Many challenges lie ahead before quantum annealing, the analogue
version of quantum computation, contributes to solve combinatorial optimization
problems. Traditional computational tools are simply not powerful enough to
solve some complex optimization problems, like, for example, protein folding.
Quantum annealing, a potentially successful implementation of analogue quantum
computing, would bring about an ultra-performant computational method.Many challenges lie
ahead before quantum annealing, the analogue version of quantum computation,
contributes to solve combinatorial optimisation problems.
Traditional computational tools are simply not
powerful enough to solve some complex optimisation problems, like, for example,
protein folding. Quantum annealing, a potentially successful implementation of
analogue quantum computing, would bring about an ultra-performant computational
method. A series of reviews in this topical issue of EPJ ST, guest-edited by
Sei Suzuki from Saitama Medical University, Japan, and Arnab Das from the
Indian Association for the Cultivation of Science, Kolkota, India, focuses on
the state of the art and challenges in quantum annealing. This approach, if
proven viable, could greatly boost the capabilities of large-scale simulations
and revolutionise several research fields, from biology to economics, medicine
and material science.
A Canadian company called D-Wave has been
commercialising what it claims are two quantum annealers of 100 qubits, since
2011, and 500 qubits, since 2013. "Unlike a bit in a traditional computer,
which can take values either 0 OR 1, a quantum bit (qubit) in a quantum
computer can take values which are superimpositions of 0 AND 1, like a switch
in a state of being on and off simultaneously," explains Das.
The trouble, Suzuki explains, is that
"computation using the quantum mechanics is technically difficult and was
thought to be unrealistic until recently." Before the advent of the D-Wave
machines, realising and manipulating such a superimposed state in real hardware
beyond the size of a few (< 10) qubits seemed to be a daunting task.
Interaction with the environment rapidly decays such strange superposition
states into ordinary 0 OR 1 states, according to Das. As Suzuki notes:
"This is because of the insufficiency of techniques that control and
protect microscopic elements against disturbances.."
There have been speculations from the science
community as to whether the D-Wave technology actually delivers quantum annealing.
"The reviews of our latest issue show that the performances of the D-Wave
machines as quantum computers, while noteworthy, have remained essentially
inconclusive," explains Das, "and scientists have not been able to
definitively ascertain that such a device qualifies as a true quantum
object."
Story Source:
The above story is based on materials provided by Springer Science+Business Media. Note:
Materials may be edited for content and length.
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