Creating Tunable Quantum Corrals on a Rashba Surface Alloy

Jolie, Wouter; Hung, Tzu-Chao; Niggli, Lorena; Verlhac, Benjamin; Hauptmann, Nadine; Wegner, Daniel; Khajetoorians, Alexander A.

doi:10.1021/acsnano.2c00467

Cited by 13 publications

(12 citation statements)

References 37 publications

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“…Trivial errors in theoretical peak positions might be attributed to atomic vibrations at room temperature and the simplifications of the assumed potential, which are acceptable here for qualitative eigenwave analysis. Similar features have also been observed in STS maps for the InAsP/InP QDs, graphene QDs, and BiCu2 quantum corrals …”

Section: Resultssupporting

confidence: 79%

“…Similar features have also been observed in STS maps for the InAsP/InP QDs, 42 graphene QDs, 43 and BiCu2 quantum corrals. 44 Additional QD systems varying from 7.7 to 3.5 nm are shown in Figure S3 accompanied by their STS results, from which QDSs peculiar to β-phase Bi islands can be recognized. QD islands are formed during β-to-α phase transformation triggered by thermal annealing at 700 K. The dot size is determined by the initial β surface area and the sample annealing time, as detailed in the following paragraphs.…”

Section: ■ Introductionmentioning

confidence: 99%

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Phase Transformation-Induced Quantum Dot States on the Bi/Si(111) Surface

Chi

Nogami

Singh

2022

ACS Appl. Mater. Interfaces

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Nanopatterns at near atomic dimensions with controllable quantum dot states (QDSs) are promising candidates for the continued downscaling of electronic devices. Herein, we report a phase transition-induced QD system achieved on the √3 × √3-Bi/Si(111) surface reconstruction, which points the way to a novel strategy on QDS implementation. Combining scanning tunneling microscopy, scanning tunneling spectroscopy, and density functional theory (DFT) calculations, the structure, energy dispersion, and size effect on band gap of the QDs are measured and verified. As-created QDs can be manipulated with a dot size down to 2 nm via Bi phase transformation, which, in turn, is triggered by thermal annealing at 700 K. The transition mechanism is also supported by our DFT calculations, and an empirical analytical model is developed to predict the transformation kinetics.

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Section: Resultssupporting

confidence: 79%

Section: ■ Introductionmentioning

confidence: 99%

Phase Transformation-Induced Quantum Dot States on the Bi/Si(111) Surface

Chi

Nogami

Singh

2022

ACS Appl. Mater. Interfaces

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“…Considering that h -BN is known to induce an upshift of the Cu(111) surface state by about 0.11 eV due to the weak interaction with the h -BN overlayer, , our observed onset (∼ −0.32 V) of the confined states fits well to the suggestion that Cu(111) surface state electrons are confined beneath the protecting h -BN. We state that the corrugated CuS reconstruction, defining the QD array, is the scatterer responsible for the confinement, analogous to traditional surface state scattering by steps, corrals ,,, and surface reconstructions . This is further assured by high-resolution STM images of previously studied CuS reconstructions on Cu(111), where clear standing wave patterns were displayed. , …”

Section: Resultsmentioning

confidence: 76%

“…Employing the former, quantum confinement in adatom corrals, , quantum mirage effects, artificial lattices promoting exotic properties, , and pseudologic gates could be realized and explored, expanding our fundamental understanding of quantum phenomena.…”

Section: Introductionmentioning

confidence: 99%

Formation of an Extended Quantum Dot Array Driven and Autoprotected by an Atom-Thick h-BN Layer

et al. 2023

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Engineering quantum phenomena of two-dimensional nearly free electron states has been at the forefront of nanoscience studies ever since the first creation of a quantum corral. Common strategies to fabricate confining nanoarchitectures rely on manipulation or on applying supramolecular chemistry principles. The resulting nanostructures do not protect the engineered electronic states against external influences, hampering the potential for future applications. These restrictions could be overcome by passivating the nanostructures with a chemically inert layer. To this end we report a scalable segregation-based growth approach forming extended quasi-hexagonal nanoporous CuS networks on Cu(111) whose assembly is driven by an autoprotecting h-BN overlayer. We further demonstrate that by this architecture both the Cu(111) surface state and image potential states of the h-BN/CuS heterostructure are confined within the nanopores, effectively forming an extended array of quantum dots. Semiempirical electron-plane-wave-expansion simulations shed light on the scattering potential landscape responsible for the modulation of the electronic properties. The protective properties of the h-BN capping are tested under various conditions, representing an important step toward the realization of robust surface state based electronic devices.

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“…Quantum materials and devices are now entering the regime where we can predict, synthesize, and image them, ushering in a world where we can engineer these devices atom-by-atom. In parallel, discoveries in quantum materials, characterized by the strongly quantum-mechanical nature of electrons and atoms, have revealed exotic properties that arise from strong electronic correlations, , including unconventional superconductors, topological insulators, Dirac and Weyl semimetals, spin liquids, and new phases of matter induced via light-matter interactions. , Part of my (P.N.) motivation for joining the ACS Nano team was to grow this intersection of nanoscience, chemistry, quantum materials, theory and computation, and quantum devices.…”

Section: Recent Newsmentioning

confidence: 99%