Innovative Research Sheds Light on Charge Transfer in 2D Semiconductors

Innovative Research Sheds Light on Charge Transfer in 2D Semiconductors
by Robert Schreiber
Berlin, Germany (SPX) Feb 09, 2024

In a significant advancement for semiconductor technology, researchers from the Universities of Gottingen, Marburg, and Cambridge have leveraged electron spectroscopy to uncover the intricate details of exciton dynamics in two-dimensional semiconductors. This groundbreaking study, published in Science Advances, offers unprecedented insights into the charge transfer processes essential for the next generation of computer and photovoltaic technologies.

Semiconductors, the backbone of modern electronics, regulate electricity flow through the formation of excitons-bound states of electrons and holes created when semiconductors absorb light. The interaction between these particles is pivotal for the semiconductor's function, especially in two-dimensional materials where excitons exhibit remarkably high binding energies. The research team focused on these excitons, aiming to unravel the mysteries of the "hole" part of the electron-hole pair, a component that, until now, remained elusive to direct measurement techniques.

Dr. Marcel Reutzel, Prof. Stefan Mathias, and physicist Jan Philipp Bange from the University of Gottingen spearheaded the study. They employed a unique microscope for photoelectrons coupled with a high-intensity laser to dissect the exciton's components. This method facilitated the observation of energy loss in electrons as excitons broke up, a phenomenon indicative of the exciton's environment and interactions.

A key finding of their research is the ability to track the hole's transfer between different layers of atomically thin semiconductors, akin to the process in solar cells. This discovery was made possible through a collaborative effort with Prof. Ermin Malic's team at the University of Marburg, who developed a model to describe these microscopic charge transfer processes.

The implications of this research are vast. Prof. Mathias envisions leveraging the spectroscopic signatures of electron-hole interactions to explore novel quantum material phases at unprecedentedly short time and length scales. Such explorations are anticipated to lay the groundwork for developing new technologies, pushing the boundaries of what is currently possible in electronics and energy conversion.

This research project received support from the German Research Foundation (DFG), highlighting the critical role of collaborative efforts and funding in advancing scientific knowledge. The DFG's backing for the Collaborative Research Centres "Atomic scale control of energy conversion," "Mathematics of Experiment" in Gottingen, and "Structure and Dynamics of Internal Interfaces" in Marburg was instrumental in achieving these groundbreaking results.

As the world leans more into the realm of quantum materials and technologies, studies like this underscore the importance of fundamental research in unlocking the potential of materials that could revolutionize electronics and energy systems.

Research Report:Probing electron-hole Coulomb correlations in the exciton landscape of a twisted semiconductor heterostructure