p
          -type conductivity in cubic (Ga,Mn)N thin films

Edmonds, K. W.; Novikov, S.V.; Sawicki, M.; Campion, R. P.; Staddon, C. R.; Giddings, A. D.; Zhao, Lixia; Wang, K. Y.; Dietl, T.; Foxon, C. T.; Gallagher, B. L.

doi:10.1063/1.1900924

Cited by 37 publications

(24 citation statements)

References 32 publications

(50 reference statements)

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“…In addition to (Ga,Mn)As, (Zn,Mn)Te:N, and related systems, recent indications of ferromagnetism in p- (Ga,Mn)N [98,99] and p-(Ga,Mn)P [100], appear to support the conclusion about the importance of delocalized or weakly localized carriers in mediating efficient spin-spin interactions. However, in those and other experimentally relevant cases, non-uniformity associated with hole localization, and perhaps with competing ferromagnetic and antiferromagnetic interactions, is seen to affect strongly ferromagnetic properties.…”

Section: Discussionmentioning

confidence: 83%

High Temperature Ferromagnetism and Nano-Scale Phase Separations in Diluted Magnetic Semiconductors and Oxides

Dietl

2007

Acta Phys. Pol. A

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In this paper the present understanding of the origin of ferromagnetic response that has been detected in a number of diluted magnetic semiconductors and diluted magnetic oxides at room temperature is outlined. It is argued that in these systems, owing to a typically small solubility of magnetic ions, crystallographic or chemical phase separation into regions with a large and a small concentration of magnetic component takes place. The ferromagnetic signatures then come from the regions with a large concentration of magnetic ions, which show non-zero spontaneous magnetization up to the blocking temperature, whose magnitude is proportional to the nanocrystal volume and magnetic anisotropy. Novel methods enabling a control of nano-assembling of magnetic nanocrystals in non-conducting matrices as well as possible functionalities of these spatially modulated magnetic systems are described. We also discuss phase separations into paramagnetic and ferromagnetic regions, which are driven by the Anderson-Mott localization and/or competing ferromagnetic and antiferromagnetic interactions. Finally, the question whether the high temperature ferromagnetism is possible in materials without magnetic ions is addressed.

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Section: Discussionmentioning

confidence: 83%

High Temperature Ferromagnetism and Nano-Scale Phase Separations in Diluted Magnetic Semiconductors and Oxides

Dietl

2007

Acta Phys. Pol. A

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“…Reports of ͑Ga,Mn͒N epilayers synthesized in cubic and hexagonal crystal structures, of p-type and n-type ferromagnetic ͑Ga,Mn͒N, and of multiple ferromagnetic phases in one material all add to the complex phenomenology of these wide-gap DMSs ͑Korotov et al, 2001;Graf et al, 2002;Graf, Gjukic, et al, 2003;Arkun et al, 2004;Edmonds, Novikov, et al, 2005;Hwang et al, 2005;Sawicki, Dietl, et al, 2005͒. Uncertainties apply also to the interpretation of ferromagnetism seen in the ͑Ga,Mn͒P samples studied to date, which have been prepared by post-MBE ion implantation of Mn followed by rapid thermal ͑Theodor-opoulou et al., 2002;Poddar et al, 2005͒ or pulse-lasermelting annealing ͑Scarpulla et al, 2005͒. Experiments in these materials have not yet established unambiguously the nature of magnetic interactions in the ͑III, Mn͒P compounds.…”

Section: B Search For High Transition Temperaturesmentioning

confidence: 99%

Theory of ferromagnetic (III,Mn)V semiconductors

et al. 2006

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The body of research on ͑III,Mn͒V diluted magnetic semiconductors ͑DMSs͒ initiated during the 1990s has concentrated on three major fronts: ͑i͒ the microscopic origins and fundamental physics of the ferromagnetism that occurs in these systems, ͑ii͒ the materials science of growth and defects, and ͑iii͒ the development of spintronic devices with new functionalities. This article reviews the current status of the field, concentrating on the first two, more mature research directions. From the fundamental point of view, ͑Ga,Mn͒As and several other ͑III,Mn͒V DMSs are now regarded as textbook examples of a rare class of robust ferromagnets with dilute magnetic moments coupled by delocalized charge carriers. Both local moments and itinerant holes are provided by Mn, which makes the systems particularly favorable for realizing this unusual ordered state. Advances in growth and postgrowth-treatment techniques have played a central role in the field, often pushing the limits of dilute Mn-moment densities and the uniformity and purity of materials far beyond those allowed by equilibrium thermodynamics. In ͑III,Mn͒V compounds, material quality and magnetic properties are intimately connected. This review focuses on the theoretical understanding of the origins of ferromagnetism and basic structural, magnetic, magnetotransport, and magneto-optical characteristics of simple ͑III,Mn͒V epilayers, with the main emphasis on ͑Ga,Mn͒As. Conclusions are arrived at based on an extensive literature covering results of complementary ab initio and effective Hamiltonian computational techniques, and on comparisons between theory and experiment. The applicability of ferromagnetic semiconductors in microelectronic technologies requires increasing Curie temperatures from the current record of 173 K in ͑Ga,Mn͒As epilayers to above room temperature. The issue of whether or not this is a realistic expectation for ͑III,Mn͒V DMSs is a central question in the field and motivates many of the analyses presented in this review.

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“…One of the approaches to eliminate these internal fields is the utilization of metastable non polar zinc-blende (zb) structures. It has also been reported that zb group IIInitrides have a quantum confined Stark effect in lowdimensional heterostructures 6 , high p-type conductivity in (Ga,Mn)N thin films 7 and negative differential resistance (NDR) at the resonant tunneling diode of the cubic Al(Ga)N/GaN 8,9 . Consequently a lot of interest is constantly attracted by this family of materials.…”

Section: Introductionmentioning

confidence: 99%

Electron-electron and electron-phonon correlation effects on the finite-temperature electronic and optical properties of zinc-blende GaN

Kawai

Yamashita²,

Cannuccia³

et al. 2014

Phys. Rev. B

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We combine the effect of the electron-electron and electron-phonon interactions to study the electronic and optical properties of zb-GaN. We show that only by treating the two effects at the same time it is possible to obtain an unprecedented agreement of the zero and finite-temperature electronic gaps and absorption spectra with the experimental results. Compared to the state-ofthe-art results our calculations predict a large effect on the main absorption peak position and width as well as on the overall absorption lineshape. These important modifications are traced back to the combined electron-phonon damping mechanism and non uniform GW level corrections. Our results demonstrate the importance of treating on equal footing the electron and phonon mediated correlation effects to obtain an accurate description of the III-nitrides group physical properties.

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p -type conductivity in cubic (Ga,Mn)N thin films

Cited by 37 publications

References 32 publications

High Temperature Ferromagnetism and Nano-Scale Phase Separations in Diluted Magnetic Semiconductors and Oxides

High Temperature Ferromagnetism and Nano-Scale Phase Separations in Diluted Magnetic Semiconductors and Oxides

Theory of ferromagnetic (III,Mn)V semiconductors

Electron-electron and electron-phonon correlation effects on the finite-temperature electronic and optical properties of zinc-blende GaN

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