Two-dimensional materials are expected to revolutionize the semiconductors industry. However, despite multiple studies that have reported prototype devices with promising properties for sensing and driving electrical current, their technology readiness level is still very low because they mostly use synthesis and processing methods that are incompatible with industry, create the large devices on unfunctional substrates, and present poor variability and yield.
A team of scientists at King Abdullah University of Science and Technology (KAUST) led by Dr. Mario Lanza, associate professor of materials science and engineering, has successfully integrated two-dimensional materials on silicon microchips, and achieved excellent integration density, electronic performance and yield. The study, Hybrid 2D/CMOS microchips for memristive applications, has been published as peer-reviewed research in Nature. "In the future, most microchips will exploit some of the many outstanding electronic and thrermal properties of these materials," said Lanza.
In particular Lanza's team used a two-dimensional insulating material called multilayer hexagonal boron nitride (about 6 nanometers thick), and employed microchips containing silicon transistors of complementary metal-oxide-semiconductor (CMOS) technology — a type of technology that is present in every electronic product we use such as phones, computers, automobiles, medical machines and household appliances. The resulting hybrid 2D/CMOS microchips exhibit high durability and special electronic properties that enable the fabrication of artificial neural networks with very low power consumption. They can successfully compute spiking neural networks — electrical stresses applied during very short time — a key component of current artificial intelligence systems that are increasing in demand. Most current devices are not suitable for implementing this type of neural network, and there is a market need to find new approaches.
The research has attracted the interest of leading semiconductor companies such as Taiwan Semiconductor Manufacturing Corporation (TSMC) and Advanced Semiconductor Materials Lithography (ASML) and could help other companies reduce processing costs and energy. Most companies in the field of microchip manufacturing and artificial intelligence are aiming to create new hardware that reduces data processing time and energy consumption but have not yet found a suitable device.
IBM has attempted to integrate graphene into transistors for radio-frequency applications, but the devices were not able to store or process information. In contrast, the devices created by Professor Lanza's team measure only 260 nanometers and could be made much smaller very easily if more advanced microchips were available.
This work is exciting for the field of nanoelectronics and semiconductors because of the high performance of the devices and circuits produced and the potential for far-reaching industry applications.
Link to the article: https://www.nature.com/articles/s41586-023-05973-1
Link to Prof. Lanza's group website: https://lanza.kaust.edu.sa/
About KAUST
Established in 2009, King Abdullah University of Science and Technology (KAUST) is a graduate research university devoted to finding solutions for some of the most pressing scientific and technological challenges in the world as well as Saudi Arabia in the areas of food and health, water, energy, environment and the digital domain. KAUST is a curiosity-driven, interdisciplinary problem-solving environment, with state-of-the-art labs, distinguished faculty and talented students.
KAUST brings together the best minds from around the world to advance research. More than 120 different nationalities live, work and study on campus. KAUST is also a catalyst for innovation, economic development and social prosperity, with research resulting in novel patents and products, enterprising startups, regional and global initiatives, and collaboration with other academic institutions, industries and Saudi agencies.
