PlanetPhysics/Qubit2

\newcommand{\sqdiagram}[9]{Failed to parse (unknown function "\diagram"): {\displaystyle \diagram #1 \rto^{#2} \dto_{#4}& \eqno{\mbox{#9}}} }

Whereas in a classical computer the bit is the unit of information, in a quantum

device called a quantum computer--which is a special type of quantum automaton-- this is replaced by a corresponding concept called qubit.

A qubit, qbit or quantum bit is defined as the unit of quantum information which is contained in a quantum state vector for a two-level quantum system consisting of only two energy levels; mathematically this is expressed as a unit vector $\Psi$ in a a two-dimensional vector space $\mathbb {C} ^{2}$ over the field of complex numbers $\mathbb {C}$ .

In order to have any practical use such a qubit must also meet several conditions, such as: it has to be measurable, undergo controlled unitary transformations, have a long coherence time, be capable of initialization, and so on. Scalability to a quantum state space $\mathbb {C} ^{n}$ of $n\times 1$ column vectors with the inner product $(x,y)=x\dagger {}y$ is also such a condition, where $A\dagger {}$ denotes the transpose conjugate of $A$ . Then a unit vector $\psi$ in $\mathbb {C} ^{n}$ denotes a quantum state. As an example, in a superconducting flux qubit an electric current can be imagined to circulate simultaneously in a stable (or coherent) loop both clockwise and counterclockwise. A qubit in such a superposition is in a highly symmetrical quantum state. Superconducting qubits involve large numbers of particles (Cooper pairs) as the superconducting current involves many billions of such coherent electron pairs. In such a many-particle superconducting loop, spontaneous symmetry breaking tends to determine the qubit to end up in a definite state, by `breaking up the superposition'. On the other hand, an ion suspended in a magnetic trap or a single electron in a quantum dot on a chip do not exhibit this phenomenon. In August 2005, a group of physicists at the National Institute of Standards and Technology (NIST) suceeded in preparing single-ion qubits with a coherence time longer than 10 seconds.

A qudit is defined as the unit of quantum information in a $d$ -level quantum system $\mathbb {C} ^{d}$ which is contained in the unit vector in a vector space $\mathbb {C} ^{d}$ of dimension $d$ .

Furthermore, one can define as follows a more complex concept than the qudit by allowing for entanglement of quantum states. A quantum register ${\mathcal {R}}_{g}$ consists, or is determined by, a number $r$ of entangled qubits.

Quantum computers could then perform calculations by manipulating qubits within a quantum register. However, the requirement for long coherence times may be a major obstacle to building quantum computers ^[1].

All Sources edit

^[1]

References edit

↑ ^1.0 ^1.1 Graham P. Collins.,October 17, 2005, Quantum Bug: Qubits might spontaneously decay in seconds. Scientific American

[Collins2k5-1] 1.0 ^1.1 Graham P. Collins.,October 17, 2005, Quantum Bug: Qubits might spontaneously decay in seconds. Scientific American

[1]