First-principles study of polar LaAlO (001) surface stabilization by point defects

Seo, Hosung; Demkov, Alexander A.

doi:10.1103/physrevb.84.045440

Cited by 38 publications

(40 citation statements)

References 54 publications

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“…The SZVP basis set produces tilt angles 30% lower than those observed by plane wave calculations 72 which is very similar to the behavior we observed in the case of STO; we attribute this to the use of localized basis sets.…”

Section: B Laalosupporting

confidence: 86%

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Structural phase transitions of the metal oxide perovskites SrTiO3, LaAlO3, and LaTiO3studied with a scree

et al. 2013

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We have investigated the structural phase transitions of the transition metal oxide perovskites SrTiO 3 , LaAlO 3 , and LaTiO 3 using the screened hybrid density functional of Heyd, Scuseria, and Ernzerhof (HSE06). We show that HSE06-computed lattice parameters, octahedral tilts, and rotations, as well as electronic properties, are significantly improved over semilocal functionals. We predict the crystal-field splitting ( CF ) resulting from the structural phase transition in SrTiO 3 and LaAlO 3 to be 3 meV and 10 meV, respectively, in excellent agreement with experimental results. HSE06 identifies correctly LaTiO 3 in the magnetic states as a Mott insulator. Also, it predicts that the GdFeO 3 -type distortion in nonmagnetic LaTiO 3 will induce a large CF of 410 meV. This large crystal-field splitting associated with the large magnetic moment found in the G-type antiferromagnetic state suggests that LaTiO 3 has an induced orbital order, which is confirmed by the visualization of the highest occupied orbitals. These results strongly indicate that HSE06 is capable of efficiently and accurately modeling perovskite oxides and promises to efficiently capture the physics at their heterointerfaces.

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Section: B Laalosupporting

confidence: 86%

“…17 In the low-temperature rhombohedral phase, the LSDA and PBE lattice parameters tend to be higher than previous plane wave calculations. [70][71][72] The octahedral tilt angle for both LSDA and PBE is about 4…”

Section: B Laalomentioning

confidence: 99%

Structural phase transitions of the metal oxide perovskites SrTiO3, LaAlO3, and LaTiO3studied with a scree

et al. 2013

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“…7,8,10 In this article, we discuss the electronic structure of a (111) bilayer of LaNiO 3 sandwiched between sufficiently large regions of LaAlO 3 . LaAlO 3 is a wide band-gap insulator 13 with an experimentally determined gap of E g = 5.6 eV while LaNiO 3 is a paramagnetic metal in bulk. The formal valence of nickel is Ni 3+ which corresponds to a partially filled 3d-shell with an electronic configuration t 6 2g e 1 g , i.e.…”

Section: Introductionmentioning

confidence: 99%

Electronic structure of (LaNiO3)2/(LaAlO3)
Rüegg
¹
,
Mitra
²
,
Demkov
³

et al. 2012
Phys. Rev. B
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The electronic structure of a LaNiO3 bilayer grown along the [111] direction and confined between insulating layers of LaAlO3 is theoretically investigated using a combination of first principle calculations and effective multi-orbital lattice models. The LDA band structure is well reproduced by a tight-binding model for the Ni-eg orbitals defined on the buckled honeycomb lattice. We highlight peculiar properties of this model which include almost flat bands as well as linear and quadratic band crossing points. The effect of local correlations is discussed within the LDA+U scheme and within the Hartree-Fock approximation for interacting multi-orbital lattice models. Over a wide range of interaction parameters we find that a ferromagnetic phase is energetically favored. We discuss the possibility of additional orbital order which could stabilize a spontaneous Chern insulator with chiral edge modes or a staggered orbital phase with a √ 3 × √ 3 reconstruction of the unit cell. By studying an interacting nickel-oxygen lattice model we find that the stability of these orbitally ordered phases also depends on the value of the charge-transfer energy. Controlling the charge-transfer energy might therefore be an important step towards engineering exotic electronic phases in certain classes of oxide heterostructures.

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“…A set of boundary conditions can be considered for the chemical potentials of the elements to provide a stability region for a host material within which the theoretical defect formation energies can be compared to each other. 63 One should also keep in mind that there might be other practical limitations in experimental samples. For instance, judicious engineering of the Fermi-level position by doping might be required to obtain a defect in a specifi c charge and spin state.…”

Section: Building a Defect From The Ground Up In Silicomentioning

confidence: 99%

“…The stabilities of different defects in various charge and spin states can be determined by calculating the defect formation energies, 74 which are thermodynamic free energies as functions of the chemical potentials of the electron and the constituent elements. 63 The theoretical chemical potentials could be estimated for given experimental conditions, which is, however, nontrivial. Instead, the chemical potentials are usually treated as theoretical parameters in DFT calculations.…”

Section: Building a Defect From The Ground Up In Silicomentioning

confidence: 99%

Designing defect spins for wafer-scale quantum technologies

et al. 2015

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Many of the conceptual moorings that led to a revolution in microelectronic and optical device technologies in the second half of the 20th century stem directly from the development of quantum physics only a few decades earlier. For instance, the early realization that matter at its most basic level exhibits wavelike properties permeates the physics of semiconductors and is critical to understanding the function of transistors. The notion that light comes "quantized" as particles that can propagate in a phase-coherent manner led to the invention of the laser.Such inventions built on new physical understandings that diverged signifi cantly from previous nonquantum descriptions of nature, but they did not capitalize fully on what many perceive as the most surprising aspects of quantum mechanics. Core aspects of the quantum world such as quantum superposition, the uncertainty principle, and quantum entanglement are probabilistic by nature and lead to behavior that frequently appears contrary to human intuition. Nevertheless, these phenomena still follow well-defi ned mathematical rules that make them predictable and controllable.This key realization-that such "spooky" quantum behaviors can actually be purposefully manipulated-came as the result of extensive experimental and theoretical research during the second half of the 20th century. It has since inspired a period of rapid technological exploration and development that promises to reframe the limits of modern information technology. This "second quantum revolution" aims to produce technologies such as uncrackable secure telecommunications, powerful computers capable of simulating advanced quantum materials, and ultrasensitive sensors. Researchers are exploring diverse candidate systems for implementing these emerging quantum technologies. In this article, we discuss one particularly promising materials paradigm that could lead to semiconductor-based implementations: electronic spins bound to point defects. Perhaps counterintuitively, although such semiconductor point defects are often regarded as undesirable sources of disorder in traditional Designing defect spins for wafer-scale quantum technologiesWilliam F. Koehl , Hosung Seo , Giulia Galli , and David D. AwschalomThe past decade has seen remarkable progress in the development of the nitrogen-vacancy (NV) defect center in diamond, which is one of the leading candidates for quantum information technologies. The success of the NV center as a solid-state qubit has stimulated an active search for similar defect spins in other technologically important and mature semiconductors, such as silicon carbide. If successfully combined with the advanced microfabrication techniques available to such materials, coherent quantum control of defect spins could potentially lead to semiconductor-based, wafer-scale quantum technologies that make use of exotic quantum mechanical phenomena like entanglement. In this article, we describe the robust spin property of the NV center and the current status of NV center research for qua...

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First-principles study of polar LaAlO (001) surface stabilization by point defects

Cited by 38 publications

References 54 publications

Structural phase transitions of the metal oxide perovskites SrTiO3, LaAlO3, and LaTiO3studied with a scree

Structural phase transitions of the metal oxide perovskites SrTiO3, LaAlO3, and LaTiO3studied with a scree

Electronic structure of (LaNiO3)2/(LaAlO3)
Rüegg
¹
,
Mitra
²
,
Demkov
³

et al. 2012
Phys. Rev. B
Self Cite
77
3
144
0
View full text Add to dashboard Cite

Designing defect spins for wafer-scale quantum technologies

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First-principles study of polar LaAlO (001) surface stabilization by point defects

Cited by 38 publications

References 54 publications

Structural phase transitions of the metal oxide perovskites SrTiO3, LaAlO3, and LaTiO3studied with a scree

Structural phase transitions of the metal oxide perovskites SrTiO3, LaAlO3, and LaTiO3studied with a scree

Electronic structure of (LaNiO3)2/(LaAlO3)Rüegg1, Mitra2, Demkov3 et al. 2012Phys. Rev. BSelf Cite7731440View full textAdd to dashboardCite

Designing defect spins for wafer-scale quantum technologies

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Electronic structure of (LaNiO3)2/(LaAlO3)
Rüegg
¹
,
Mitra
²
,
Demkov
³

et al. 2012
Phys. Rev. B
Self Cite
77
3
144
0
View full text Add to dashboard Cite