April
16, 2004
Calgary
will be home to one of the world’s elite research institutes
exploring unsolved puzzles on the frontiers of quantum information
science,
Dr Barry Sanders, director of the new Alberta Institute for
Quantum Information Science, announced this week.
The university has approved the creation of a unique multidisciplinary
institute that will advance the frontiers quantum information
science. Only a few quantum institutes of this calibre exist
in the world. The new institute will eventually link research
in computer science, theoretical and experimental physics,
chemistry, mathematics, and electrical engineering.
“The U of C institute will attract and educate highly
qualified personnel in a field that has considerable potential,” says
Dr. Harvey Weingarten, president of the University of Calgary. “We
expect it to attract top students and faculty and to generate
substantial research funds annually to support its important
work.”
“We want to establish international leadership in quantum
information science research, with Canada and the University
of Calgary as front-runners in quantum information science,” says
Dr Barry Sanders, also an iCORE Professor of quantum information
science in the department of physics and astronomy at the University
of Calgary. “The institute will take advantage of the
U of C’s expertise in this new science, and its willingness
to innovate in the interstices between traditional disciplines.”
“The institute will provide an excellent setting for
people from various disciplines associated with quantum information
science to freely associate ideas and share expertise,” says
Dr Richard Cleve, University Professor of Computer Science
at the U of C and one of the institute’s founders.
Quantum information science has a potentially profound impact
on everything from Internet security to e-commerce. The institute
will focus primarily on experimental and theoretical research
with the aim of developing quantum information science, its
applications, and high quality personnel to support the growth
of this area. International collaborations with other quantum
information researchers will be fostered as well as ongoing
education programs for the local, national and international
community in this emerging field.
The Institute for Quantum Information Science will be funded
by the University of Calgary. Partners in this project include
the University of Montreal, McGill University and the University
of Waterloo.
Contact:
Dr Barry Sanders, iCORE Professor (403) 210-8462, [email protected]
Mary Anne Moser, iCORE Communications (403) 949-3306, @icore.ca
Backgrounder
1) University of Calgary Quantum Information Science Research
Team
Barry Sanders, iCORE Professor in Quantum Information Science
Richard Cleve, University Professor, Computer Science
John Watrous, Canada Research Chair in Quantum Computing
David Feder, University Professor, Physics and Astronomy
David Hobill, University Professor, Physics and Astronomy
Robert Thompson, University Professor, Physics and Astronomy
2) Three examples of the paradigm shift that quantum information
has introduced by combining computing science and quantum
physics:
i) Quantum computation
In computing
science, there is a class of problems that are not solvable – not
because there is no possible answer, but because there is
no computer powerful enough to do the
calculation in a single lifetime. Quantum computation research
is in the process of developing efficient solutions for problems
that have long been believed to be intractable in standard
computing. This new ability will render essentially all current
public-key cryptographic protocols insecure to attackers with
quantum computers.
ii) Quantum cryptography
If a quantum computer is created, capable of the quantum computation
described above, then the levels of security that we now have
to protect our information on computers will be worthless.
It is absolutely essential that quantum cryptography be developed
out before quantum computers become a reality. Quantum cryptography
is a security system that is guaranteed by the laws of physics,
rather than principles of mathematical complexity as in standard
cryptography. This area of research is now of considerable
industrial and commercial interest.
iii) Quantum communication
The idea
of a “broadband” network may change radically
with quantum communication. This area of research explores
ways or transmitting many more bits that classic computing.
Significant savings in communication costs for a number of
communication and distributed computation tasks are envisioned.
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