A new look at high-temperature superconductors
Method allows direct detection of rapid fluctuations that may help to
explain how high-temperature superconducting materials work.
MIT researchers' new method for observing the motion of electron density waves in a superconducting material
led to the detection of two different kinds of variations in those waves: amplitude (or intensity) changes and phase changes,
shifting the relative positions of peaks and troughs of intensity. These new findings could make it easier to search for
new kinds of higher-temperature superconductors.
Graphic courtesy of the researchers
February 24, 2013
While the phenomenon of superconductivity — in which some materials lose all resistance to electric currents at extremely low temperatures — has been known for more than a century, the temperature at which it occurs has remained too low for any practical applications. The discovery of “high-temperature” superconductors in the 1980s — materials that could lose resistance at temperatures of up to negative 140 degrees Celsius — led to speculation that a surge of new discoveries might quickly lead to room-temperature superconductors. Despite intense research, these materials have remained poorly understood.
There is still no agreement on a single theory to account for high-temperature superconductivity. Recently, however, researchers at MIT and elsewhere have found a new way to study fluctuating charge-density waves, which are the basis for one of the leading theories. The researchers say this could open the door to a better understanding of high-temperature superconductivity, and perhaps prompt new discoveries of higher-temperature superconductors.
The findings were published this week in the journal
Nature Materials by assistant professor of physics Nuh Gedik; graduate student Fahad Mahmood; Darius Torchinsky, a former MIT postdoc who is now at the California Institute of Technology; and two researchers at Brookhaven National Laboratory.
Explaining the basis for high-temperature superconductivity remains “the hardest problem in condensed-matter physics,” Gedik says. But one way of getting a handle on this exotic state of matter is to study what happens to these materials near their “transition temperature,” the point below which they become superconductors.
Previous experiments have shown that above the transition temperature, there is a peculiar state where, Gedik says, “the material starts to behave very weirdly”: Its electrons act in unusual ways, which some physicists believe is caused by a phenomenon called charge-density waves. While the electron density in most conductors is uniform, Gedik explains, in materials with charge-density waves the density is distributed in a sinusoidal pattern, somewhat like ripples on a pond. But so far, such charge-density waves have only been detected in high-temperature superconductors under special circumstances, such as a particular level of doping (the introduction of atoms of another element onto its surface).
Some researchers have proposed that these waves are elusive in high-temperature superconductors because they fluctuate very rapidly, at speeds measured in picoseconds (trillionths of a second). “You can’t see it with conventional techniques,” Gedik says.
That’s where Gedik’s new approach comes in: His team has spent years perfecting methods for studying the movement of electrons by zapping them with laser pulses lasting just a few femtoseconds (or quadrillionths of a second), and then detecting the results with a separate laser beam.
Using that method, the researchers have now detected these fluctuating waves. To do this, they have selectively generated and observed two different collective motions of electrons in these waves: variation in amplitude (the magnitude of modulation of the waves) and in phase (the position of the troughs and peaks of the waves). These measurements show that charge density waves are fluctuating at an interval of only about 2 picoseconds.
“It’s not surprising that static techniques didn’t see them,” Gedik says, but “this settles the question: The fluctuating charge-density waves do exist” — at least in one of the cuprate compounds, the first high-temperature superconducting materials discovered in the 1980s.
Another question: What role, if any, do these charge-density waves play in superconductivity? “Are they helping, or are they interfering?” Gedik asks. To answer this question, the researchers studied the same material, with optimal doping, in which the superconducting transition temperature is maximized. “We see no evidence of charge-density waves in this sample,” Gedik says. This suggests that charge-density waves are probably competing with superconductivity.
In addition, it remains to be seen whether the same phenomenon will be observed in other high-temperature superconducting materials. The new technique should make it possible to find out.
In any case, detecting these fluctuations could help in understanding high-temperature superconductors, Gedik says — which, in turn, could “help in finding other [superconducting materials] that actually work at room temperature.” That elusive goal could enable significant new applications, such as electric transmission lines that eliminate the losses that now waste as much as 30 percent of all electricity produced.
David Hsieh, an assistant professor of physics at Caltech, says the phenomena detected by this research “are known to be very difficult to detect,” so this work “is a great technical achievement and a high-quality piece of research.” By showing for the first time that the fluctuating charge-density waves seem to compete with superconductivity, he says, “It provides the insight that finding a way to suppress this fluctuating charge-density wave order may simultaneously increase” the temperature limits of superconductivity.
The work, which also included researchers Anthony Bollinger and Ivan Bozovic of Brookhaven National Laboratory,
was supported by grants from the National Science Foundation and the U.S. Department of Energy.