When a current is applied to a thin layer of tungsten diselenide, it begins to glow in a highly unusual fashion. In addition to ordinary light, which other semiconductor materials can emit, tungsten diselenide also produces a very special type of bright quantum light, which is created only at specific points of the material. It consists of a series of photons that are always emitted one by one—never in pairs or in bunches. This anti-bunching effect is perfect for experiments in the field of quantum information and quantum cryptography, where single photons are required. However, for years, this emission has remained a mystery.
Researchers at TU Vienna have now explained this: A subtle interaction of single atomic defects in the material and mechanical strain are responsible for this quantum light effect. Computer simulations show how the electrons are driven to specific places in the material, where they are captured by a defect, lose energy and emit a photon. The solution to the quantum light puzzle has now been published in Physical Review Letters.
Only three atoms thick
Tungsten diselenide is a two-dimensional material that forms extremely thin layers. Such layers are only three atomic layers thick, with tungsten atoms in the middle, coupled to selenium atoms below and above. “If energy is supplied to the layer, for example by applying an electrical voltage or by irradiating it with light of a suitable wavelength, it begins to shine,” explains Lukas Linhart from the Institute of Theoretical Physics at the TU Vienna. “This in itself is not unusual, many materials do that. However, when the light emitted by tungsten diselenide was analyzed in detail, in addition to ordinary light a special type of light with very unusual properties was detected.”
This special nature quantum light consists of photons of specific wavelengths—and they are always emitted individually. It never happens that two photons of the same wavelength are detected at the same time. “This tells us that these photons cannot be produced randomly in the material, but that there must be certain points in the tungsten diselenide sample that produce many of these photons, one after the other,” explains Professor Florian Libisch, whose research focuses on two-dimensional materials.
Explaining this effect requires detailed understanding of the behavior of the electrons in the material on a quantum physical level. Electrons in tungsten diselenide can occupy different energy states. If an electron changes from a state of high energy to a state of lower energy, a photon is emitted. However, this jump to a lower energy is not always allowed: The electron has to adhere to certain laws—the conservation of momentum and angular momentum.
Due to these conservation laws, an electron in a high-energy quantum state must remain there—unless certain imperfections in the material allow the energy states to change. “A tungsten diselenide layer is never perfect. In some places, one or more selenium atoms may be missing,” says Lukas Linhart. “This also changes the energy of the electron states in this region.”
Moreover, the material layer is not a perfect plane. Like a blanket that wrinkles when spread over a pillow, tungsten diselenide stretches locally when the material layer is suspended on small support structures. These mechanical stresses also have an effect on the electronic energy states.
“The interaction of material defects and local strains is complicated. However, we have now succeeded in simulating both effects on a computer,” says Lukas Linhart. “And it turns out that only the combination of these effects can explain the strange light effects.”
At those microscopic regions of the material, where defects and surface strains appear together, the energy levels of the electrons change from a high to a low energy state and emit a photon. The laws of quantum physics do not allow two electrons to be in exactly the same state at the same time, and therefore, the electrons must undergo this process one by one. As a result, the photons are emitted one by one, as well.
At the same time, the mechanical distortion of the material helps to accumulate a large number of electrons in the vicinity of the defect so that another electron is readily available to step in after the last one has changed its state and emitted a photon.
This result illustrates that ultrathin 2-D materials open up completely new possibilities for materials science.