Optical response of a topological-insulator–quantum-dot hybrid interacting with a probe electric field

Castro-Enríquez, L. A.; Quezada, L. F.; Martín-Ruiz, A.

doi:10.1103/physreva.102.013720

Cited by 25 publications

(16 citation statements)

References 81 publications

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“…Some works have been done in this spirit. For example, some particular classical electrodynamics configurations both in TIs [34][35][36][37][38][39] and WSMs [40][41][42][43][44], the frequency shift induced by the Casimir-Polder interaction between atoms and TIs [45][46][47], and the optical absorption of semiconductor-TI quantum dots [48][49][50], among others. Moved by these researches, in this paper we investigate the effects of a Weyl semimetallic phase upon hydrogenlike ions near its surface, taking into account the modifications arising from the topological nontriviality of the material.…”

Section: Introductionmentioning

confidence: 99%

Ground state and polarization of an hydrogen-like atom near a Weyl semimetal

Castaño-Yepes¹,

Nader²,

Martín-Ruiz³

2022

Preprint

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In this paper we study the effects of a topological Weyl semimetal (WSM) upon the ground state and polarization of an hydrogen-like atom near its surface. The WSM is assumed to be in the equilibrium state and at the neutrality point, such that the interaction between the atomic charges and the material is fully described (in the non retarded regime) by axion electrodynamics, which is an experimentally observable signature of the anomalous Hall effect in the bulk of the WSM. The atom-WSM interaction provides additional contributions to the Casimir-Polder potential thus modifying the energy spectra and wave function, which now became distance dependent. Using variational methods, we solve the corresponding Schrödinger equation for the atomic electron. The ground state and the polarization are analyzed as a function of the atom-surface distance, and we directly observe the effects of the nontrivial topology of the material by comparing our results with that of a topologically trivial sample. We also study the impact of the medium's permittivity by assuming a hydrogen atom in vacuum and a donor impurity in gallium arsenide (GaAs). We found that the topological interaction behaves as an effective-attractive charge so that the electronic cloud tends to be polarized to the interface of materials. Moreover, the loss of wave-function normalization is interpreted as a critical location from below which the bound state is broken.

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Section: Introductionmentioning

confidence: 99%

Ground state and polarization of an hydrogen-like atom near a Weyl semimetal

Castaño-Yepes¹,

Nader²,

Martín-Ruiz³

2022

Preprint

Self Cite

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“…In recent years, nanoparticles based on TIs have been thoroughly investigated for their interest in photonics, optically controlled quantum memory and quantum computing [8][9][10][11][12][13][14]. Surface states * Corresponding author show little sensitivity to disorder, which is beneficial for optical applications at the nanoscale [10].…”

Section: Introductionmentioning

confidence: 99%

Tailoring topological states of core–shell nanoparticles

Martínez-Strasser

Baba²,

Díaz‐Fernández³

et al. 2022

Physica E: Low-dimensional Systems and Nanostructures

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In this work we investigate novel spherical core-shell nanoparticles with band inversion. The core and the embedding medium are normal semiconductors while the shell material is assumed to be a topological insulator. The envelope functions are found to satisfy a Dirac-like equation that can be solved in a closed form. The core-shell nanoparticle supports midgap bound states located at both interfaces due to band inversion. These states are robust since they are topologically protected. The energy spectrum presents mirror symmetry due to the chiral symmetry of the Dirac-like Hamiltonian. As a major result, we show that the thickness of the shell acts as an additional parameter for the fine tuning of the energy levels, which paves the way for electronics and optoelectronics applications.

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“…The TDS Sn microdots could potentially be coupled through graphene or quantum dots towards quantum device applications. [36][37][38] . They also demonstrated optical absorption at ∼1250-1750 nm wavelength, which may enable quantum state switching by optical excitation 39 at 1310-1550 nm telecommunication wavelengths, potentially through integration with silicon photonics.…”

Section: Introductionmentioning

confidence: 99%

Reversed Phase Transformation of β→α-Sn at Elevated Temperatures towards Quantum Material Integration on Silicon

Covian

Liu

Gardener

et al. 2021

Preprint

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α-Sn and SnGe alloys have recently attracted much attention as a new family of topological quantum materials. However, bulk α-Sn is thermodynamically stable only at <13°C. Moreover, scalable integration of α-Sn quantum materials/devices on Si has been hindered by a large lattice mismatch. To address these challenges, we demonstrate compressively strained α-Sn doped with 2-4 at.% Ge on a native oxide layer on Si, grown at 300-500°C through a reversed β-to-α-Sn phase transformation without relying on epitaxy. The size of α-Sn microdots reaches up to 200 nm, ~10x larger than the upper size limit for α-Sn formation reported before. Furthermore, the compressive strain makes it one of the few candidates for 3D topological Dirac semimetals with interesting applications in spintronics. We find that Ge-rich GeSn nanoclusters in the as-deposited materials seeded the reversed β-to-α-Sn transition at elevated temperatures. This process can be further optimized for SnGe quantum material and device integration on Si.

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Optical response of a topological-insulator–quantum-dot hybrid interacting with a probe electric field

Cited by 25 publications

References 81 publications

Ground state and polarization of an hydrogen-like atom near a Weyl semimetal

Ground state and polarization of an hydrogen-like atom near a Weyl semimetal

Tailoring topological states of core–shell nanoparticles

Reversed Phase Transformation of β→α-Sn at Elevated Temperatures towards Quantum Material Integration on Silicon

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