Single development-atom class graphene coating improves the life of the accelerator’s electronics.
Protective coatings are used frequently for many problems in everyday life and are used heavily: we put the finishing touches on laminate floors; Teflon coating on car paint; even use diamond coating on medical devices. Protective coatings are also important in many demanding analysis and industrial purposes.
Now, researchers at Los Alamos National Laboratory have developed and tested an atom-thin graphene coating for next-generation electron-beam accelerator tools — which could essentially be The most difficult technical utility in the profession, its success gives the potential for “Atomic Armor” for a variety of purposes.
“Accelerators are essential tools for solving some of the great challenges facing humanity,” said Hisato Yamaguchi, member of the Sigma-2 team at the Laboratory. “These challenges represent the search for sustainable vitality, the continued expansion of computational power, the detection and mitigation of pathogens, and the study of the structure and dynamics of the building blocks of life. . And human challenges all require the ability to penetrate, observe and manage matter on the frontier time scales of digital motion and the spatial scale of atomic bonds.”
The problem of photocathode
Current electron beam accelerators often use thermal emission – the process of heating fabric to release electrons. The accelerator’s next technology will generate sources of electrons from photons, using photovoltaic cells – supplies that can convert photons into free electrons and thus electron beams. . The characteristic of that process is the generation of corrosive gases that add critical forces and tear the photovoltaic cells, disrupting the analytical service and including time and value for innovations. .
“Long-term accelerators increasingly require more efficient electron beams,” said Yamaguchi. “However, these performance needs significantly exceed the capabilities of modern electron sources.”
For photocathodes to function in next-generation accelerators, a suitable protective coating must be discovered. It is the result of a reaction from photons that place photocathodes that give off electrons, and at the same time generate a corrosive fuel that can rapidly degrade bialkalium thin-film photocathodes, products of antimony, potassium, and cesium.
Cesium is the perfect material for accelerators due to its low efficiency. The working action is the amount of gas that wants to remove an electron from the fabric and place it in a vacuum, an important step in electron beam manufacturing. That low work activity comes at a cost, though, in the higher category of harm from chemical reactions and sensitivity to ion bombardment. The lifetime of the thin film photocathode is limited even in the ultra-high vacuum state.
Graphene offers promising results
The researchers searched for a fabric that could protect the photocathode while allowing the emission of electrons. They discovered their answer in graphene.
“As far as I know, there isn’t a single different material that can transfer electrons and for the same time will protect the fabric,” says Yamaguchi. “A really porous material would allow electrons to travel, but then you might not be able to protect the fabric from corrosive fuel. The uniqueness of graphene is that it is atomically thin enough to transfer electrons, yet the atomic structure can also be packed simply enough that no corrosive fuel can seep through it.”
Coating biological photocathode presents a bold engineering problem. Distributed on the photocathode in a layer just one atom thick, graphene possesses excessive fuel impermeability, which protects the photocathode from the harmful effects of gases produced by the conversion of photons to free electrons. In similar time, graphene’s excessive quantum efficiency (a measure of how unique a cloth converts photons to electrons) implies that electrons can nonetheless penetrate the mantle – important for generate and accelerate an electron beam for analysis. The researchers found that the transmission efficiency of the optoelectronics was 5%, which in principle has the potential to enhance by about 50%, a promising charge that shows the fabric is protected while still allowing it to generate an electron beam.
“These results represent essential advances for fully encapsulated biophotovoltaic cells each with excessive QE and long lifetimes using safety layers,” said Yamaguchi. atomically thin,” Yamaguchi said.
The photocathode coating builds on the “Atomic Armor” expertise, selected for the acclaimed R&D 100 in 2019. Previous analysis with graphene expertise explored its usefulness as an eating barrier. wear and tear, used for cars, ships, airplanes and various other items.
References: “Photoemission from Bialkali Photocathodes by an Atomally Skinny Safety Layer” by Fangze Liu, Lei Guo, Jeffrey DeFazio, Vitaly Pavlenko, Masahiro Yamamoto, Nathan A. Moody and Hisato Yamaguchi, December 22, 2022, ACS Utitified Materials and Interfaces.
DOI: 10.1021 / acsami.1c19393
Funding: This work was supported by the U.S. Department of Energy Science (DOE) U.S.-Japan Science and Technology Collaborative Program in Excess Vitality Physics. In part, the research was conducted at the Center for Integrated Nanotechnology, a Workplace Consumer Science Facility operated for the US Department of Energy (DOE), the Workplace of Science. .
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