Transistors And Quantum Tunneling at Skye Dyason blog

Transistors And Quantum Tunneling. Precise control over quantum tunneling is key because it enables the transistors to become “entangled” or interlinked in a way only possible through quantum mechanics. Molecular transistors operating in the quantum tunneling regime represent potential electronic building blocks for future integrated circuits. Two pieces of graphene connected by a single molecule (zinc porphyrin) serve as a test transistor that harnesses quantum interference for better performance. Semiconductor devices that rely on quantum tunnelling could be of use in logic, memory and radiofrequency applications. The electron has a pesky ability to penetrate barriers —a phenomenon known as quantum tunneling.

Precise control over quantum tunneling is key because it enables the transistors to become “entangled” or interlinked in a way only possible through quantum mechanics. Semiconductor devices that rely on quantum tunnelling could be of use in logic, memory and radiofrequency applications. Two pieces of graphene connected by a single molecule (zinc porphyrin) serve as a test transistor that harnesses quantum interference for better performance. The electron has a pesky ability to penetrate barriers —a phenomenon known as quantum tunneling. Molecular transistors operating in the quantum tunneling regime represent potential electronic building blocks for future integrated circuits.

Quantum mechanical transistor

Transistors And Quantum Tunneling Semiconductor devices that rely on quantum tunnelling could be of use in logic, memory and radiofrequency applications. Precise control over quantum tunneling is key because it enables the transistors to become “entangled” or interlinked in a way only possible through quantum mechanics. Two pieces of graphene connected by a single molecule (zinc porphyrin) serve as a test transistor that harnesses quantum interference for better performance. Molecular transistors operating in the quantum tunneling regime represent potential electronic building blocks for future integrated circuits. The electron has a pesky ability to penetrate barriers —a phenomenon known as quantum tunneling. Semiconductor devices that rely on quantum tunnelling could be of use in logic, memory and radiofrequency applications.