Related papers: Semiconductor Circuits for Quantum Computing with Electronic Wave Packets

Semiconductor Circuits for Quantum Computing with Electronic Wave Packets

URL: http://arxiv.org/abs/2410.16244v1
Date: Mon, 21 Oct 2024 17:51:13 GMT
Title: Semiconductor Circuits for Quantum Computing with Electronic Wave Packets
Authors: David Pomaranski, Ryo Ito, Ngoc Han Tu, Arne Ludwig, Andreas D. Wieck, Shintaro Takada, Nobu-Hisa Kaneko, Seddik Ouacel, Christopher Bauerle, Michihisa Yamamoto,
Abstract summary: We propose an alternative approach that utilizes flying electronic wave packets propagating in solid-state quantum semiconductor circuits. Hardware requirements are drastically reduced because qubits can be created on-demand and manipulated with a common hardware element. This landmark lays the foundation for fault-tolerant quantum computing with a compact and scalable architecture.
Score: 0.15729203067736897
License:
Abstract: Standard approaches to quantum computing require significant overhead to correct for errors. The hardware size for conventional quantum processors in solids often increases linearly with the number of physical qubits, such as for transmon qubits in superconducting circuits or electron spin qubits in quantum dot arrays. While photonic circuits based on flying qubits do not suffer from decoherence or lack of potential scalability, they have encountered significant challenges to overcome photon loss in long delay circuits. Here, we propose an alternative approach that utilizes flying electronic wave packets propagating in solid-state quantum semiconductor circuits. Using a novel time-bin architecture for the electronic wave packets, hardware requirements are drastically reduced because qubits can be created on-demand and manipulated with a common hardware element, unlike the localized approach of wiring each qubit individually. The electronic Coulomb interaction enables reliable coupling and readout of qubits. Improving upon previous devices, we realize electronic interference at the level of a single quantized mode that can be used for manipulation of electronic wavepackets. This important landmark lays the foundation for fault-tolerant quantum computing with a compact and scalable architecture based on electron interferometry in semiconductors.

Related papers

Quantum Compiling with Reinforcement Learning on a Superconducting Processor [55.135709564322624]
We develop a reinforcement learning-based quantum compiler for a superconducting processor. We demonstrate its capability of discovering novel and hardware-amenable circuits with short lengths. Our study exemplifies the codesign of the software with hardware for efficient quantum compilation.
arXiv Detail & Related papers (2024-06-18T01:49:48Z)
Electron-beam annealing of Josephson junctions for frequency tuning of quantum processors [0.0]
We present an approach to tuning fixed-frequency qubits with the use of an electron beam to locally anneal the Josephson junction. We demonstrate the ability to both increase and decrease the junction barrier resistance.
arXiv Detail & Related papers (2024-02-27T10:43:51Z)
Circuit Cutting with Non-Maximally Entangled States [59.11160990637615]
Distributed quantum computing combines the computational power of multiple devices to overcome the limitations of individual devices. circuit cutting techniques enable the distribution of quantum computations through classical communication. Quantum teleportation allows the distribution of quantum computations without an exponential increase in shots. We propose a novel circuit cutting technique that leverages non-maximally entangled qubit pairs.
arXiv Detail & Related papers (2023-06-21T08:03:34Z)
Quantum circuit debugging and sensitivity analysis via local inversions [62.997667081978825]
We present a technique that pinpoints the sections of a quantum circuit that affect the circuit output the most. We demonstrate the practicality and efficacy of the proposed technique by applying it to example algorithmic circuits implemented on IBM quantum machines.
arXiv Detail & Related papers (2022-04-12T19:39:31Z)
Conveyor-mode single-electron shuttling in Si/SiGe for a scalable quantum computing architecture [0.0]
Small spin-qubit registers defined by single electrons confined in Si/SiGe quantum dots operate successfully. Shuttling the qubit carrying electrons between registers is a natural choice for high-fidelity coherent links. Our proof-of-principle demonstrates shuttling of a single electron by a propagating wave-potential in an electrostatically defined 420 nm long Si/SiGe quantum-channel.
arXiv Detail & Related papers (2021-08-02T13:26:46Z)
Chiral Quantum Network with Giant Atoms [7.33811357166334]
In superconducting quantum circuits (SQCs), chiral routing quantum information is often realized with the ferrite circulators. We propose a novel method to realize chiral quantum networks by exploiting giant atom effects in SQC platforms.
arXiv Detail & Related papers (2021-06-24T17:08:49Z)
Hardware-Efficient, Fault-Tolerant Quantum Computation with Rydberg Atoms [55.41644538483948]
We provide the first complete characterization of sources of error in a neutral-atom quantum computer. We develop a novel and distinctly efficient method to address the most important errors associated with the decay of atomic qubits to states outside of the computational subspace. Our protocols can be implemented in the near-term using state-of-the-art neutral atom platforms with qubits encoded in both alkali and alkaline-earth atoms.
arXiv Detail & Related papers (2021-05-27T23:29:53Z)
Interleaving: Modular architectures for fault-tolerant photonic quantum computing [50.591267188664666]
Photonic fusion-based quantum computing (FBQC) uses low-loss photonic delays. We present a modular architecture for FBQC in which these components are combined to form "interleaving modules" Exploiting the multiplicative power of delays, each module can add thousands of physical qubits to the computational Hilbert space.
arXiv Detail & Related papers (2021-03-15T18:00:06Z)
Long-range connectivity in a superconducting quantum processor using a ring resonator [0.0]
We introduce a novel superconducting architecture that uses a ring resonator as a multi-path coupling element with the qubits uniformly distributed throughout its circumference. We theoretically analyse the qubit connectivity and experimentally verify it in a device capable of supporting up to twelve qubits where each qubit can be connected to nine other qubits.
arXiv Detail & Related papers (2020-12-17T09:34:14Z)
Circuit Quantum Electrodynamics [62.997667081978825]
Quantum mechanical effects at the macroscopic level were first explored in Josephson junction-based superconducting circuits in the 1980s. In the last twenty years, the emergence of quantum information science has intensified research toward using these circuits as qubits in quantum information processors. The field of circuit quantum electrodynamics (QED) has now become an independent and thriving field of research in its own right.
arXiv Detail & Related papers (2020-05-26T12:47:38Z)
Dissipation-engineering of nonreciprocal quantum dot circuits: An input-output approach [6.211723927647019]
Nonreciprocal effects in nanoelectronic devices offer unique possibilities for manipulating electron transport and engineering quantum electronic circuits. We provide a general input-output description of nonreciprocal transport in solid-state quantum dot architectures. We show that a nonreciprocal coupling induces unidirectional electron flow in the resonant transport regime.
arXiv Detail & Related papers (2020-04-11T14:13:14Z)

This list is automatically generated from the titles and abstracts of the papers in this site.