TY - GEN
T1 - Simulation of XSTS imaging of Self-Assembled quantum dot electronic states
AU - Roy, Mervyn
AU - Maksym, P.A.
AU - Bruls, D.M.
AU - Offermans, P.
AU - Koenraad, P.M.
PY - 2003
Y1 - 2003
N2 - Recently, STM measurements of cleaved, self assembled quantum dots (SAQDs) have
provided important information on the morphology and composition of these buried semiconductor islands. It is also now becoming possible to use STM techniques to image the electronic charge density within the SAQDs. At low bias voltages, the tunnelling current measured during crosssectional scanning tunnelling spectroscopy (XSTS) experiments contains direct information on the 0D bound electronic states of the cleaved quantum dots.
In this paper we present a numerical simulation of an XSTS experiment. The calculated tunnelling currents between an STM tip and the bound states inside a physically realistic model of a cleaved SAQD are compared to experimental results and qualitative agreement is found. The calculation of the tunnelling current is split into two stages. First the bound electron states of the cleaved quantum dot are calculated by exact diagonalisation of the Hamiltonian in a simple harmonic oscillator basis set. The calculation is performed within the single-band effective mass approximation including the position dependence of the effective mass and, most crucially, the effect of the deformations of the cleaved dot structure and the strain field within the system. The strains and deformations of the heterostructure are found with a continuum, finite element model.
The calculation method is completely general, however, in this paper we apply it to the InGaAs dot structure reported by Bruls et al [1]. Second, the Tersoff-Hamann approximation [2] is used to calculate the tunnelling probability between the bound electronic states and the STMtip at different tip positions and bias voltages. The calculated STM signal is compared to experimental data and reasonable agreement is obtained. The method may be used to obtain additional physical information about the buried SAQDs, for example, details on the lateral variations in the composition.
AB - Recently, STM measurements of cleaved, self assembled quantum dots (SAQDs) have
provided important information on the morphology and composition of these buried semiconductor islands. It is also now becoming possible to use STM techniques to image the electronic charge density within the SAQDs. At low bias voltages, the tunnelling current measured during crosssectional scanning tunnelling spectroscopy (XSTS) experiments contains direct information on the 0D bound electronic states of the cleaved quantum dots.
In this paper we present a numerical simulation of an XSTS experiment. The calculated tunnelling currents between an STM tip and the bound states inside a physically realistic model of a cleaved SAQD are compared to experimental results and qualitative agreement is found. The calculation of the tunnelling current is split into two stages. First the bound electron states of the cleaved quantum dot are calculated by exact diagonalisation of the Hamiltonian in a simple harmonic oscillator basis set. The calculation is performed within the single-band effective mass approximation including the position dependence of the effective mass and, most crucially, the effect of the deformations of the cleaved dot structure and the strain field within the system. The strains and deformations of the heterostructure are found with a continuum, finite element model.
The calculation method is completely general, however, in this paper we apply it to the InGaAs dot structure reported by Bruls et al [1]. Second, the Tersoff-Hamann approximation [2] is used to calculate the tunnelling probability between the bound electronic states and the STMtip at different tip positions and bias voltages. The calculated STM signal is compared to experimental data and reasonable agreement is obtained. The method may be used to obtain additional physical information about the buried SAQDs, for example, details on the lateral variations in the composition.
M3 - Conference contribution
SN - 0-7354-0168-3
T3 - AIP Conference Proceedings
SP - 707
EP - 714
BT - Proc. 12th Int. Conf. on Scanning Tunneling Microscopy/Spectroscopy and Related Techniques, July 21-25 2003, Eindhoven, Neth.
A2 - Kemerink, M.
A2 - Koenraad, P.M.
PB - American Institute of Physics
CY - Melville, New-York, USA
T2 - conference; 12th Int. Conf. on Scanning Tunneling Microscopy/Spectroscopy and Related Techniques : STM 2003; 2003-07-21; 2003-07-25
Y2 - 21 July 2003 through 25 July 2003
ER -