In initial tests, the researchers found that their strain engineering approach enabled an enhancement in the performance of 2D MoS 2 transistors, while also reducing both transistor channels and ...

Strain engineering can significantly manipulate the two-dimensional (2D) materials' electronic and optical properties, which endow it the potential applications in optoelectronics and nanophotonics.

Nov 23, 2020: Strain engineering of 2D semiconductors and graphene (Nanowerk News) Strain engineering usually refers to a kind of material processing technology, which aims to regulate the properties ...

WIESBADEN, Germany — Ms. Jennifer Cruz, lead engineer and Engineering Branch Chief, 2d Theater Signal Brigade, was selected as the 2023 Asian American Engineer of the Year, an annual award ...

It does this by looking at a short video sequence that consists of the current frame and a few previous frames, then extracting pieces of 3D information from each 2D frame.

A new technical paper titled “Strain engineering in 2D FETs: Physics, status, and prospects” was published by researchers at UC Santa Barbara. “In this work, we explore the physics and evaluate the ...

Recently, two-dimensional (2D) crystals have offered a new approach for tuning the energy of the electronic states through Coulomb interactions. A team of international researchers have engineered the ...

Researchers at Washington University in St.Louis have built what they claim is the world's fastest 2D receive-only camera, which is able to capture images at a rate of up to 100 billion frames per ...

Algorithm for 2D-to-3D engineering integrates art, nature and science. University of Pennsylvania. Journal Science Advances Funder Army Research Office DOI 10.1126/sciadv.abq3248. Keywords ...

“Our work investigates how emerging 2D materials can be integrated with existing silicon technology to enhance functionality and improve performance, paving the way for energy-efficient ...

The T-CUP (Trillion-frame-per-second compressed ultrafast photography) system was based on passive femtosecond imaging capable of acquiring ten trillion (10 13) frames per second.