Polarizability of Donors in Polar Semiconductors. Effect of a Weak Magnetic Field

Cahay, M.; Kartheuser, E.

doi:10.1002/pssb.2221210137

Cited by 6 publications

(8 citation statements)

References 23 publications

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“…The polarizability of the donors in polar. seniiconductors in a magnetic field has been computed in [6]. These authors conclude that the choice of the model potential is important and the contribution from electron-lattice coupling is large (30 to 50%).…”

Section: Resultsmentioning

confidence: 97%

Shallow Donor Binding Energies in Semiconductors in a Magnetic Field

Sukumar

Navaneethakrishnan

1989

Physica Status Solidi (b)

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The binding energies of the P donor in Si and the Si and S donors in GaP a t the cation and anion sites, respectively, in strong magnetic fields are calculated using a variational procedure. The central cell effects are taken into account using an Yukawa type potential and its effects on the ionization energies are obtained for various magnetic fields. In GaP the electron-lattice coupling (polaronic effect) is also taken into account both, in fixing the parameters of the model potential and also in the computation of binding energies. It is shown that the central cell effects are important especially for magnetic fields of the order of y = 100. The contribution from the electronlattice coupling is small and seen to decrease with the increase of magnetic field in confirmation with previous works. The central cell effect enhances the electron-lattice coupling appreciably, the enhancement being 30 to l OOyo for the range of magnetic fields investigated. Mit Variationsrechnung werden die Bindungsenergien von P-Donatoren in Si und Si-und SDonatoren in GaP auf Kationen bzw. Anionenplgtzen im starken Magnetfeld berechnet. DieZentralzelleneffekte werden mit einem Yukawapotential beriicksichtigt und seine Einflusse auf die Ionisierungsenergien ftir verschiedene Magnetfelder erhalten. In GaP wird die ElektronenGitterkopplung (Polaroneffekt) ebenfalls beriicksichtigt, sowohl bei der Festlegung der Parameter des Modellpotentials als auch bei der Berechnung der Bindungsenergien. Es wird gezeigt, daI3 die Zentralzelleneffekte besonders wesentlich sind fur Magnetfelder der GroBenordnung y = 100.Der Beitrag der Elektronen-Gitterkopplung ist gering und nimmt mit wachsendem Magnetfeld in tfbereinstimmung mit friiheren Arbeiten ab. Der Zentralzelleneffekt erhoht die ElektronenGitterkopplung wesentlich, die Erhohung betragt 30 bis l OOyo fur den untersuchten Magnetfeldbereich.

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Section: Resultsmentioning

confidence: 97%

Shallow Donor Binding Energies in Semiconductors in a Magnetic Field

Sukumar

Navaneethakrishnan

1989

Physica Status Solidi (b)

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“…The results are presented in reduced atomic units (a.u*) which correspond to a length unit of the e¡ective Bohr radius a* and an energy of the e¡ective Rydberg R*. We have considered the case of ZnSe/ZnCdTe QWW structure, we have used: m Ã 0:16m e and e 0 9:42 [23] (R Ã 24:53 meV, a Ã 31:15 Ð). For the comparison with the literature, we choose the case of GaAs/GaAlAs QWW which the parameters used are: m Ã 0:067m e and e 0 12:5 [3] (R Ã 5:83 meV and a Ã 98:7 Ð).…”

Section: Resultsmentioning

confidence: 99%

“…A comparison with our previous work [1] (In¢nite-barrier case) and the numerical results and discussions are presented in Section 3. For application, we will use QWW made out of ZnSe (ZnSe/ZnCdSe) a 0 0:448 [23] and a QWW made of GaAs a 0 0:067 (GaAs/GaAlAs) [13] for comparison with the literature.…”

Section: Introductionmentioning

confidence: 99%

Polaron and Finite-Barrier Effects on Polarizability of Shallow Donors in Quantum Well Wires

Filali¹,

Zorkani²

2002

Phys. Scr.

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Polarizability and ground state binding energy values are estimated of an electron bound to a donor confined to move in quantum well wire (QWW) within a variational calculation in the effective mass approximation. The calculations have been performed by using suitable variational wave functions for finite confinement potentials. We present our results for the polarizability as a function of the size of the wire. A comparison with the infinite potential case is presented. The electron-longitudinal optical (LO) phonon interaction is taken into account using the adiabatic approximation. It is found that the polaronic effects decrease significantly the polarizability, increase with increasing wire size and are more pronounced in the case of finite QWW than in infinite QWW.

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“…The polarizability values are calculated using the following parameters: m* 0.16m e , e 0 9.42 suitable for wires made out of ZnSe [23]. The effective Rydberg Ry * 24X53 meV and the effective Bohr radius a * 31X15 # e define the relevant energy and length scale, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…This paper is organized as follows: In Section 2 we present the general formalism, we deduce the expressions for the donor binding energy and polarizability of shallow polaron donors as a function of the wire width. The numerical results and discussions are presented in Section 3 with an application to a wire made out of ZnSe (a 0 0.448) [23].…”

Section: Introductionmentioning

confidence: 99%

Polaron and Form Effects on the Polarizabilities of Shallow Donors in Quantum Well Wires

Zorkani¹,

Filali²

1999

phys. stat. sol. (b)

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Polarizability and binding energy values are estimated for a shallow donor confined to move in a quantum well wire with a rectangular and square cross-section. We present our results for the polarizability as a function of the size of the wire. The electron±longitudinal optical (LO) phonon interaction is taken into account using the adiabatic approximation. It is found that the polaronic effects decrease significantly the polarizability and increase with increasing wire size.

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Polarizability of Donors in Polar Semiconductors. Effect of a Weak Magnetic Field

Cited by 6 publications

References 23 publications

Shallow Donor Binding Energies in Semiconductors in a Magnetic Field

Shallow Donor Binding Energies in Semiconductors in a Magnetic Field

Polaron and Finite-Barrier Effects on Polarizability of Shallow Donors in Quantum Well Wires

Polaron and Form Effects on the Polarizabilities of Shallow Donors in Quantum Well Wires

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