Abstract I accidentally dropped the phone and found that the screen was broken. It was really troublesome. Soon, you don't have to worry anymore because the researchers have developed a "magic material." This material is somewhat similar to silicon, but with stability and flexibility...
I accidentally dropped the phone, and when I picked it up, I found that the screen was broken. It was really troublesome. Soon, you don't have to worry anymore because the researchers have developed a "magic material." This material is somewhat similar to silicon, but with better stability and flexibility, making it ideal for making smart devices that don't break.
The team is made up of international researchers and is led by Queen's University of Belfast. They have developed a new material that is electrically conductive, illuminating, durable, and easy to manufacture on a large scale. The material is made of a particle called C60, which is a semiconductor coated with other materials such as graphene and hexagonal boron nitride. Why is this unique combination work? Because hexagonal boron nitride makes materials more stable and electronically compatible, the C60 converts sunlight into electricity.
Elton Santos, the lead author of the report, said: "Our findings show that this new material has similar physical properties to silicon, but it has better chemical stability, brightness and elasticity, so it can be used in intelligence. On the equipment, the possibility of breaking is lower."
The report also said: "With this material, the equipment architecture is very special, so the equipment consumes less energy, which can extend the battery life and is not easy to get an electric shock."
Santos initially believed that if hexagonal boron nitride, graphene and C60 were put together, a material with unique physicochemical properties should be formed. He then worked with international researchers to try to turn ideas into reality. Santos believes: "For theorists, this project is a bit like a 'dream project', because the experiment is highly consistent with my predictions, and this consistency is not easy to see. The model tells us that some assumptions are completely correct."
Although the material has potential, it is not yet available. For example, there is still a problem with the lack of band gaps in graphene and new material architectures, and switching of electronic devices. Bandgap is important for this operation. But the team has found a solution to the problem. They used a substance called TMD (transitional metal dichalcogenide), which is chemically stable.
The researchers said: "These materials are semiconductors, so we can skip the bandgap problem and we are about to develop a true transistor."
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