = 4- 4.9 mV I, = 3.0 nA [219]...

Fig. 8. Scanning tunneling microscope image of gallium arsenide (GaAs). Atoms to the left of each row are gallium others are arsenic. (IBM Corporation)...

Andersen, J. E. T., Jensen, M. H., Moller, P., and Ulstrup, J. (1996). Perspectives for in situ scanning tunnel microscopic imaging of metalloproteins at HOPG surfaces. Electrochim. Acta 41, 2005-2010. 

Figure 3 Scanning tunneling microscope image of a Si(00 1) surface showing symmetric and asymmetric dimers. Scan area is 40 x 40 nm2. Sample bias is —2 V and tunneling current is 1.0 nA.

Figure 5 Scanning tunneling microscope image (100 x 100 nm2) of single-layer-stepped Si(0 0 1) surface 0.5° misoriented towards the [110] direction, obtained at —2V sample bias and 0.5nA tunneling current. The single-layer steps are alternating smooth (5a) and rough (5b)-...

Figure 7 A scanning tunneling microscope image of a Si(001) surface after the deposition of a small amount of Si at room temperature. The image shows two single-layer steps (die jagged interfaces) separating three terraces. The image is obtained —2 V sample bias and 1.0 nA tunneling current. The area pictured is 30 by 30 nm. Several isolated on-top and trough dimers can be identified.

Figure 10 HREEL spectrum (a), in situ scanning tunneling microscope image (b), and molecular model (c) ofquinone sulfonate chemisorbed...

Figure 6.3. Scanning tunneling microscope image of the placement of individual Xe atoms on a Ni(llO) surface - no surprise, by researchers at IBM. Reproduced with permission from Eigler, D. M. Schweizer, E. K. Nature 1990, 344, 524. Copyright 1990 Macmillan Publishers Ltd.

Fig. 8.24. A scanning tunneling microscope image of a pyrite growth surface taken under oil. The surface structure is arranged in ranges and valleys parallel to the line marked A-A, which is parallel to a principal crystallographic axis. A 5.4 X 5.4 surface cell, as expected for a termination of the bulk pyrite structure, is marked. However, the atomic arrangement does not correspond to a simple termination of the pyrite structure as discussed by Eggleston and Hochella (1990), from whose work this figure is reproduced (with the publisher s permission).

Galperin, M. and Beratan, D.N. (2005) Simulation of scanning tunneling microscope images of 1,3-cyclohexadiene bound to a silicon surface. J. Phys. Chem. B, 109, 1473-1480. 

Allen, M.J., Balooch, M., Subbiah, S., Tench, R.J., Siekliaus, W., and Balhorn, R. (1991) Scanning tunneling microscope images of adenine and thymine at atomic resolution. Scanning Microscopy, 5, 625-630. 

Fig. 9.21. Scanning tunneling microscope image, 100 nm x 100 nm, of a stepped Si(OOl) surface (courtesy of A. Laracuente and L. J. Whitman).

FIGURE 2.1.5 Scanning tunneling microscope images of a-b facet of a thick, as-grown rubrene crystal. The herringbone molecular organization at the surface, consistent with the bulk structure (shown in the lower left corner), is evident. (From Menard, E. et al., Adv. Mater., 18, 1552, 2006.)... 

Fig. 3. In-situ scanning tunneling microscope images of a Pd(lll)-(V3xV3)R30°-I facet on a single-crystal bead at various stages of adsorbate-catalyzed dissolution. M, marker S, step.

Figure 13.5.1 Scanning tunneling microscope image of a 23 A X 23 A region of an Au (111) surface prepared by evaporation of Au on a mica substrate. [Reprinted with permission from Y.-T. Kim, R. L. McCarley, and A. J. Bard, J. Phys. Chem., 96, 7416 (1992). Copyright 1992, American Chemical Society.]...

Figure Al.7.2. Large-scale (5000 Atimes 5000 A) scanning tunnelling microscope image of a stepped Si...

Allen M J, Balooch M, Subbiah S, Tenoh R J, Balhorn R and Slekhaus W 1991 Scanning tunnelling microscope images of adenine and thymine at atomio resolution Scanning Microsc. 5 625... 

A scanning tunneling microscope image of nickel metal. Each peak represents a nickel atom. 

Loo, B. H., Liu, Z. R, and Fujishima, A, Scanning Tunneling Microscopic Images of an Azobenzene Derivative Differently Deposited on Highly Oriented Pyrolytk Graphite Surfaces. Surf. Set. 227,1 (1990). 

Figure 11a. A scanning tunneling microscope image of a graphite adsorbed layer on the platinum (111) crystal face. (Reproduced with permission from Lawrence Berkeley Laboratory.)...

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