Binding energy of impurity states in a parabolic quantum dot in a strong magnetic field

Peter, A. John; Gnanasekar, K. I.; Navaneethakrishnan, K.

doi:10.1002/pssb.200440087

Cited by 24 publications

(12 citation statements)

References 39 publications

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“…In general, in all low dimensional heterostructures, the magnetic field increases with the binding energy. 21 The insert figure brings out the effect of applied magnetic field on the hydrogenic donor impurity. The donor diamagnetic shift as a function of magnetic field for the GaMnAs/Ga 0 4 Al 0 6 As quantum dot is shown here.…”

Section: Resultsmentioning

confidence: 99%

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga_0.4 Al_0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Lalitha¹,

Peter²

2012

j adv phys

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Magnetic field induced hydrogenic donor binding energy as a function of dot radius in a GaMnAs/Ga 0.4 Al 0.6 As quantum dot is calculated including the exchange interaction of Mn alloy content with an itinerant carrier. Calculations are performed by varying its dot radius, for various Mn incorporation in GaMnAs material within a single band effective mass approximation using variational method. The spin polaronic energy of donor impurity for different Mn 2+ is evaluated for different dot radii using a mean field theory in the presence of magnetic field strength. The effective g-factor of conduction band electron with the geometrical confinement is computed in the influence of magnetic field. The exchange coupling constant is calculated for various magnetic field. The results show that the s-d exchange interaction in the GaMnAs/Ga 0.4 Al 0.6 As quantum dot has a strong dependence on spatial confinement and the Mn alloy content. The magnetic confinement is dominant for larger dot sizes whereas the Mn alloy content has more pronounced for the smaller dots. The g-factor of conduction band electrons is considerably different from the free electron value. Our results are in good agreement with the other investigators.

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Section: Resultsmentioning

confidence: 99%

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga_0.4 Al_0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Lalitha¹,

Peter²

2012

j adv phys

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“…The variation of band gap differences is taken from the Ref. [16] and the strain-induced potential for the conduction band in the influence of pressure is given by 17 V C strian P = a c xx P + yy P + zz P (6) where a c is the deformation potential constant of conduction band, xx P = yy P = a 0 P − a P /a P where a 0 P and a P are the pressure dependent lattice parameters of bulk CdTe (6.481 nm) and MnTe (6.334 nm) respectively and zz P = −2C 12 P /C 11 P xx P , the values of parameters C 11 and C 12 are 5 66 + 0 36 GPa and 3 96 + 0 44 GPa. 18 19 The strain-induced potential for the valence band in the influence of pressure can be written as 20…”

Section: Exciton Binding Energymentioning

confidence: 99%

Effects of Hydrostatic Pressure on Optical Absorption and Refractive Index Changes of Exciton in Semimagnetic CdMnTe Quantum Wells

Leonora¹,

Peter²

2012

Jnl of Comp & Theo Nano

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Pressure induced binding energy of a confined exciton in a Cd 1−x out Mn x out Te/Cd 1−x in Mn x in Te/ Cd 1−x out Mn x out Te diluted magnetic quantum well is investigated. Calculations are performed for various Mn incorporation into Cd 1−x Mn x Te material within a single band effective mass approximation using variational method. Spin polaronic shifts are estimated using mean field theory for different Mn concentration and the well sizes. A theoretical study of diluted magnetic semiconductors treating the local sp-d exchange interaction J between the itinerant carriers and the Mn electrons is treated within a realistic band structure. The total optical absorption and the refractive index changes as a function of normalized photon energy in the presence of pressure and the Mn ion content are analysed. The optical absorption coefficients and the refractive index changes strongly depend on the incident optical intensity and the pressure. The occurred blue shift of the resonant peak due to the pressure gives the information about the variation of two energy levels in the quantum well width. The optical absorption coefficients and the refractive index changes strongly depend on the incident optical intensity and the pressure and Mn content.

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“…Peter et al [35] and Wu and Wan [37] investigated the electronic structure and binding energies of parabolic and spherical QDs in a strong external magnetic field by using variational approach. Zhang et al [40] and Seddik et al [42] studied the field effects on the optical properties in parabolic QDs in the presence of electric and magnetic fields.…”

Section: Introductionmentioning

confidence: 99%

“…The symmetry of the impurity states, the nature of the wave functions leading to more complicated changes of the binding energy and the other properties of impurity energy states can be modified by application of a magnetic field to QDs. Therefore, several studies [33][34][35][36][37][38][39][40][41][42][43][44][45][46] are performed on the electronic structures, energy states, binding energies, optical and other properties of QDs in the presence of a magnetic field.…”

Section: Introductionmentioning

confidence: 99%

Calculation of Zeeman splitting and Zeeman transition energies of spherical quantum dot in uniform magnetic field

et al. 2016

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Binding energy of impurity states in a parabolic quantum dot in a strong magnetic field

Cited by 24 publications

References 39 publications

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga_0.4 Al_0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga_0.4 Al_0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Effects of Hydrostatic Pressure on Optical Absorption and Refractive Index Changes of Exciton in Semimagnetic CdMnTe Quantum Wells

Calculation of Zeeman splitting and Zeeman transition energies of spherical quantum dot in uniform magnetic field

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Binding energy of impurity states in a parabolic quantum dot in a strong magnetic field

Cited by 24 publications

References 39 publications

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga0.4 Al0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga0.4 Al0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Effects of Hydrostatic Pressure on Optical Absorption and Refractive Index Changes of Exciton in Semimagnetic CdMnTe Quantum Wells

Calculation of Zeeman splitting and Zeeman transition energies of spherical quantum dot in uniform magnetic field

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Product

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Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga_0.4 Al_0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement

Effect of s – d Exchange with an Itinerant Carrier in a GaMnAs/Ga_0.4 Al_0.6 As Quantum Dot: Effects of Magnetic Field and Spatial Confinement