Interband transitions of quantum wells and device structures containing Ga(N, As) and (Ga, In)(N, As)

Klar, Peter J.; Grüning, H.; Heimbrodt, W.; Weiser, G.; Koch, J.; Volz, Kerstin; Stolz, W.; Koch, S. W.; Tomić, Stanko; Choulis, Stelios A.; Hosea, T. J. C.; O’Reilly, Eoin P.; Hofmann, Martin R.; Hader, J.; Moloney, Jerome V.

doi:10.1088/0268-1242/17/8/312

Cited by 44 publications

(41 citation statements)

References 91 publications

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“…The arrows indicate the effective band gap for each sample (obtained by least-squares fitting using Aspnes's lineshape model [7]). Examination of the data clearly reveals two trends as a function of increasing N-content: i) a rapid red-shift in the transition energies similar to the results found in prior studies on thick In y Ga 1-y As 1-x N x epilayers [3] and on a variety of dilute-N III-V MQWs [2]; (ii) a strong broadening in the line-shapes: this indicates that adding N increases the inhomogeneous broadening of the QW transitions [4].…”

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confidence: 76%

“…In this new class of dilute-N III-N-V semiconductor alloys, modification in the band structure is achieved by N forming localised states which interact with the conduction band (CB) edge of the host semiconductor [3]. To investigate this complex band formation, modulation spectroscopy as a function of pressure, has proved to be a very useful tool [2][3][4]. Previously we reported the dramatic effects of increasing N-incorporation on the quantum well (QW) interband energies including negative bandgap-bowing, smaller total temperature variation, and strong decrease in the rate of pressure-shift (reduced linear shifts with larger sub-linear components) [4].…”

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confidence: 99%

“…InGaNAs differs considerably from the conventional III-V alloys and exhibits striking new properties [2], some of which are reviewed in this paper. In this new class of dilute-N III-N-V semiconductor alloys, modification in the band structure is achieved by N forming localised states which interact with the conduction band (CB) edge of the host semiconductor [3].…”

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Pressure and k · p studies of band parameters in dilute‐N GaInNAs/GaAs multiple quantum wells

Choulis

Hosea

Tomić

et al. 2003

Physica Status Solidi (b)

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We report pressure dependent photomodulated reflectance (PR) measurements on a series of dilute-N InGaNAs/GaAs multiple quantum wells (MQWs). Our experimental results indicate the presence of important N-related disorder effects due to different nearest-neighbour N-cation configurations The quantum well transition energies obtained from the PR spectra are modelled using a realistic 10-band k · p Hamiltonian that includes tight-binding-based energies and coupling parameters for the N-levels. By matching experiment with theory we are able to determine accurately the band structure and thus predict some important material parameters for dilute-N InGaAsN alloys.Introduction The ability to calculate effective masses and conduction band offsets is important for designing laser devices. Accurate knowledge of the band structure of the component materials is the first step to identifying these parameters. Although this can be a much easier procedure for well-known materials, it is much more difficult task for novel systems such as InGaNAs [1].InGaNAs differs considerably from the conventional III-V alloys and exhibits striking new properties [2], some of which are reviewed in this paper. In this new class of dilute-N III-N-V semiconductor alloys, modification in the band structure is achieved by N forming localised states which interact with the conduction band (CB) edge of the host semiconductor [3]. To investigate this complex band formation, modulation spectroscopy as a function of pressure, has proved to be a very useful tool [2][3][4]. Previously we reported the dramatic effects of increasing N-incorporation on the quantum well (QW) interband energies including negative bandgap-bowing, smaller total temperature variation, and strong decrease in the rate of pressure-shift (reduced linear shifts with larger sub-linear components) [4]. Here, we seek to gain a more comprehensive picture of the influence of nitrogen on the confined levels in In y Ga 1-y As 1-x N x /GaAs multiple quantum wells (QWs), including the effects of disorder due to different nearest-neighbour N-cation configurations [5]. We determine the band structure of dilute-N InGaNAs/GaAs (0 ≤ x ≤ 4.3%) MQWs, by combined pressure dependent photomodulated reflectance (PR) measurements and theoretical k · p studies. The accurate determination of the band-structure allows us to

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confidence: 76%

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confidence: 99%

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Pressure and k · p studies of band parameters in dilute‐N GaInNAs/GaAs multiple quantum wells

Choulis

Hosea

Tomić

et al. 2003

Physica Status Solidi (b)

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“…Detailed studies on the nearest-neighbor environment of the substitutional N atoms in GaInNAs have shown that the fundamental band-gap energy in quaternary dilute nitride alloys is fairly sensitive to the local environmental conditions especially in the case of quantum well structures. 65,66 A more complicated modeling of the electronic structure based on pseudopotentials 67,68 requires a substantial computational effort. The numerical results are difficult to use.…”

Section: Band Anticrossingmentioning

confidence: 99%

New Developments in Dilute Nitride Semiconductor Research

Shan¹,

Walukiewicz²,

Yu³

et al. 2006

III-Nitride Semiconductor Materials

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“…The two approaches have been highly successful in describ-ing the band edge energies, and their variation upon annealing [17,18]. The BAC model has also been successfully applied to interpret photoreflectance (PR) measurements both of bulk and quantum well (QW) GaNAs samples at room temperature, identifying a higher energy feature (E + ) observed in bulk samples [16,19,20], and also providing a consistent interpretation of quantum well excited state transition energies across a wide range of samples, and as a function of hydrostatic pressure [21,22]. Despite the wide success of the BAC model, there has until recently been one significant set of experimental data which has remain unexplained, namely the observed composition dependence of the conduction band edge (CBE) effective mass in Ga(In)NAs alloys, in particular, at low temperatures.…”

Section: Introductionmentioning

confidence: 99%

Theory of electron confinement and electron effective mass in dilute nitride alloys and heterostructures

O’Reilly

Lindsay

Tomić

et al. 2004

Physica Status Solidi (b)

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The band-anti-crossing (BAC) model describes the strong band-gap bowing at low N composition x in Ga(In)N x As 1-x in terms of an interaction between the conduction band edge and a higher-lying band of localized nitrogen resonant states. We first present an analytical technique based on the BAC model to calculate electron energies in Ga(In)NAs square quantum well (QW) structures. We then show through detailed comparison with photoreflectance measurements that the BAC model successfully describes ground and excited state interband transition energies in bulk and QW GaNAs samples, both at ambient pressure and as a function of hydrostatic pressure. Turning to the conduction band dispersion, we find that the twolevel BAC model is insufficient, and must be modified to give a quantitative understanding of the unexpectedly large electron effective mass values observed in some GaNAs samples, which we attribute to hybridisation between the conduction band edge and nitrogen states close to the band edge. We predict a non-monotonic variation of electron mass with hydrostatic pressure in many GaNAs samples.

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Interband transitions of quantum wells and device structures containing Ga(N, As) and (Ga, In)(N, As)

Cited by 44 publications

References 91 publications

Pressure and k · p studies of band parameters in dilute‐N GaInNAs/GaAs multiple quantum wells

Pressure and k · p studies of band parameters in dilute‐N GaInNAs/GaAs multiple quantum wells

New Developments in Dilute Nitride Semiconductor Research

Theory of electron confinement and electron effective mass in dilute nitride alloys and heterostructures

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