One of the most fundamental
interactions in physics is that of electrons and light. In an experiment at
Goethe University Frankfurt, scientists have now managed to observe what is
known as the Kapitza-Dirac effect for the first time in full temporal
resolution. This effect was first postulated more than 90 years ago, but only
now are its finest details coming to light.
It was one of the biggest surprises in the history of science: In the early days of quantum physics about 100 years ago, scholars discovered that the particles which make up our matter always behave like waves. Just as light can scatter at a double slit and produce scattering patterns, electrons can also display interference effects.
In 1933, the two theorists Piotr Kapitza and Paul Dirac proved that an electron beam is even diffracted from a standing light wave (due to the particles' properties) and that interference effects as a result of the wave properties are to be expected.
A German–Chinese team led by Professor Reinhard Dörner from Goethe University Frankfurt has succeeded in using this Kapitza-Dirac effect to visualize even the temporal evolution of the electron waves, known as the electrons' quantum mechanical phase. The study is published in the journal Science.
"It was a former doctoral researcher at our institute, Alexander Hartung, who originally constructed the experimental apparatus," says Dörner. "After he left, Kang Lin, an Alexander von Humboldt fellow who worked in the Frankfurt team for four years, was able to use it to measure the time-dependent Kapitza-Dirac effect." To do so, it was necessary to further develop the theoretical description, too, as Kapitza and Dirac did not take the temporal evolution of the electron phase specifically into consideration at that time.
In their experiment, the scientists in Frankfurt first fired two ultrashort laser pulses from opposite directions at a xenon gas. At the crossover point, these femtosecond pulses—a femtosecond is a quadrillionth of a second—produced an ultrastrong light field for fractions of a second. This tore electrons out of the xenon atoms, i.e., it ionized them.
Very shortly afterward, the physicists fired a second pair of short laser pulses at the electrons released in this way, which also formed a standing wave at the center. These pulses were slightly weaker and did not cause any further ionization. They were, however, now able to interact with the free electrons, which could be observed with the help of a COLTRIMS reaction microscope developed in Frankfurt.
"At the point of interaction, three things can happen," says Dörner. "Either the electron does not interact with the light—or it is scattered to the left or to the right."
According to the laws of quantum physics, these three possibilities together add up to a certain probability that is reflected in the wave function of the electrons: The cloud-like space in which the electron—with a certain probability—is likely to be, collapses, so to speak, into three-dimensional slices. Here, the temporal evolution of the wave function and its phase is dependent on how much time elapses between ionization and the moment of impact of the second pair of laser pulses.
"This opens up many exciting applications in quantum physics. Hopefully, it will help us to track how electrons transform from quantum particles into completely normal particles within the shortest space of time. We are already planning to use it to find out more about the entanglement between different particles that Einstein called 'spooky,'" says Dörner.