Gate‐Controlled Quantum Dots Based on 2D Materials

Jing, Fang‐Ming; Zhang, Zhuo‐Zhi; Qin, Guo‐Quan; Luo, Gang; Cao, Gang; Li, Hai‐Ou; Song, Xiang‐Xiang; Guo, Guo‐Ping

doi:10.1002/qute.202100162

Cited by 18 publications

(12 citation statements)

References 330 publications

(735 reference statements)

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“…This characteristic is a complete contrast to that of the curves in figure 2. Thus, we can conclude that the two-qubit gate caused by the Hamiltonian defined by equation (35) is not well protected from thermal fluctuations of the phonons.…”

Section: An Example Of a Two-qubit Gate That Generates Entanglement B...mentioning

confidence: 87%

“…In [35], experimental demonstrations of gate-controlled quantum dots based on two-dimensional materials were discussed. According to [35], experiments of quantum dots for quantum computation also require the temperature of the system to be kept low enough. where T ge = T ge (n, Ω, ν, Δν, η), and T ge is on the order of ν/Ω 2 .…”

Section: Conclusion and Discussionmentioning

confidence: 99%

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A simplified Mølmer–Sørensen gate for the trapped ion quantum computer

Azuma

2024

Phys. Scr.

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We discuss how to simplify the Mølmer-Sørensen (MS) gate which is used for the trapped ion quantum computer. The original MS gate is implemented by illuminating two ions with bichromatic coherent light fields separately at the same time. In this paper, we propose a method for transforming a separable state of two ions into one of the Bell states by illuminating the two ions with monochromatic coherent light fields individually and this point is the advantage of our scheme over the original MS gate. The length of the execution time of our proposed gate is comparable to that of the original MS gate, however, numerical calculations show that our proposed gate is weakly sensitive to thermal fluctuations of the phonons. By giving another example of a simple two-ion gate that can generate entanglement but is strongly vulnerable to thermal fluctuations, we show that our simplified MS gate is more marked than usual.

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Section: An Example Of a Two-qubit Gate That Generates Entanglement B...mentioning

confidence: 87%

Section: Conclusion and Discussionmentioning

confidence: 99%

A simplified Mølmer–Sørensen gate for the trapped ion quantum computer

Azuma

2024

Phys. Scr.

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“…Recently, 2D materials have emerged as qubit candidates; their atomically thin geometry presents natural carrier confinement along the out-of-plane dimension and improved electrostatics that facilitate carrier confinement. − While current state-of-the-art 2D material-based quantum dot demonstrations are mostly on graphene, , 2D TMD semiconductors offer many enticing upgrades. − 2D TMDs have direct band-gaps; unlike graphene which requires additional fabrication complexity to induce a bandgap, e.g., with atomically precise edges or perpendicular electric fields. Due to the d orbital electrons in the metal atoms, TMDs have strong spin–orbit coupling useful for fast, all-electrical qubit control via electric dipole spin resonance.…”

Section: Applicationsmentioning

confidence: 99%

Dielectrics for Two-Dimensional Transition-Metal Dichalcogenide Applications

et al. 2023

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Despite over a decade of intense research efforts, the full potential of two-dimensional transition-metal dichalcogenides continues to be limited by major challenges. The lack of compatible and scalable dielectric materials and integration techniques restrict device performances and their commercial applications. Conventional dielectric integration techniques for bulk semiconductors are difficult to adapt for atomically thin two-dimensional materials. This review provides a brief introduction into various common and emerging dielectric synthesis and integration techniques and discusses their applicability for 2D transition metal dichalcogenides. Dielectric integration for various applications is reviewed in subsequent sections including nanoelectronics, optoelectronics, flexible electronics, valleytronics, biosensing, quantum information processing, and quantum sensing. For each application, we introduce basic device working principles, discuss the specific dielectric requirements, review current progress, present key challenges, and offer insights into future prospects and opportunities.

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“…Since the decoherence time is the most problematic parameter to cope with, we envision that the realization using longer-lived qubits (nano-to microseconds) will be much more optimal. Superconducting qubits, self-assembled stacked semiconductor quantum dots (at a low density, so that a single stack can be isolated), 48 quantum dot molecules, 49 and especially voltage-induced (gate-controlled) quantum dot molecules in semiconductor 50 or 2D materials 51 have by orders of magnitude longer coherence times, and the remaining challenge will be the precise engineering of the cascaded structure. The control of the potential well parameters by applying prescribed voltages makes such a cascaded quantum-dot molecule a recommended realization to consider.…”

Section: Implementationsmentioning

confidence: 99%

Controlled Emission of Entangled Multiphoton States from Cascaded Quantum Wells

Sivan,

Orenstein

2023

ACS Photonics

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Entangled multiphoton states are a critical resource for the emerging applications of quantum science. Generation of reliable sources of such quantum states of light poses both theoretical and practical challenges, particularly in the small scale. We propose a deterministic source of entangled multiphoton states based on spontaneous emission from a ladder of cascaded quantum potential wells. The special ingredient of this scheme compared with a simple ensemble of emitters is the coupling between the two-level systems, creating sublevels in the energy ladder. This enables, via an indistinguishable multipath evolution, the creation of highly entangled multiphoton photon-number combination states in three modes, namely, tripartite entanglement in the frequency degree of freedom. Due to the intricate energy ladder of our proposed structure, we can apply control and switch the entanglement between two multiphoton modes by measuring the third. We further discuss an application as a qubit-pair source with an error-detection ancilla and comment on possible implementations.

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Gate‐Controlled Quantum Dots Based on 2D Materials

Cited by 18 publications

References 330 publications

A simplified Mølmer–Sørensen gate for the trapped ion quantum computer

A simplified Mølmer–Sørensen gate for the trapped ion quantum computer

Dielectrics for Two-Dimensional Transition-Metal Dichalcogenide Applications

Controlled Emission of Entangled Multiphoton States from Cascaded Quantum Wells

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