Kirsten Govaerts scite author profile

In this work we have investigated the structural and electronic properties of SnO, which is built up from layers kept together by van der Waals (vdW) forces. The combination of a vdW functional within density functional theory (DFT) and quasiparticle band structure calculations within the GW approximation provides accurate values for the lattice parameters, atomic positions, and the electronic band structure including the fundamental (indirect) and the optical (direct) band gap without the need of experimental or empirical input. A systematic comparison is made between different levels of self-consistency within the GW approach {following the scheme of Shishkin et al. [Phys. Rev. B 75, 235102 (2007)]} and the results are compared with DFT and hybrid functional results. Furthermore, the effect of the vdW-corrected functional as a starting point for the GW calculation of the band gap has been investigated. Finally, we studied the effect of the vdW functional on the electron charge density.

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Erratum: Effect of Bi bilayers on the topological states ofBi2Se3: A first-principles study [Phys. Rev. B90, 155124 (2014)]

Govaerts¹,

Park²,

Beule³

et al. 2015

Phys. Rev. B

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Effect of Bi bilayers on the topological states ofBi2Se3: A first-principles study

et al. 2014

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Bi 2 Se 3 is a three-dimensional topological insulator which has been extensively studied because it has a single Dirac cone on the surface, inside a relatively large bulk band gap. However, the effect of two-dimensional topological insulator Bi bilayers on the properties of Bi 2 Se 3 and vice versa, has not been explored much. Bi bilayers are often present between the quintuple layers of Bi 2 Se 3 , since (Bi 2 ) n (Bi 2 Se 3 ) m form stable ground-state structures. Moreover, Bi 2 Se 3 is a good substrate for growing ultrathin Bi bilayers. By first-principles techniques, we first show that there is no preferable surface termination by either Bi or Se. Next, we investigate the electronic structure of Bi bilayers on top of, or inside a Bi 2 Se 3 slab. If the Bi bilayers are on top, we observe a charge transfer to the quintuple layers that increases the binding energy of the surface Dirac cones. The extra states, originating from the Bi bilayers, were declared to form a topological Dirac cone, but here we show that these are ordinary Rashba-split states. This result, together with the appearance of a new Dirac cone that is localized slightly deeper, might necessitate the reinterpretation of several experimental results. When the Bi bilayers are located inside the Bi 2 Se 3 slab, they tend to split the slab into two topological insulators with clear surface states. Interface states can also be observed, but an energy gap persists because of strong coupling between the neighboring quintuple layers and the Bi bilayers.

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Stability of Sb-Te layered structures: First-principles study

Govaerts¹,

Sluiter²,

Partoens³

et al. 2012

Phys. Rev. B

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Using an effective one-dimensional cluster expansion in combination with first-principles electronic structure calculations we have studied the energetics and electronic properties of Sb-Te layered systems. For a Te concentration between 0 and 60 at. % an almost continuous series of metastable structures is obtained consisting of consecutive Sb bilayers next to consecutive Sb 2 Te 3 units, with the general formula (Sb 2 ) n (Sb 2 Te 3 ) m (n,m = 1,2, . . .). Between 60 and 100 at. % no stable structures are found. We account explicitly for the weak van der Waals bonding between Sb bilayers and Sb 2 Te 3 units by using a recently developed functional, which strongly improves the interlayer bonding distances. At T = 0 K, no evidence is found for the existence of two separate single-phase regions δ and γ and a two-phase region δ + γ . Metastable compounds with a Te concentration between 0 and 40 at. % are semimetallic, whereas compounds with a Te concentration between 50 and 60 at. % are semiconducting. Compounds with an odd number of Sb layers are metallic and have a much higher formation energy than those with an even number of consecutive Sb layers, thereby favoring the formation of Sb bilayers.

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Extended homologous series of Sn–O layered systems: A first-principles study

Govaerts

Partoens

Lamoen

2016

Solid State Communications

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