[FDE] Advances in Quantum Computing - Moving from "having information" to "communicating information"

[Saqib Ali]

Yale Scientists Make Two Giant Steps in Advancement of Quantum Computing
http://www.yale.edu/opa/newsr/07-09-26-01.all.html

New Haven,  Two major steps toward putting quantum computers into real  sending 
a photon signal on demand from a qubit onto wires and transmitting the signal 
to a second, distant  have been brought about by a team of scientists at Yale. 
The accomplishments are reported in sequential issues of Nature on September 20 
and September 27, on which it is highlighted as the cover along with 
complementary work from a group at the National Institute of Standards and 
Technologies.

Over the past several years, the research team of Professors Robert Schoelkopf 
in applied physics and Steven Girvin in physics has explored the use of 
solid-state devices resembling microchips as the basic building blocks in the 
design of a quantum computer. Now, for the first time, they report that 
superconducting qubits, or artificial atoms, have been able to communicate 
information not only to their nearest neighbor, but also to a distant qubit on 
the chip.

This research now moves quantum computing from "having information" to 
"communicating information." In the past information had only been transferred 
directly from qubit to qubit in a superconducting system. Schoelkopf and 
Girvin's team has engineered a superconducting communication bus' to store and 
transfer information between distant quantum bits, or qubits, on a chip. This 
work, according to Schoelkopf, is the first step to making the fundamentals of 
quantum computing useful.

The first breakthrough reported is the ability to produce on  and  single, 
discrete microwave photons as the carriers of encoded quantum information. 
While microwave energy is used in cell phones and ovens, their sources do not 
produce just one photon. This new system creates a certainty of producing 
individual photons.

 "It is not very difficult to generate signals with one photon on average, but, 
it is quite difficult to generate exactly one photon each time. To encode 
quantum information on photons, you want there to be exactly one," according to 
postdoctoral associates Andrew Houck and David Schuster who are lead co-authors 
on the first paper.

"We are reporting the first such source for producing discrete microwave 
photons, and the first source to generate and guide photons entirely within an 
electrical circuit," said Schoelkopf.

In order to successfully perform these experiments, the researchers had to 
control electrical signals corresponding to one single photon. In comparison, a 
cell phone emits about 1023 (100,000,000,000,000,000,000,000) photons per 
second. Further, the extremely low energy of microwave photons mandates the use 
of highly sensitive detectors and experiment temperatures just above absolute 
zero.

"In this work we demonstrate only the first half of quantum communication on a  
quantum information efficiently transferred from a stationary quantum bit to a 
photon or flying qubit,'" says Schoelkopf. "However, for on-chip quantum 
communication to become a reality, we need to be able to transfer information 
from the photon back to a qubit."

This is exactly what the researchers go on to report in the second 
breakthrough. Postdoctoral associate Johannes Majer and graduate student Jerry 
Chow, lead co-authors of the second paper, added a second qubit and used the 
photon to transfer a quantum state from one qubit to another. This was possible 
because the microwave photon could be guided on  similarly to the way fiber 
optics can guide visible  and carried directly to the target qubit. "A novel 
feature of this experiment is that the photon used is only virtual," said Majer 
and Chow, "winking into existence for only the briefest instant before 
disappearing."

To allow the crucial communication between the many elements of a conventional 
computer, engineers wire them all together to form a data "bus," which is a key 
element of any computing scheme. Together the new Yale research constitutes the 
first demonstration of a "quantum bus" for a solid-state electronic system. 
This approach can in principle be extended to multiple qubits, and to 
connecting the parts of a future, more complex quantum computer.

However, Schoelkopf likened the current stage of development of quantum 
computing to conventional computing in the 1950's, when individual transistors 
were first being built. Standard computer microprocessors are now made up of a 
billion transistors, but first it took decades for physicists and engineers to 
develop integrated circuits with transistors that could be mass produced.

Schoelkopf and Girvin are members of the newly formed Yale Institute for 
Nanoscience and Quantum Engineering (YINQE), a broad interdisciplinary activity 
among faculty and students from across the university. Further information and 
FAQs about qubits and quantum computing are available online at 
http://www.eng.yale.edu/rslab/

Other Yale authors involved in the research are J.M. Gambetta, J.A. Schreier, 
J. Koch, B.R. Johnson, L. Frunzio, A. Wallraff, A. Blais and Michel Devoret. 
Funding for the research was from the National Security Agency under the Army 
Research Office, the National Science Foundation and Yale University.

Citation: Nature 449, 328-331 (20 September 2007) doi:10.1038/nature06126
& Nature 450, 443-447 (27 September 2007) doi:10.1038/nature06184

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