A systematic1 study of phase changes in vanadium dioxide(二氧化钒) has solved a mystery that has puzzled scientists for decades, according to researchers at the Department of Energy's Oak Ridge3 National Laboratory. Scientists have known that vanadium dioxide exhibits several competing phases when it acts as an insulator4(绝缘体) at lower temperatures. However, the exact nature of the phase behavior has not been understood since research began on vanadium dioxide in the early 1960s.
Alexander Tselev, a research associate from the University of Tennessee-Knoxville working with ORNL's Center for Nanophase Materials Sciences, in collaboration5 with Igor Luk'yanchuk from the University of Picardy in France used a condensed matter physics(凝聚物理学) theory to explain the observed phase behaviors of vanadium dioxide, a material of significant technological6 interest for optics and electronics.
"We discovered that the competition between several phases is purely7 driven by the lattice(晶格,格子) symmetry," Tselev said. "We figured out that the metallic8 phase lattice of vanadium oxide2 can 'fold' in different ways while cooling, so what people observed was different types of its folding."
Vanadium dioxide is best known in the materials world for its speedy and abrupt9 phase transition that essentially10 transforms the material from a metal to an insulator. The phase change takes place at about 68 degrees Celsius11.
"These features of electrical conductivity make vanadium dioxide an excellent candidate for numerous applications in optical, electronic and optoelectronic devices," Tselev said.
Devices that might take advantage of the unusual properties of VO2 include lasers, motion detectors12 and pressure detectors, which could benefit from the increased sensitivity provided by the property changes of vanadium dioxide. The material is already used in technologies such as infrared13 sensors14.
Researchers said their theoretical work could help guide future experimental research in vanadium dioxide and ultimately aid the development of new technologies based on VO2.
"In physics, you always want to understand how the material ticks," said Sergei Kalinin, a senior scientist at the CNMS. "The thermodynamic(热力学的) theory will allow you to predict how the material will behave in different external conditions."
The results were published in the American Chemical Society's Nano Letters. The research team also included Ilia Ivanov, John Budai and Jonathan Tischler at ORNL and Evgheni Strelcov and Andrei Kolmakov at Southern Illinois University.
The team's theoretical research expands upon previous experimental ORNL studies with microwave imaging that demonstrated how strain and changes of crystal lattice symmetry(对称,整齐) can produce thin conductive wires in nanoscale vanadium dioxide samples.