Scientists take new spin on quantum research
Date:
August 26, 2020
Source:
U.S. Army Research Laboratory
Summary:
Researchers discovered a way to further enhance quantum systems
to provide soldiers with more reliable and secure capabilities on
the battlefield.
FULL STORY ==========================================================================
Army researchers discovered a way to further enhance quantum systems
to provide Soldiers with more reliable and secure capabilities on the battlefield.
========================================================================== Specifically, this research informs how future quantum networks will be designed to deal with the effects of noise and decoherence, or the loss
of information from a quantum system in the environment.
As one of the U.S. Army's priority research areas in its Modernization Strategy, quantum research will help transform the service into a
multi-domain force by 2035 and deliver on its enduring responsibility
as part of the joint force providing for the defense of the United States.
"Quantum networking, and quantum information science as a whole, will potentially lead to unsurpassed capabilities in computation, communication
and sensing," said Dr. Brian Kirby, researcher at the U.S. Army Combat Capabilities Development Command's Army Research Laboratory. "Example applications of Army interest include secure secret sharing, distributed network sensing and efficient decision making." This research effort
considers how dispersion, a very common effect found in optical systems, impacts quantum states of three or more particles of light.
Dispersion is an effect where a pulse of light spreads out in time as it
is transmitted through a medium, such as a fiber optic. This effect can
destroy time correlations in communication systems, which can result in
reduced data rates or the introduction of errors.
==========================================================================
To understand this, Kirby said, consider the situation where two light
pulses are created simultaneously and the goal is to send them to two
different detectors so that they arrive at the same time. If each light
pulse goes through a different dispersive media, such as two different
fiber optic paths, then each pulse will be spread in time, ultimately
making the arrival time of the pulses less correlated.
"Amazingly, it was shown that the situation is different in quantum
mechanics," Kirby said. "In quantum mechanics, it is possible to describe
the behavior of individual particles of light, called photons. Here,
it was shown by research team member Professor James Franson from the University of Maryland, Baltimore County, that quantum mechanics allows
for certain situations where the dispersion on each photon can actually
cancel out so that the arrival times remain correlated." The key to
this is something called entanglement, a strong correlation between
quantum systems, which is not possible in classical physics, Kirby said.
In this new work, Nonlocal Dispersion Cancellation for Three or More
Photons, published in the peer-reviewed Physical Review A, the researchers extend the analysis to systems of three or more entangled photons and
identify in what scenarios quantum systems outperform classical ones. This
is unique from similar research as it considers the effects of noise on entangled systems beyond two-qubits, which is where the primary focus
has been.
"This informs how future quantum networks will be designed to deal
with the effects of noise and decoherence, in this case, dispersion specifically," Kirby said.
========================================================================== Additionally, based on the success of Franson's initial work on systems
of two- photons, it was reasonable to assume that dispersion on one
part of a quantum system could always be cancelled out with the proper application of dispersion on another part of the system.
"Our work clarifies that perfect compensation is not, in general, possible
when you move to entangled systems of three or more photons," Kirby said.
"Therefore, dispersion mitigation in future quantum networks may need
to take place in each communication channel independently." Further,
Kirby said, this work is valuable for quantum communications because it
allows for increased data rates.
"Precise timing is required to correlate detection events at different
nodes of a network," Kirby said. "Conventionally the reduction in time correlations between quantum systems due to dispersion would necessitate
the use of larger timing windows between transmissions to avoid confusing sequential signals." Since Kirby and his colleagues' new work describes
how to limit the uncertainty in joint detection times of networks,
it will allow subsequent transmissions in quicker succession.
The next step for this research is to determine if these results can be
readily verified in an experimental setting.
========================================================================== Story Source: Materials provided by U.S._Army_Research_Laboratory. Note: Content may be edited for style and length.
========================================================================== Journal Reference:
1. I. C. Nodurft, S. U. Shringarpure, B. T. Kirby, T. B. Pittman, J. D.
Franson. Nonlocal dispersion cancellation for three or more photons.
Physical Review A, 2020; 102 (1) DOI: 10.1103/PhysRevA.102.013713 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/08/200826123113.htm
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