Electronic Properties of PbTeCdTe 100 interfaces

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Electronic Properties of PbTeCdTe 100 interfaces

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Electronic Properties of PbTe/CdTe (100) interfaces. Roman Leitsmann, F. ... zinc blende structure. fundamental gap at G-point: 1.6 eV. PbTe : CdTe : CBO 1.0 eV ... – PowerPoint PPT presentation

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Title: Electronic Properties of PbTeCdTe 100 interfaces

1
Electronic Properties of PbTe/CdTe (100)
interfaces
Sponsored by
2
Motivation

PbTe/CdTe

PbTe Quantum-Dots are formed by an annealing
process
W. Heiss et al. Appl. Phys. Lett. 88, 192109(
2006)
they exhibit (110), (100), and (111) facets
they show intense mid-infrared luminescence
high potential for future applications like
mid-infrared quantumdot-laser
devices in medical diagnostics
mid-infrared spectroscopy

3
Motivation

Theory

Theoretical Problems using periodic boundary
conditions
two in general different A- and B-interfaces
induced dipole field at polar interfaces ( -
... - -)
charge transfer ? ionization degree of interface
atoms

Energy
Position along 100
4
Modelling
Slab-Approximations
Four Supercell modells for electronic
bandstructure calculations
5
Modelling
Bulk-Properties
PbTe
rocksalt structure fundamental gap at L-point
0.19 eV
P. Dziawa et al. phys.stat.sol c. 2,1167(2005)
CBO 1.0 eV VBO 0.4 eV
R.Leitsmann (to be published)
CdTe
zinc blende structure fundamental gap at G-point
1.6 eV
P. Dziawa et al. phys.stat.sol. c 2,1167(2005)
6

Stoichiometric slab approximation

Induced dipole potential
charge transfer
partiall ionized interface atoms

Metallic band structure
occupied conduction bands
empty valence bands

Not suitable for isolated interfaces
Suitable for layered heterostructures

Band structure
Energy alignment

B-interf.
A-interf.
B-interf.
7

Non-stoichiometric slab approximation

No dipole potential
no charge transfer
partiall ionized interface atoms

Metallic band structure
shifted Fermi-level
interface states (1/2cK, 1cJ)

Suitable for
isolated interfaces
layered heterostructures

Band structure
Energy alignment

B-interf.
B-interf.
B-interf.
8
Summary/Conclusions
Calculation of polar interface band structures
different situations different modells
Non-stoichiometric Slab Approx.
Dipole corrected Slab Approx.
Stoichiometric Slab Approx.
Vacuum Slab Approx.
symmetry constrained sys.
layered herterostructures
isolated interfaces
Cd-terminated PbTe/CdTe(100) interface band
structure
several interface states
metallic character
9
Thank you for your attention.
Sponsored by
10
Results

Dipole corrected slab approximation

Comp. dipole potential
no charge transfer
fully ionized interface atoms

Semicond. band structure
filled/empty bands
interface states (1cK, 1cJ, 1vG)

Suitable for
field-free interfaces
e.g. dot-matrix interfaces

Interface band structure
Energy alignment

A-interf.
B-interf.
A-interf.
11
Results

Vacuum slab approximation

Dipole potential within CdTe
no charge transfer
partiall ionized interface atoms

Metallic band structure
shifted Fermi-level
interface states (1/2cK, 1cJ)

Suitable for
isolated interfaces
BUT not as good as N-SA

Interface band structure
Energy alignment

A-interf.
surfaces
A-interf.
12
Additional information

Dipole correction

We compensate the artificial dipole potential ?
with a ramp-shaped potential
plane averaged potential
Calculate interface energies by total energy
differences
Energy corrections due to artificial dipole
potential ?
position along 100
13
Band offset

Alignment of electrostatic potentials

Two step procedure
PbTe
CdTe
?VBM
VBM(CdTe)
VBM(PbTe)
?(PbTe-CdTe)

bulk calculation of VBM w.r.t. the
plane-averaged potential
interface calculation of ?(PbTe-CdTe) ? ?VBM

14
Results

Band offset

Type- I heterostructure
LDA
LDASO
? results are used to correctly align the
interface bandstructures
Experimental-gap PbTe 0.19 eV L-point
CdTe 1.6 eV ?-point P. Dziawa et al.
phys.stat.sol. 2,1167(2005)
15
Results