Hybrid Quantum Device Based onNVCenters in Diamond Nanomechanical Resonators Plus Superconducting Waveguide Cavities

AbstractAdvantages in several fields of research and industry are expected with the rise of quantum computers. However, the computational cost to load classical data in quantum computers can impose restrictions on possible quantum speedups. Known algorithms to create arbitrary quantum states require quantum circuits with depth O(N) to load an N-dimensional vector. Here, we show that it is possible to load an N-dimensional vector with exponential time advantage using a quantum circuit with polylogarithmic depth and entangled information in ancillary qubits. Results show that we can efficiently load data in quantum devices using a divide-and-conquer strategy to exchange computational time for space. We demonstrate a proof of concept on a real quantum device and present two applications for quantum machine learning. We expect that this new loading strategy allows the quantum speedup of tasks that require to load a significant volume of information to quantum devices.

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Room-temperature control and electrical readout of individual nitrogen-vacancy nuclear spins

Nature Communications ◽

10.1038/s41467-021-24494-x ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Michal Gulka ◽

Daniel Wirtitsch ◽

Viktor Ivády ◽

Jelle Vodnik ◽

Jaroslav Hruby ◽

...

Keyword(s):

Dipolar Interaction ◽

Coherence Time ◽

Wide Bandgap ◽

Nitrogen Vacancy ◽

Ambient Conditions ◽

Nuclear Spins ◽

Quantum Device ◽

Nanoscale Electronics ◽

Quantum Processor ◽

Processor Unit

AbstractNuclear spins in semiconductors are leading candidates for future quantum technologies, including quantum computation, communication, and sensing. Nuclear spins in diamond are particularly attractive due to their long coherence time. With the nitrogen-vacancy (NV) centre, such nuclear qubits benefit from an auxiliary electronic qubit, which, at cryogenic temperatures, enables probabilistic entanglement mediated optically by photonic links. Here, we demonstrate a concept of a microelectronic quantum device at ambient conditions using diamond as wide bandgap semiconductor. The basic quantum processor unit – a single 14N nuclear spin coupled to the NV electron – is read photoelectrically and thus operates in a manner compatible with nanoscale electronics. The underlying theory provides the key ingredients for photoelectric quantum gate operations and readout of nuclear qubit registers. This demonstration is, therefore, a step towards diamond quantum devices with a readout area limited by inter-electrode distance rather than by the diffraction limit. Such scalability could enable the development of electronic quantum processors based on the dipolar interaction of spin-qubits placed at nanoscopic proximity.

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Evolutionary Computation for Adaptive Quantum Device Design

Advanced Quantum Technologies ◽

10.1002/qute.202100013 ◽

2021 ◽

pp. 2100013

Author(s):

Luke Mortimer ◽

Marta P. Estarellas ◽

Timothy P. Spiller ◽

Irene D'Amico

Keyword(s):

Evolutionary Computation ◽

Device Design ◽

Quantum Device

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A Single-Layer Circularly Polarized Antenna With Improved Gain Based on Quarter-Mode Substrate Integrated Waveguide Cavities Array

IEEE Antennas and Wireless Propagation Letters ◽

10.1109/lawp.2020.3033621 ◽

2020 ◽

Vol 19 (12) ◽

pp. 2388-2392

Author(s):

Tianming Yang ◽

Zhiqin Zhao ◽

Deqiang Yang ◽

Zaiping Nie

Keyword(s):

Single Layer ◽

Substrate Integrated Waveguide ◽

Circularly Polarized ◽

Waveguide Cavities

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Vibration Analysis of Single Walled Boron Nitride Nanotube Based Nanoresonators

Journal of Nanotechnology in Engineering and Medicine ◽

10.1115/1.4007696 ◽

2012 ◽

Vol 3 (3) ◽

Cited By ~ 8

Author(s):

Mitesh B. Panchal ◽

S. H. Upadhyay ◽

S. P. Harsha

Keyword(s):

Boron Nitride ◽

Resonant Frequency ◽

Continuum Mechanics ◽

Boron Nitride Nanotubes ◽

Response Analysis ◽

Published Data ◽

Boron Nitride Nanotube ◽

Mass Sensor ◽

Nanomechanical Resonators ◽

Mass Sensitivity

In this paper, the vibration response analysis of single walled boron nitride nanotubes (SWBNNTs) treated as thin walled tube has been done using finite element method (FEM). The resonant frequencies of fixed-free SWBNNTs have been investigated. The analysis explores the resonant frequency variations as well as the resonant frequency shift of the SWBNNTs caused by the changes in size of BNNTs in terms of length as well as the attached masses. The performance of cantilevered SWBNNT mass sensor is also analyzed based on continuum mechanics approach and compared with the published data of single walled carbon nanotube (SWCNT) for fixed-free configuration as a mass sensor. As a systematic analysis approach, the simulation results based on FEM are compared with the continuum mechanics based analytical approach and are found to be in good agreement. It is also found that the BNNT cantilever biosensor has better response and sensitivity compared to the CNT as a counterpart. Also, the results indicate that the mass sensitivity of cantilevered boron nitride nanotube nanomechanical resonators can reach 10−23 g and the mass sensitivity increases when smaller size nanomechanical resonators are used in mass sensors.

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