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Posted: Feb 8th, 2013
Oxide flips from open to closed
(Nanowerk News) The transistor is the ultimate on-off switch. When a voltage is applied to the surface of a semiconductor, current flows; when the voltage is reversed, current is blocked. Researchers have tried for decades to replicate these effects in transition metal oxides by using a voltage to convert the material from an insulator to a metal, but the induced change only occurs within a few atomic layers of the surface.
Now, Masaki Nakano and colleagues at the RIKEN Advanced Science Institute in Wako have discovered that applying a voltage to a vanadium dioxide (VO2) film several tens of nanometers thick converts the entire film from an insulator to a metal. The findings ("Collective bulk carrier delocalization driven by electrostatic surface charge accumulation") point to the specific material properties needed to make such devices work. They may also lead to new types of ‘smart’ technology.
The electronic properties of transition metal oxides can be tuned by changing their chemical composition or temperature. For example, VO2 is an insulator at room temperature, but heating it or replacing a small fraction of the vanadium atoms with tungsten (an electron donor) causes a phase transition where the vanadium ions, which are paired up at low temperature, unfasten into a different crystal structure in which electrons are mobile. In principle, applying a positive voltage to the surface of an insulating VO2 film can accomplish the same effect by inducing electrons to the surface, making this region metallic.
Researchers have assumed that this charging effect would be limited to a few atomic layers just below the surface because the excess of electrons cancels out the applied electric field (an effect called screening). But Nakano and his colleagues found that the excess electrons were enough to ‘trigger’ the crystal structure change associated with metallic behavior (Fig. 1). “The surface lattice distortion propagates through the entire film, followed by an electronic phase transition inside the bulk region,” he says. The voltage-induced transition decreases VO2’s resistance by a factor of 100.
The team is actively seeking other materials like VO2, as well as technological applications. One is a heat switch. Since temperature determines if VO2 is a metal or an insulator, it also determines the frequency of light the material absorbs. VO2-coated glass could therefore act as a ‘smart window’, passing or blocking infrared light depending on the temperature outside. “Normally, this switching temperature is fixed,” says Nakano. “Our device adds electrical switching functionality to a smart window, which is very promising for energy-saving applications.”
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