Researchers reveal that plasmons in boron-doped diamonds are driving advances in electronics, optics and quantum computing.

More information: Seunghyun Ji et al, Nucleation‐Controlled Doping of II–VI Semiconductor Nanocrystals Mediated by Magic‐Sized Clusters, Small Science (2024). DOI: 10.1002/smsc.202400300 ...

[Zachary Tong] is dipping his toes into the DIY semiconductor world, and further to the goal of keeping costs to a hobbyist scale, is experimenting with laser doping of silicon. Doping is the ...

Monolayer doping techniques have emerged as a significant advancement in the field of semiconductor nanostructures, particularly for enhancing the performance of electronic devices. These ...

This study (Small Science, "Nucleation-Controlled Doping of II–VI Semiconductor Nanocrystals Mediated by Magic-Sized Clusters") was conducted in collaboration with a research team led by Stefan Ringe ...

Ion implantation is a low-temperature method of ‘doping’ semiconductor devices in which high energy charged particles (ions) are accelerated towards a semiconductor, causing the ions to ...

A research group led by Prof. Yang Liangbao from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences ...

Unlike metals or even other doped semiconductors, boron-doped diamonds remain optically clear. "Diamond continues to shine," said Giuseppe Strangi, professor of physics at Case Western Reserve ...

Semiconductors can be doped to increase these concentrations: n-doping increases the concentration of electrons, while p-doping increases the concentration of holes. This doping process also affects ...

Rising demand for ultra-high purity gases drives semiconductor innovation, with TSMC, Samsung, and Intel leading consumption, ...