Light controls electricity in metals
Researchers at the University of Minnesota Twin Cities have developed a method to control the flow of electricity in ultra-thin metal films at room temperature using light. This discovery could revolutionize the development of new, highly efficient components in optoelectronics and quantum technology.
A team of researchers at the University of Minnesota Twin Cities has achieved a significant breakthrough. They have developed a method that uses light to influence the flow of electricity in extremely thin metal layers at room temperature. This new approach could help to make optical sensors and quantum information devices significantly more efficient in the future. The scientists’ interim results were recently published in the renowned journal “Science Advances”.
The study is based on ultra-thin layers of ruthenium dioxide (RuO2), which were applied to titanium dioxide (TiO2). Depending on the direction, these layers not only react differently to light, but also to the flow of electricity. The structure of these layers makes it possible to specifically control the dynamics of the electrons and thus regulate energy flows.
New paths through targeted use of light
A key finding of the researchers is that the reactions of the material to light can be precisely influenced by targeted changes in the atomic structure. This controlled effect occurs at normal temperatures and opens up exciting prospects for future applications. “This is the first time anyone has demonstrated tunable, directed ultrafast carrier relaxation in a metal at room temperature,” confirms Seunggyo Jeong, a postdoctoral researcher in the Department of Chemical Engineering and Materials Science at the University of Minnesota.
Such findings challenge many ideas about the behavior of metals of recent years and prove that the targeted control of electricity through controlled light pulses is possible. This opens up completely new approaches to dealing with energy and information processing in the smallest of spaces.
Controlling electricity in detail
The previous consensus in physics considered metals to be unsuitable for such precise control mechanisms because they have too complex electronic properties. However, the current research team discovered that precisely this complexity, known as band interleaving, can be actively used to steer the ultra-fast response of metals in different directions. This means that the material’s ability to control electricity can be adapted depending on the situation.
New applications in computer technology, data storage, sensor technology and communication could benefit massively from this. The efficiency and speed of components in particular could be significantly improved through the targeted control of electricity. Tony Low, co-author and Professor of Electrical and Computer Engineering at the University of Minnesota, emphasizes that the results provide deep insights into how subtle structural distortions can change the electronic structure of metals. This could be crucial for future ultrafast and polarization-sensitive optoelectronic technologies.