Physicists Advance Theory For New Class Of Quantum Phase Transition

ScienceDaily ^ | 10.29.01 | Rice University

[callisto]

HOUSTON, Oct. 25, 2001 — The complete workings of quantum mechanics and how it affects the universe is still a mystery, but Rice University-led physicists have made a key advancement in understanding how complex quantum fluctuations play a role in the transformation of metals from one electronic state to another.

The findings provide insight into the electronic structure of strongly correlated materials — materials that are potentially significant for far-reaching technological applications in nanotechnology and high-temperature superconductors.

Rice University theoretical physicist Qimiao Si and his team of researchers report their discovery of an entirely new class of critical point — the point at which a complex system undergoes a change between two distinctive phases — marking a substantial advance in the study of phase transitions. Familiar examples of thermal phase transitions, those driven by changes in temperature, are when water changes to steam or to ice.

Quantum phase transitions, on the other hand, are those driven by quantum fluctuations and dictated by Heisenberg’s famous uncertainty principle.

"The findings clarify, for the first time, what experimentalists have observed but were not able to explain because the results apparently contradict the traditional theory for quantum-critical metals — a theory that has held sway since the mid-1970’s," said Qimiao Si, associate professor of physics and astronomy at Rice University.

Their research is published in the Oct. 25 issue of the journal Nature. Authors on the report are Si of Rice; Silvio Rabello, postdoctoral fellow at Rice; Kevin Ingersent, associate professor of physics at the University of Florida, Gainesville; and Llewellun Smith, graduate student at Rice.

The researchers’ theory provides a basis for the quantum mechanism that gives seemingly conventional metals unconventional properties. In effect, they discovered a new quantum critical metallic state of matter. It is "quantum critical" because the transformation is dependent upon quantum fluctuations.

"The theoretical findings show that, under suitable conditions, quantum critical metals contain ‘critical local excitations’ — collective electronic objects which have very low energy, yet occur at one point in space," Si said.

The notion of local criticality could be applicable to a range of strongly correlated metals, including high-temperature superconductors. There is a growing realization that the apparent breakdown of the standard theory of metals — Landau’s Fermi-liquid theory — in high-temperature superconductors and related systems may result from proximity to quantum criticality.

Si, associate professor of physics, and his colleagues looked at a class of strongly correlated electron systems: heavy fermion metals, which contain the so-called rare earth elements and actinides, or radioactive metals. Among the most famous heavy fermions are the plutonium metals.

In strongly correlated electron systems, the interaction between neighboring electrons is so strong that the electrons can not be considered separately, as is done in describing simple metals and insulators.

Theoretically, it is very difficult to study complex behavior so Si and his team looked for benchmarks where they could understand the behavior.

Physicists have learned how to manipulate, or fine-tune, the degree to which the uncertainty principle comes into play in strongly correlated electron systems, allowing them to observe a quantum critical point. Experimentalists have previously done just that in heavy fermion metals.

When electrons are strongly interacting, even a small change in some external variable can have a dramatic impact, resulting in a change from one type of electronic or magnetic state to another.By changing the parameters of the system, Si and his colleagues were able to tune the system to be exactly at or on the cusp of the transition, where electrons behave most collectively and paradoxically, where accurate theoretical treatment is easier to carry through. Taking into account both quantum fluctuations and strong electron-electron interactions, they discovered the surprising "locally critical point."

In correlated electron physics, a frontier of condensed matter physics, scientists are trying to get an understanding of all of the electronic processes governing natural materials and man-made ones.

"Our field is still very much in its infancy," Si said. "We are looking for some very basic principles that govern how new electronic states of matter emerge as a result of quantum fluctuations and electron-electron interactions."

This research was supported by the National Science Foundation, the Texas Center for Superconductivity at the University of Houston and the Alfred P. Sloan Foundation.

[callisto]

ping

[Maceman]

There is a growing realization that the apparent breakdown of the standard theory of metals — Landau’s Fermi-liquid theory — in high-temperature superconductors and related systems may result from proximity to quantum criticality.

Well du-uh.

[MichaelP]

Modern Physics is exploding with new understanding. The entire spectrum of Quantum Mechanics is surging with breakthrough science. The near future holds possible what until recently was thought to be impossible.

Mike

[willyb_jr]

bump to: list

Click here for a list of all RealScience articles

[newzjunkey]

bump for later reading.

[callisto]

Science and technology are growing at an exponential rate. The amount of newly discovered information that is written daily is overwhelming to keep up with. Now we just need computers with the ability to process all of this data....But one is on the way to link a lot of the worlds universities that computes in petabytes...approximately 1 million gigabytes!!!! WOW!!!

[Vide]

"...that computes in petabytes..."

What next, namblabytes?

[samtheman]

Any chance of getting a new weapon out of this research? (Sorry, one track mind these days.)

[Check6]

Does a bear have hair?

[callisto]

Any chance of getting a new weapon out of this research?

I see lots of possiblities here for new weapons.

[Check6]

The Chicoms are probably looking at it as we speak (if they didn't have the research in their hands months ago).

[callisto]

What next, namblabytes?

ROTFLMAO!!!! You must be wide awake this AM!

[Check6]

I wonder if Qimiao Si would quality for a Secret or Top Secret clearance . . . bet not.

[d4now]

bump for later

[general_re]

ping

So where are my room-temperature superconductors and maglev trains and railguns and what-have-you? This is good money we're spending here, and if we can't have newer and better ways to frag bad guys, I don't wanna bother ;)

[Gordian Blade]

I'm leaving soon for my class, but I want to take a closer look when I get a chance.

One of my classmates in grad school did his Ph.D. thesis on maglev. It can work technically, but the cost per mile of the track is very high compared with conventional high-speed track. Too bad.

Then I have another friend who worked on railguns. They couldn't make a practical weapon out of it. Too bad.

Then I have another friend from grad school who was working on magnetic containment for controlled fusion. That hasn't worked yet, although some progress is being made. Too bad.

Is there a pattern here?

[zeugma]

After petabytes, come exobytes.

[zeugma]

I'd be interested in seeing some charts of data relating to these newly discovered phase transitions. I recall reading many years ago that electromagnetic state transitions are governed by the Mandelebrot formula.

[general_re]

Is there a pattern here?

Yes. Hanging around with you is bad luck. Stop making so many friends - it's retarding the progress of science ;)

More seriously, it seems pretty clear that a lot of these things have been somewhat oversold in the public imagination. If I were a cynic, I might say that this is the inevitable result of the vagaries of scientific funding - turning scientists into salesmen, and funding the best salesmen rather than the most promising scientists.

But, less cynically, when you say magnetic containment fields for fusion, are you speaking of tokamak-type reactors? I seem to recall some articles a few years ago showing some progress down around Princeton way....