2D conductive metal-organic framework maintains performance when stacked
Researchers designed a twisted 2D conductive MOF that preserves its electronic properties when stacked, advancing practical 2D materials.
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Researchers designed a twisted 2D conductive MOF that preserves its electronic properties when stacked, advancing practical 2D materials.
In a groundbreaking advancement poised to redefine materials science and molecular engineering, researchers have unveiled a novel strategy for fabricating ultrathin, free-standing...
Researchers have developed a new way to create moire patterns - atomic-scale structures that can give materials unusual quantum behaviors - without relying on the difficult-to-cont...
New technique allows researchers to probe the top layer of an atomically thin topological quantum material for the first time The post Encapsulation enhances surface structure imag...
Can 2D semiconductors replace silicon? A new pilot line targets 5nm-equivalent chips without relying on EUV lithography by 2029. Shanghai-based semiconductor start-up Yuanjiwei has...
A 3D soundwave lattice creates the first fully flat Landau levels, proving they can exist beyond two dimensions The post Flat bands go 3D appeared first on Physics World.
Researchers say the method could be used to develop next-generation devices used for accelerating research in quantum computing.
Researchers show that twisting atom-thin boron nitride layers can tune quantum light emitters, offering new control for quantum technologies.
A computer built with a 2D semiconductor integrates more than 1,400 transistors on one chip, demonstrating a path toward AI and edge computing. Researchers from Nanjing University,...
Ultrafast optical measurements expose buried crystal flaws in atom-thin insulating films, offering a non-destructive route to improve device materials.
Nanoscale Horiz., 2026, Accepted ManuscriptDOI: 10.1039/D6NH00044D, CommunicationLiyan Wang, Kaijun Feng, Shuai Liu, Jiehui Tian, Xiangdong Guo, Lin Geng, Yuchuan Xiao, Debo Hu, Li...
Researchers from the Max Planck Institute, National Center for Nanoscience and Technology in Beijing, University of Warsaw, TUD Dresden University of Technology, University of Müns...
Chinese researchers, in collaboration with Huawei Technologies, have built the world’s first parallel processor using a two-dimensional (2D) semiconductor. As silicon devices appro...
MXenes—atomically thin transition metal carbides and nitrides—are drawing fresh attention for one simple reason: their surfaces are never truly bare. During production, the “...
Insider Brief PRESS RELEASE — Honeycombs are famous for their elegant design, but now they may have found a new application: quantum computing. To collect knowledge from subatomic...
Researchers at MIT, University of Basel, Florida State University, the University of Florida and the National Institute for Materials Science in Japan have reported a new family of...
By showing when MXenes shift from order to disorder and how that affects performance, scientists are building a roadmap for tailored materials.
In a groundbreaking study published in Nature Chemistry, researchers have unveiled a novel cyclophane-based shielding strategy designed to achieve the singular dispersion of graphe...
Nanoscale Horiz., 2026, Accepted ManuscriptDOI: 10.1039/D5NH00644A, Review ArticleHao Wu, Li Yang, Gaojie Zhang, Wen Jin, Jie Yu, Bichen Xiao, Wenfeng Zhang, Haixin ChangThe anomal...
Atomic-scale MoOCl2 bends light with record strength, enabling ultrathin optics for smart contact lenses, AR glasses, and invisible wearables.
Researchers made 1-nm MoS2 nanotubes inside boron nitride shells, advancing atomically precise semiconductors for smaller future electronic devices.
Electron-beam cuts make twisted graphene rebuild itself into carbon nanotubes, arrays, and Y-junctions through controlled edge chemistry.
A newly found chain-reaction phase change in 2D MoTe2 lowers energy barriers, enabling faster control of electronic and optical states for future devices.
US-based Avadain has developed a novel graphene type, which it brands as Large, Thin, Defect-Free (LTDF) graphene, which is meant to position graphene around high value application...
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