Equation reveals the characteristics of quantum chaos
What does chaos look like in the smallest of worlds that we can imagine – inside atoms? The world in there behaves a lot differently to the world that we experience; the protons and neutrons in the nucleus are waves. In this microcosmos, the so-called quantum world, the normal rules of nature do not apply, but in terms of the state called chaos, there are universal features that are present, regardless of the level of existence.
In a new study, a research group including researchers from Lund University, has therefore set out to tackle the theory of quantum chaos, i.e. they have studied the chaotic state at quantum level. The theory of quantum chaos is about explaining the irregular movements of both electrons and nuclei, as well as the irregular movements of, for example, rays of light in optical instruments with complex geometries, or sound waves in a furnished room.
The researchers have analysed statistical properties at different energy levels in a quantum chaos state. Although the research is theoretical, it has practical applications. Chaos theory and the associated concept of random matrices are used in different contexts where there is an attempt to describe and analyse chaotic states. These contexts include financial instruments, brain surgery and even the string theory for the universe.
“In chaotic quantum systems, the energy levels repel each other, and they affect each other even if they are far apart”, states Vladimir Osipov, a researcher at Lund University’s Faculty of Science and one of the authors of the new study.
He notes that it is difficult to make computer calculations for a specific quantum chaos state, as chaotic systems are extremely sensitive to the initial numbers entered in calculations. Small differences in initial values can produce large diviations in the final result of the calculation. However, due to the results of the new study, it is possible from now on to use an exact, mathematical equation to predict the characteristics of chaos without such extensive number-crunching.
“Yes, we now have an exact equation. Personally, I am actually surprised that it was possible at all”, says Vladimir Osipov.
Vladimir Osipov, postdoc
Department of Chemistry, Lund University
+46 46-222 81 31
vladimir [dot] osipov [at] chemphys [dot] lu [dot] se