Quantum nanoscience

Quantum nanoscience is the basic research area at the intersection of nanoscale science and quantum science that creates the understanding that enables development of nanotechnologies. It uses quantum mechanics to explore and utilize coherent quantum effects in engineered nanostructures. This may eventually lead to the design of new types of nanodevices and nanoscopic scale materials, where functionality and structure of quantum nanodevices are described through quantum phenomena such as superposition and entanglement. With the growing work toward realization of quantum computing, quantum has taken on new meaning that describes the effects at this scale. Current quantum refers to the quantum mechanical phenomena of superposition, entanglement and quantum coherence that are engineered instead of naturally-occurring phenomena. Quantum nanoscience is the basic research area at the intersection of nanoscale science and quantum science that creates the understanding that enables development of nanotechnologies. It uses quantum mechanics to explore and utilize coherent quantum effects in engineered nanostructures. This may eventually lead to the design of new types of nanodevices and nanoscopic scale materials, where functionality and structure of quantum nanodevices are described through quantum phenomena such as superposition and entanglement. With the growing work toward realization of quantum computing, quantum has taken on new meaning that describes the effects at this scale. Current quantum refers to the quantum mechanical phenomena of superposition, entanglement and quantum coherence that are engineered instead of naturally-occurring phenomena. Quantum nanoscience explores and utilizes coherent quantum effects in engineered nanostructures. Coherence is the property of a quantum system that allows to predict its evolution in time, once it has been prepared in a superposition of different quantum states. This property is important when one intends to use the system for specific tasks, such as performing a sequence of logic operations in a quantum computer. Quantum coherence is fragile and can easily be lost if the system becomes too large or is subjected to uncontrolled interactions with the environment. Quantum coherence-enabled functionality holds the promise of making possible disruptive technologies such as quantum computing, quantum communication, quantum simulation, and quantum sensing. Coherent quantum effects at the nanoscale are relatively uncharted territory. Therefore the field of quantum nanoscience is special among basic sciences in that because it provides a pathway into this frontier of human knowledge. Quantum coherence is at the very heart of quantum nanoscience. The goal of the field is to manipulate and exploit quantum-coherent functionality. Much of the quantum nanoscience is dedicated to understanding the mechanisms of decoherence in order to preserve and maximize coherence. Superposition is the quantum phenomena wherein an entity can simultaneously exist in two states. The classic description is the though experiment of Schroedinger’s Cat. In this gedanken experiment, the cat can be both alive and dead until the state of the cat is actually observed. Entanglement can link the quantum states of two or more objects over any distance. Entanglement lies at the heart of quantum teleportation and quantum communication.