Quantum information

In physics and computer science, quantum information is physical information that is held in the state of a quantum system. Quantum information is the basic entity that is studied in the burgeoning field of quantum information theory, and manipulated using the engineering techniques of quantum information processing. Much like classical information can be processed with digital computers, transmitted from place to place, manipulated with algorithms, and analyzed with the mathematics of computer science, so also analogous concepts apply to quantum information.

Quantum information

Quantum information differs strongly from classical information, epitomized by the bit, in many striking and unfamiliar ways. Among these are the following:

• A unit of quantum information is the qubit. Unlike classical digital states (which are discrete), a qubit is continuous-valued, describable by a direction on the Bloch sphere. Despite being continuously valued in this way, a qubit is the smallest possible unit of quantum information. The reason for this indivisibility is due to the Heisenberg uncertainty principle: despite the qubit state being continuously-valued, it is impossible to measure the value precisely.

• A qubit cannot be converted into classical bits; that is, it cannot be "read". This is the no-teleportation theorem.

• Despite the awkwardly-named no-teleportation theorem, qubits can be moved from one physical particle to another, by means of quantum teleportation. That is, qubits can be transported, independently of the underlying physical particle.

• An arbitrary qubit can neither be copied, nor destroyed. This is the content of the no cloning theorem and the no-deleting theorem.

• Although a single qubit can be transported from place to place (e.g. via quantum teleportation), it cannot be delivered to multiple recipients; this is the no-broadcast theorem, and is essentially implied by the no-cloning theorem.

• Qubits can be changed, by applying linear transformations or quantum gates to them, to alter their state.

• Classical bits may be combined with and extracted from configurations of multiple qubits, through the use of quantum gates. That is, two or more qubits can be arranged in such a way as to convey classical bits. The simplest such configuration is the Bell state, which consists of two qubits and four classical bits (i.e. requires two qubits and four classical bits to fully describe).

• Quantum information can be moved about, in a quantum channel, analogous to the concept of a classical communications channel. Quantum messages have a finite size, measured in qubits; quantum channels have a finite channel capacity, measured in qubits per second.

• Multiple qubits can be used to carry classical bits. Although n qubits can carry more than n classical bits of information, the greatest amount of classical information that can be retrieved is n. This is Holevo's theorem.

• Quantum information, and changes in quantum information, can be quantitatively measured by using an analogue of Shannon entropy, called the von Neumann entropy. Given a statistical ensemble of quantum mechanical systems with the density matrix , it is given by Many of the same entropy measures in classical information theory can also be generalized to the quantum case, such as Holevo entropy and the conditional quantum entropy.

• Quantum algorithms have a different computational complexity than classical algorithms. The most famous example of this is Shor's factoring algorithm, which is not known to have a polynomial time classical algorithm, but does have a polynomial time quantum algorithm. Other examples include Grover's search algorithm, where the quantum algorithm gives a quadratic speed-up over the best possible classical algorithm.

• Quantum encryption allows unconditionally secure transmission of classical information, unlike classical encryption, which can always be broken in principle, if not in practice. (Note that certain subtle points are hotly debated).

• Linear logic describes the logic of quantum information, in analogy to how classical logic works with classical bits. Linear logic is much like classical logic, except that Gentzen's rules for cloning are omitted. That is, entailment cannot be used to clone or delete logical premises, since qubits cannot be cloned or deleted.

• The simplest description^[1] of generalized quantum information is provided by dagger compact categories, in much the same way that categorical logic and type theory provide the foundations for computer science. This extends the Curry–Howard correspondence between proof theory and computation to quantum domains.

• The general framework for the manipulation of quantum states is given by categorical quantum mechanics.

The study of all of the above topics and differences comprises quantum information theory.

Quantum information theory

The theory of quantum information is a result of the effort to generalize classical information theory to the quantum world. Quantum information theory aims to investigate the following question:

How is information stored in a state of a quantum system?

As mentioned in the introduction, an arbitrary quantum state cannot be precisely converted in classical bits; this is the content of the no-teleportation theorem.

The information content of a message M can be measured in terms of the minimum number n of qubits needed to encode the message. Such a message M is encoded with n qubits and n² classical bits that describe the relative arrangement of the n qubits. The qubit is the smallest possible unit of quantum information.

Quantum information can be transmitted through quantum channels, which do have a finite capacity. This is analogous to the classical case, where the noisy-channel coding theorem defines the maximum channel capacity of a classical communications channel. An important breakthrough for the theory of quantum information occurred when quantum error correction codes and fault-tolerant quantum computation schemes were discovered.

Quantum information can be manipulated and processed using quantum logic gates, in rough analog to the processing of classical information with digital circuits.

Journals

Many journals publish research in quantum information science, although only a few are dedicated to this area. Among these are

• International Journal of Quantum Information
• Quantum Information & Computation
• Quantum Information Processing
• npj Quantum Information

See also

References

External links and references

• Quantiki - A wiki portal for quantum information with introductory tutorials.
• Charles H. Bennett and Peter W. Shor, "Quantum Information Theory," IEEE Transactions on Information Theory, Vol 44, pp 2724–2742, Oct 1998
• Gregg Jaeger's book on Quantum Information(published by Springer, New York, 2007, ISBN 0-387-35725-4)
• Lectures at the Institut Henri Poincaré (slides and videos)
• International Journal of Quantum Information World Scientific
• Quantum Information Processing Springer
• Mark M. Wilde, "From Classical to Quantum Shannon Theory", arXiv:1106.1445.
• Quantum information can be negative
• Centres and groups doing research on quantum information include:
  • Quantum Information Theory at ETH Zurich
  • Quantum Information Perimeter Institute for Theoretical Physics
  • Institute for Quantum Computing - The Institute for Quantum Computing, based in Waterloo, ON Canada, is a research institute working in conjunction with the University of Waterloo and Perimeter Institute on the subject of Quantum Information.
  • Centre for Quantum Technologies - CQT is a research centre at the National University of Singapore bringing together quantum physicists and computer scientists
  • Center for Quantum Computation - The CQC, part of Cambridge University, is a group of researchers studying quantum information, and is a useful portal for those interested in this field.
  • Quantum Information Group The quantum information research group at the University of Nottingham.
  • Research Group on Mathematics and Quantum Information Madrid
  • Institute for Quantum Information and Matter Caltech
  • Quantum Information Theory Imperial College
  • Quantum Information University College London
  • Quantum Information Technology Toshiba Research
  • USC Center for Quantum Information Science & Technology
  • Center for Quantum Information and Control Theoretical and experimental groups from University of New Mexico and University of Arizona.
  • Group of Quantum Information Theory Kyungnam University in Korea

Quantum information science General Quantum computer Qubit Quantum information Quantum programming Timeline of quantum computing Quantum communication Quantum capacity Classical capacity Entanglement-assisted classical capacity Quantum channel Quantum network Quantum cryptography Quantum key distribution Quantum energy teleportation Quantum teleportation Superdense coding LOCC Entanglement distillation Quantum algorithms Universal quantum simulator Deutsch–Jozsa algorithm Grover's algorithm Quantum Fourier transform Shor's algorithm Simon's problem Quantum phase estimation algorithm Quantum annealing Algorithmic cooling Quantum complexity theory Quantum Turing machine BQP QMA PostBQP Quantum computing models Quantum circuit Quantum gate One-way quantum computer cluster state Adiabatic quantum computation Topological quantum computer Decoherence prevention Quantum error correction Stabilizer codes Entanglement-Assisted Quantum Error Correction Quantum convolutional codes Physical implementations Quantum optics Cavity QED Circuit QED Linear optical quantum computing Ultracold atoms Trapped ion quantum computer Optical lattice Spin-based Nuclear magnetic resonance QC Kane QC Loss–DiVincenzo QC Nitrogen-vacancy center Superconducting quantum computing Charge qubit Flux qubit Phase qubit