Chinese scientists have achieved a unique feat that could revolutionize the economy by turning diamonds into high-value electrons. Known for its exceptional hardness and thermal conductivity, diamond has long been valued for its durability and many uses. However, their inability to produce electricity limits their effectiveness in some areas.
Collaboration between researchers from famous universities such as Zhengzhou University, Henan Academy of Science, Ningbo University and Jilin University has led to the development of energy-saving materials such as concrete, diamond. Produced through a new process, the diamond combines the strength of diamond with the conductivity of graphene, another type of carbon known for its excellent electrical properties. According to tradition, diamonds form on the earth’s surface over billions of years. However, synthetic stones are popular due to their low cost and ease of production. Zhengzhou, Henan, China, is a major center for large-scale concrete production, an industry that uses technologies such as high-pressure heat treatment (HPHT) and carbon vapor deposition (CVD) to produce synthetic stone.
The new method developed by the researchers involves combining diamond and graphene to create an ultra-thin diamond that interacts with the graphene layer. These diamonds gain electrical conductivity while conserving energy, making them ideal for use in harsh environments such as aerospace applications and electrocatalysis in wastewater treatment. Despite their excellent properties, these new diamonds have properties that differ from traditional diamonds, such as black particles due to the presence of graphene. But scientists believe they can change the size and shape of these diamonds to meet specific needs.
In summary, the development of conductive diamond represents a major advance in information science. With their unique composition, these diamonds have the ability to transform many industries, offering new possibilities for their practical use in business.