Noise-Robust and Loss-Tolerant Quantum Steering with Qudits
- URL: http://arxiv.org/abs/2202.09294v2
- Date: Wed, 20 Apr 2022 16:23:57 GMT
- Title: Noise-Robust and Loss-Tolerant Quantum Steering with Qudits
- Authors: Vatshal Srivastav, Natalia Herrera Valencia, Will McCutcheon, Saroch
Leedumrongwatthanakun, S\'ebastien Designolle, Roope Uola, Nicolas Brunner,
Mehul Malik
- Abstract summary: We introduce a noise-robust and loss-tolerant test of quantum steering designed for single detector measurements.
We experimentally demonstrate detection loophole-free quantum steering in 53 dimensions through simultaneous loss and noise conditions.
By surpassing the constraints imposed upon the device-independent distribution of entanglement, our loss-tolerant, noise-robust, and resource-efficient demonstration of quantum steering proves itself a critical ingredient for making device-independent quantum communication over long distances a reality.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: A primary requirement for a robust and unconditionally secure quantum network
is the establishment of quantum nonlocal correlations over a realistic channel.
While loophole-free tests of Bell nonlocality allow for entanglement
certification in such a device-independent setting, they are extremely
sensitive to loss and noise, which naturally arise in any practical
communication scenario. Quantum steering relaxes the strict technological
constraints of Bell nonlocality by re-framing it in an asymmetric manner, thus
providing the basis for one-sided device-independent quantum networks that can
operate under realistic conditions. Here we introduce a noise-robust and
loss-tolerant test of quantum steering designed for single detector
measurements that harnesses the advantages of high-dimensional entanglement. We
showcase the improvements over qubit-based systems by experimentally
demonstrating detection loophole-free quantum steering in 53 dimensions through
simultaneous loss and noise conditions corresponding to 14.2 dB loss equivalent
to 79 km of telecommunication fibre, and 36% of white noise. We go on to show
how the use of high dimensions counter-intuitively leads to a dramatic
reduction in total measurement time, enabling a quantum steering violation
almost two orders of magnitude faster obtained by simply doubling the Hilbert
space dimension. By surpassing the constraints imposed upon the
device-independent distribution of entanglement, our loss-tolerant,
noise-robust, and resource-efficient demonstration of quantum steering proves
itself a critical ingredient for making device-independent quantum
communication over long distances a reality.
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