Photoemission Structure Factor Effect for Fermi Rings of the Si(111)√3×√3-Ag Surface

Abstract: The energy contour at Fermi level (Fermi surface) of the Si(111) √ 3 × √ 3-Ag superstructure was measured in several surface Brillouin zones (SBZs) by high resolution angle-resolved photoemission spectroscopy (ARPES). Fermi rings centered at Γ points were observed only in the second SBZs, but missing in the first SBZ. This phenomenon was successfully reproduced by a calculation of the optical transition matrix based on a simple tightbinding approximation for the surface topmost-layer Ag atoms; the intensity in… Show more

“…This is supported by experimentally observed linear I-V curves in the present conductivity measurements and theoretically by the WKB tunneling regime typically used in STM theories [22]. Inserting T determined above and k F (0:1 A ÿ1 ) determined in the previous ARPES measurements for the 3 p 3 p -Ag surface [2,3,21] into Eq. (2), 2D at a monatomic step on this particular surface is determined to be 2D 94 10 3 ÿ1 m ÿ1 .…”

“…In the figure, the energy position on the horizontal axis is referred to as the bottom of the surface-state band, E min . According to previous ARPES studies [2,3], E min is located at a binding energy 0:3 eV below E F , so that E F is located at 0:3 eV in Fig. 3(c).…”

“…Its physical properties have been well studied on noble metal surfaces [15][16][17][18][19]. The wavelength varied with tip bias (not shown here) [15,16], and the energy versus wave number dispersion obtained through the bias-dependent standing waves showed a parabola with an effective mass equal to that obtained by angle-resolved photoemission spectroscopy (ARPES) [2,3,20,21]. Figure 3(b) shows topographic STM and dI=dV profiles over a step.…”

“…The surface has a parabolic electronic band crossing the Fermi level with a circular Fermi surface, indicating an isotropic twodimensional free-electron like metal of monolayer thickness [2,3]. Recently, transport measurements with stateof-the-art monolithic micro-four-point probes (MFPP) and four-tip scanning tunneling microscope (STM) probes have been reported to be successful in obtaining (anisotropic) conductance values of atomic-scale structures on semiconductor surfaces, including the Si111 3 p 3 p -Ag surface [4 -9].…”

Electrical Resistance of a Monatomic Step on a Crystal Surface

“…This is supported by experimentally observed linear I-V curves in the present conductivity measurements and theoretically by the WKB tunneling regime typically used in STM theories [22]. Inserting T determined above and k F (0:1 A ÿ1 ) determined in the previous ARPES measurements for the 3 p 3 p -Ag surface [2,3,21] into Eq. (2), 2D at a monatomic step on this particular surface is determined to be 2D 94 10 3 ÿ1 m ÿ1 .…”

“…In the figure, the energy position on the horizontal axis is referred to as the bottom of the surface-state band, E min . According to previous ARPES studies [2,3], E min is located at a binding energy 0:3 eV below E F , so that E F is located at 0:3 eV in Fig. 3(c).…”

“…Its physical properties have been well studied on noble metal surfaces [15][16][17][18][19]. The wavelength varied with tip bias (not shown here) [15,16], and the energy versus wave number dispersion obtained through the bias-dependent standing waves showed a parabola with an effective mass equal to that obtained by angle-resolved photoemission spectroscopy (ARPES) [2,3,20,21]. Figure 3(b) shows topographic STM and dI=dV profiles over a step.…”

“…The surface has a parabolic electronic band crossing the Fermi level with a circular Fermi surface, indicating an isotropic twodimensional free-electron like metal of monolayer thickness [2,3]. Recently, transport measurements with stateof-the-art monolithic micro-four-point probes (MFPP) and four-tip scanning tunneling microscope (STM) probes have been reported to be successful in obtaining (anisotropic) conductance values of atomic-scale structures on semiconductor surfaces, including the Si111 3 p 3 p -Ag surface [4 -9].…”

Electrical Resistance of a Monatomic Step on a Crystal Surface

“…[7] Since reflection phase shift at a scatter is related with transmission through it, a research of a standing wave will lead to obtaining its conductivity. Using an isotropic two-dimensional (2D) metallic surface, Si(111) √ 3 × √ 3-Ag, [8][9][10][11] described below, we have examined the issue. In this research, we studied conductance of a single atomic step through detailed analyses on standing waves near the steps and surface transport measurements.…”

Electrical conduction through a monatomic surface step

Multi-Probe Scanning Tunneling Microscopy