Monolayer borophene has a high charge capacity, mechanical strength, and low diffusion barrier, but it's not stable enough for practical use
They successfully created bilayer borophene, expanding the family of boron nanomaterials.
They studied a type of borophene called hydrogenated β12 borophene, which is more resistant to oxidation.
Borophene has metallic behavior and exceptional properties that make it suitable for use in sensors.
Researchers are developing a new material called borophene hybrid foam (CMB-foam) to create high-performance multifunctional materials
Researchers are delving into borophene, a highly promising material among the Xenes family
Toxic gases emitted by industries and vehicles cause environmental pollution and pose significant health risks which are becoming increasingly dangerous
Two-dimensional (2D) borophene materials are predicted to be ideal catalytic materials due to their structural analogy to graphene.
Boron shows a variety of properties, determining a chemistry rich and complementary to that of carbon
Researchers are studying a phenomenon called crossed Andreev reflection (CAR) in a special structure made with borophene
This material has excellent electrical conductivity and strength.
Researchers are working on improving a type of battery called a Li–O2 battery by adding a special component called a photoelectrode to its design.
Researchers are exploring a new material called α′-borophene nanoribbon (α′-BNR), which has remarkable properties making it highly efficient for use in thermoelectric devices.
The article discusses the advancements in borophene research, particularly the bilayer borophene, which has shown improved stability due tostrong B−B bonds between layers.
Hydrogen is gaining attention as a superb fuel option because it’s lightweight, burns cleanly, and has a high energy content
Borophene’s unique structure allows for effective magnetic and electronic control
The article discusses the exciting world of two-dimensional (2D) materials, which are materials that are only one atom thick and have very specific and useful properties.
The study investigates a boron-based two-dimensional (2D) material, which has been modified by adding a functional group called NLi4 to see if it can store hydrogen effectively.
The research presented in the abstract is about improving the process of photoelectrochemical(PEC) water splitting, which is a way to generate clean energy
Researchers have been exploring a new Borophene-based two-dimensional (2D) material, called monolayer B5Se, to see how well it can hold onto lithium (Li) atoms.
The researchers are interested in how this heterostructure behaves when it’s used in electronic devices.
The study relates to electrochemical water splitting, a process that can turn electricity into clean energy by using reactions at electrodes.
As the world looks for ways to meet its energy needs without harming the environment, green hydrogen has emerged as a promising option.
The study is about making materials that can absorb electromagnetic radiation—like light or radio waves—more efficiently.
This study discusses borophene, a two-dimensional (2D) material made of boron, which is fascinating due to its complex structure and the way electrons behave within it.
The study explores borophene, a material with a honeycomb structure made of boron atoms, which is interesting for its potential use in electronics.
This study discuss the potential of borophenebilayers (BBL)—which are two layers of boron atoms—as a material for creating electronic devices.
The research introduces a sophisticated neural network potential (NNP), which is a type of artificial intelligence model designed to predict how a material called borophene behaves when it’s placed on top of silver.
The study investigates a special kind of superconductivity in bilayer borophenes—materials made of two layers of boron atoms.
Borophene is a material that has unique properties, making it very interesting for scientific research, especially because of how it interacts with light and electricity
Borophene is an emerging material that’s capturing attention in the world of energy storage, particularly for devices called supercapacitors.
The study focuses on green energy systems, particularly fuel cells, which are seen as a key component in transitioning to environmentally friendly energy sources.
This research used Density FunctionalTheory (DFT) to explore how adding tiny particles of palladium (a precious metal) affects the ability of a materialcalled β12-borophene to store hydrogen.
The study is about how electricity moves through two types of tiny structures made by alternating layers of borophene (B) and graphene (G).
Graphene is known to conduct electricity well, but only for certain types of light in the infrared range, which is beyond what our eyes can see.
Borophene nanoribbons, or BNRs for short, are incredibly thin strips of boron atoms arranged in a line.
