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量子統計力學英语quantum statistical mechanics中,以科學家約翰·馮·紐曼命名的馮紐曼熵是古典吉布士熵在量子力學領域的延伸。對於由密度矩陣ρ描述的量子力學系統,馮·諾依曼熵是[1]

代表 跡數 , ln 代表一個自然對數矩陣。當ρ用代表自身的特徵值和特徵向量 |1〉, |2〉, |3〉, 可以寫成以下形式:

進而可以將「馮紐曼熵」改寫成以下形式[1]

在這個形式中,S可視為資訊理論中的[1][需要解释]

背景

约翰·冯·诺伊曼於1932年所出版的著作《量子力学的数学基础》中建立了一套嚴謹的數學架構來計算量子力學。[2]他在書中提供一套量測的理論,波函數的塌縮在其中被視為一種不可逆的過程。

John von Neumann established a rigorous mathematical framework for quantum mechanics in his 1932 work Mathematical Foundations of Quantum Mechanics.[3] In it, he provided a theory of measurement, where the usual notion of wave-function collapse is described as an irreversible process (the so-called von Neumann or projective measurement).

這邊會使用密度矩陣來進行計算。约翰·冯·诺伊曼朗道不約而同都使用了密度矩陣進行運算,但兩人使用的動機並不相同。給予朗道靈感的是,不可能用狀態向量來描述複合量子系統的子系統這件事。[4]约翰·冯·诺伊曼使用密度矩陣是為了發展量子統計力學和量子測量理論。

The density matrix was introduced, with different motivations, by von Neumann and by Lev Landau. The motivation that inspired Landau was the impossibility of describing a subsystem of a composite quantum system by a state vector.[5] On the other hand, von Neumann introduced the density matrix in order to develop both quantum statistical mechanics and a theory of quantum measurements.

發展密度矩陣是為了將古典統計力學的計算工具拓展到量子的領域。在古典物理架構之下,為了計算一個系統中與熱力學有關的物理量,必須先計算一個系統的配分函数。馮紐曼熵以希爾伯特空間作為基礎,使用密度函數來描述狀態,並在希爾伯特空間中進行計算。統計密度矩陣計算的知識可以產生一種,與原先的計算方式不同,但是概念上相同的計算方法。假設有一個波函數|Ψ〉 ,這個波函數藉由一組量子數n1, n2, ..., nN來決定。

The density matrix formalism was developed to extend the tools of classical statistical mechanics to the quantum domain. In the classical framework we compute the partition function of the system in order to evaluate all possible thermodynamic quantities. Von Neumann introduced the density matrix in the context of states and operators in a Hilbert space. The knowledge of the statistical density matrix operator would allow us to compute all average quantities in a conceptually similar, but mathematically different way. Let us suppose we have a set of wave functions |Ψ〉 that depend parametrically on a set of quantum numbers n1, n2, ..., nN. The natural variable which we have is the amplitude with which a particular wavefunction of the basic set participates in the actual wavefunction of the system. Let us denote the square of this amplitude by p(n1, n2, ..., nN). The goal is to turn this quantity p into the classical density function in phase space. We have to verify that p goes over into the density function in the classical limit, and that it has ergodic properties. After checking that p(n1, n2, ..., nN) is a constant of motion, an ergodic assumption for the probabilities p(n1, n2, ..., nN) makes p a function of the energy only.

After this procedure, one finally arrives at the density matrix formalism when seeking a form where p(n1, n2, ..., nN) is invariant with respect to the representation used. In the form it is written, it will only yield the correct expectation values for quantities which are diagonal with respect to the quantum numbers n1, n2, ..., nN.

Expectation values of operators which are not diagonal involve the phases of the quantum amplitudes. Suppose we encode the quantum numbers n1, n2, ..., nN into the single index i or j. Then our wave function has the form

 

The expectation value of an operator B which is not diagonal in these wave functions, so

 

The role which was originally reserved for the quantities   is thus taken over by the density matrix of the system S.

 

Therefore, 〈B〉 reads

 

The invariance of the above term is described by matrix theory. A mathematical framework was described where the expectation value of quantum operators, as described by matrices, is obtained by taking the trace of the product of the density operator   and an operator   (Hilbert scalar product between operators). The matrix formalism here is in the statistical mechanics framework, although it applies as well for finite quantum systems, which is usually the case, where the state of the system cannot be described by a pure state, but as a statistical operator   of the above form. Mathematically,   is a positive-semidefinite Hermitian matrix with unit trace.

定義

Given the density matrix ρ, von Neumann defined the entropy[6][7] as

 

which is a proper extension of the Gibbs entropy (up to a factor kB) and the Shannon entropy to the quantum case. To compute S(ρ) it is convenient (see logarithm of a matrix英语logarithm of a matrix) to compute the Eigendecomposition of  . The von Neumann entropy is then given by

 

Since, for a pure state, the density matrix is idempotent英语Idempotent matrix, ρ = ρ2, the entropy S(ρ) for it vanishes. Thus, if the system is finite (finite-dimensional matrix representation), the entropy S(ρ) quantifies the departure of the system from a pure state. In other words, it codifies the degree of mixing of the state describing a given finite system. Measurement decoheres a quantum system into something noninterfering and ostensibly classical; so, e.g., the vanishing entropy of a pure state  , corresponding to a density matrix

 

increases to   for the measurement outcome mixture

 

as the quantum interference information is erased.

性質

Some properties of the von Neumann entropy:

  • S(ρ) is zero if and only if ρ represents a pure state.
  • S(ρ) is maximal and equal to ln N for a maximally mixed state, N being the dimension of the Hilbert space.
  • S(ρ) is invariant under changes in the basis of ρ, that is, S(ρ) = S(UρU), with U a unitary transformation.
  • S(ρ) is concave, that is, given a collection of positive numbers λi which sum to unity ( ) and density operators ρi, we have
 
  • S(ρ) is additive for independent systems. Given two density matrices ρA , ρB describing independent systems A and B, we have
 .
  • S(ρ) is strongly subadditive for any three systems A, B, and C:
 
This automatically means that S(ρ) is subadditive:
 

Below, the concept of subadditivity is discussed, followed by its generalization to strong subadditivity.

次可加性

If ρA, ρB are the reduced density matrices of the general state ρAB, then

 

This right hand inequality is known as subadditivity. The two inequalities together are sometimes known as the triangle inequality. They were proved in 1970 by Huzihiro Araki英语Huzihiro Araki and Elliott H. Lieb.[8] While in Shannon's theory the entropy of a composite system can never be lower than the entropy of any of its parts, in quantum theory this is not the case, i.e., it is possible that S(ρAB) = 0, while S(ρA) = S(ρB) > 0.

Intuitively, this can be understood as follows: In quantum mechanics, the entropy of the joint system can be less than the sum of the entropy of its components because the components may be entangled. For instance, as seen explicitly, the Bell state英语Bell state of two spin-½s,

 

is a pure state with zero entropy, but each spin has maximum entropy when considered individually in its reduced density matrix.[9] The entropy in one spin can be "cancelled" by being correlated with the entropy of the other. The left-hand inequality can be roughly interpreted as saying that entropy can only be cancelled by an equal amount of entropy.

If system A and system B have different amounts of entropy, the smaller can only partially cancel the greater, and some entropy must be left over. Likewise, the right-hand inequality can be interpreted as saying that the entropy of a composite system is maximized when its components are uncorrelated, in which case the total entropy is just a sum of the sub-entropies. This may be more intuitive in the phase space formulation, instead of Hilbert space one, where the Von Neumann entropy amounts to minus the expected value of the -logarithm of the Wigner function, ∫ f log f  dx dp, up to an offset shift.[7] Up to this normalization offset shift, the entropy is majorized by that of its classical limit.

強次可加性

The von Neumann entropy is also strongly subadditive英语Strong Subadditivity of Quantum Entropy. Given three Hilbert spaces, A, B, C,

 

This is a more difficult theorem and was proved in 1973 by Elliott H. Lieb and Mary Beth Ruskai,[10] using a matrix inequality of Elliott H. Lieb[11] proved in 1973. By using the proof technique that establishes the left side of the triangle inequality above, one can show that the strong subadditivity inequality is equivalent to the following inequality.

 

when ρAB, etc. are the reduced density matrices of a density matrix ρABC. If we apply ordinary subadditivity to the left side of this inequality, and consider all permutations of A, B, C, we obtain the triangle inequality for ρABC: Each of the three numbers S(ρAB), S(ρBC), S(ρAC) is less than or equal to the sum of the other two.

應用

The von Neumann entropy is being extensively used in different forms (conditional entropies, relative entropies, etc.) in the framework of quantum information theory.[12] Entanglement measures are based upon some quantity directly related to the von Neumann entropy. However, there have appeared in the literature several papers dealing with the possible inadequacy of the Shannon information measure, and consequently of the von Neumann entropy as an appropriate quantum generalization of Shannon entropy.[來源請求] The main argument is that in classical measurement the Shannon information measure is a natural measure of our ignorance about the properties of a system, whose existence is independent of measurement.

Conversely, quantum measurement cannot be claimed to reveal the properties of a system that existed before the measurement was made.[13] This controversy has encouraged some authors to introduce the non-additivity英语Additive map property of Tsallis entropy英语Tsallis entropy (a generalization of the standard Boltzmann–Gibbs entropy) as the main reason for recovering a true quantum information measure in the quantum context, claiming that non-local correlations ought to be described because of the particularity of Tsallis entropy.

相關條目

參考文獻

  1. ^ 1.0 1.1 1.2 Bengtsson, Ingemar; Zyczkowski, Karol. Geometry of Quantum States: An Introduction to Quantum Entanglement 1st. : 301. 
  2. ^ Von Neumann, John. Mathematische Grundlagen der Quantenmechanik. Berlin: Springer. 1932. ISBN 3-540-59207-5. ; Von Neumann, John. Mathematical Foundations of Quantum Mechanics. Princeton University Press. 1955. ISBN 978-0-691-02893-4. 
  3. ^ Von Neumann, John. Mathematische Grundlagen der Quantenmechanik. Berlin: Springer. 1932. ISBN 3-540-59207-5. ; Von Neumann, John. Mathematical Foundations of Quantum Mechanics. Princeton University Press. 1955. ISBN 978-0-691-02893-4. 
  4. ^ Landau, L. Das Daempfungsproblem in der Wellenmechanik. Zeitschrift für Physik. 1927, 45 (5–6): 430–464. Bibcode:1927ZPhy...45..430L. doi:10.1007/BF01343064. 
  5. ^ Landau, L. Das Daempfungsproblem in der Wellenmechanik. Zeitschrift für Physik. 1927, 45 (5–6): 430–464. Bibcode:1927ZPhy...45..430L. doi:10.1007/BF01343064. 
  6. ^ Geometry of Quantum States: An Introduction to Quantum Entanglement, by Ingemar Bengtsson, Karol Życzkowski, p301
  7. ^ 7.0 7.1 Zachos, C. K. A classical bound on quantum entropy. Journal of Physics A: Mathematical and Theoretical. 2007, 40 (21): F407. Bibcode:2007JPhA...40..407Z. arXiv:hep-th/0609148 . doi:10.1088/1751-8113/40/21/F02. 
  8. ^ Huzihiro Araki and Elliott H. Lieb, Entropy Inequalities, Communications in Mathematical Physics, vol 18, 160–170 (1970).
  9. ^ Zurek, W. H. Decoherence, einselection, and the quantum origins of the classical. Reviews of Modern Physics. 2003, 75 (3): 715. Bibcode:2003RvMP...75..715Z. arXiv:quant-ph/0105127 . doi:10.1103/RevModPhys.75.715. 
  10. ^ Elliott H. Lieb and Mary Beth Ruskai, Proof of the Strong Subadditivity of Quantum-Mechanical Entropy, Journal of Mathematical Physics, vol 14, 1938–1941 (1973).
  11. ^ Elliott H. Lieb, Convex Trace Functions and the Wigner–Yanase–Dyson Conjecture, Advances in Mathematics, vol 67, 267–288 (1973).
  12. ^ Nielsen, Michael A. and Isaac Chuang. Quantum computation and quantum information Repr. Cambridge [u.a.]: Cambridge Univ. Press. 2001: 700. ISBN 978-0-521-63503-5. 
  13. ^ Pluch, P. (2006). Theory for Quantum Probability, PhD Thesis, Klagenfurt University.

Category:Quantum mechanical entropy英语Category:Quantum mechanical entropy Category:John von Neumann英语Category:John von Neumann