麻豆淫院

麻豆淫院icists at Bielefeld University and the Leibniz Institute for Solid State and Materials Research Dresden (IFW Dresden) have developed a method to control atomically thin semiconductors using ultrashort light pulses. The study, in Nature Communications, could pave the way for components that are controlled at unprecedented speeds directly by light鈥攗shering in a new generation of optoelectronic devices.

The researchers employ specially designed nanoscale antennas to convert terahertz light into vertical electric fields in atomically-thin semiconductors, such as molybdenum disulfide (MoS鈧�). Terahertz radiation lies in the electromagnetic spectrum between infrared and microwaves. Due to the newly designed antennas, these electric fields reach several megavolts per centimeter strength.

"Traditionally, such vertical electric fields, used, for example, to switch transistors and other electronic devices, are applied using electronic gating, but this method is fundamentally limited to relatively slow response times," explains the project leader, physics professor Dr. Dmitry Turchinovich from Bielefeld University. "Our approach uses the terahertz light itself to generate the control signal within the semiconductor material鈥攁llowing an industry-compatible, light-driven, ultrafast optoelectronic technology that was not possible until now."

Ultrafast material control

The technique allows real-time control of the electronic structure on timescales of less than a picosecond鈥攖hat is, one trillionth of a second. The scientists were able to experimentally demonstrate that the optical and electronic properties of the material could be selectively altered using light pulses.

The fundamental concept, along with the experimental implementation and theoretical modeling, was developed at Bielefeld University. Dr. Tomoki Hiraoka, lead author of the study and a Marie Sk艂odowska Curie Fellow in Professor Turchinovich's group at the time, played a key role in the project. "Seeing such a strong and coherent effect induced purely by terahertz light pulses was very rewarding," says Hiraoka.

The complex 3D鈥�2D nanoantennas necessary to produce this effect were fabricated at IFW Dresden by a team led by Dr. Andy Thomas. "It took us a lot of work to develop the optimal devices鈥攚e had to fabricate and test many different structures before achieving the desired performance," says Thomas.

Applications in future technologies

This development could lead to ultrafast signal control devices, electronic switches, and sensors. Such components are used in data transmission, cameras, and laser systems. Potential application areas include communication systems, computing, imaging, and quantum technologies.