Samsung Advanced Institute of Technology, the core R&D incubator for Samsung Electronics, has developed a new transistor structure utilizing graphene, touted as the “miracle material.” This research is believed to have brought us one step closer to the development of transistors that can overcome the limits of conventional silicon. Currently, semiconductor devices consist of billions of silicon transistors. To increase the performance of semiconductors (the speed of devices), the options have to been to either reduce the size of individual transistors to shorten the traveling distance of electrons, or to use a material with higher electron mobility, which allows for faster electron velocity. For the past 40 years, the industry has been increasing performance by reducing size. However, experts believe we are now nearing the potential limits of scaling down. Since graphene possesses electron mobility about 200 times greater than that of silicon, it has been considered a potential substitute.
Although one issue with graphene is that, unlike conventional semiconducting materials, the current cannot be switched off because it is semi-metallic. This has become the key issue in realizing graphene transistors. Both on and off flow of current is required in a transistor to represent “1” and “0” of digital signals. Previous solutions and research have tried to convert graphene into a semi-conductor. However, this radically decreased the mobility of graphene, leading to skepticism over the feasibility of graphene transistors. By re-engineering the basic operating principles of digital switches, Samsung Advanced Institute of Technology has developed a device that can switch off the current in graphene without degrading its mobility. The graphene-silicon Schottky barrier can switch current on or off by controlling the height of the barrier. The new device was named Barristor, after its barrier-controllable feature.
In addition, to expand the research into the possibility of logic device applications, the most basic logic gate (inverter – a logic gate that converts 0 into 1 and vice versa) and logic circuits (half-adder – adding two binary digits) were fabricated, and basic operation (adding) was demonstrated. Samsung Advanced Institute of Technology owns 9 major patents related to the structure and the operating method of the Graphene Barristor.
As demonstrated in this research, the institute has solved the most difficult problem in graphene device research and has opened the door to new directions for future studies. With scaling reaching its limits, this definitely looks like the material for the future.
Source:- Tech2
Although one issue with graphene is that, unlike conventional semiconducting materials, the current cannot be switched off because it is semi-metallic. This has become the key issue in realizing graphene transistors. Both on and off flow of current is required in a transistor to represent “1” and “0” of digital signals. Previous solutions and research have tried to convert graphene into a semi-conductor. However, this radically decreased the mobility of graphene, leading to skepticism over the feasibility of graphene transistors. By re-engineering the basic operating principles of digital switches, Samsung Advanced Institute of Technology has developed a device that can switch off the current in graphene without degrading its mobility. The graphene-silicon Schottky barrier can switch current on or off by controlling the height of the barrier. The new device was named Barristor, after its barrier-controllable feature.
In addition, to expand the research into the possibility of logic device applications, the most basic logic gate (inverter – a logic gate that converts 0 into 1 and vice versa) and logic circuits (half-adder – adding two binary digits) were fabricated, and basic operation (adding) was demonstrated. Samsung Advanced Institute of Technology owns 9 major patents related to the structure and the operating method of the Graphene Barristor.
As demonstrated in this research, the institute has solved the most difficult problem in graphene device research and has opened the door to new directions for future studies. With scaling reaching its limits, this definitely looks like the material for the future.
Source:- Tech2
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