A density matrix is a matrix that describes a quantum system in a mixed state, a statistical ensemble of several quantum states. (In contrast, a pure state is described by a single state vector). The density matrix is the quantum-mechanical analogue to a phase-space probability measure (probability distribution of position and momentum) in classical statistical mechanics.
Explicitly, suppose a quantum system may be found in state with probability p1, or it may be found in state with probability p2, or it may be found in state with probability p3, and so on. Then the density matrix for this system is
The expectation value for any observable A is given by
that is, the expectation value of A for the mixed state is the sum of the expectation values of A for each of the pure states, weighted by the probabilities pi.
Mixed states arise in situations where the experimenter does not know which particular states are being manipulated. Examples include a system in thermal equilibrium (at finite temperatures) or a system with an uncertain or randomly-varying preparation history (so one does not know which pure state the system is in). Also, if a quantum system has two or more subsystems that are entangled, then each subsystem must be treated as a mixed state even if the complete system is in a pure state. The density matrix is also a crucial tool in quantum decoherence theory.
The density matrix is a representation of a linear operator called the density operator. (The close relationship between matrices and operators is a basic concept in linear algebra.) In practice, the terms "density matrix" and "density operator" are often used interchangeably. Both matrix and operator are self-adjoint (or Hermitian), positive semi-definite, of trace one, and may be infinite-dimensional. The formalism was introduced by John von Neumann (and independently but less systematically by Lev Landau and Felix Bloch in 1927).
Read more about Density Matrix: Pure and Mixed States, Formulation, Measurement, Entropy, The Von Neumann Equation For Time Evolution, "Quantum Liouville", Moyal's Equation, Composite Systems, C*-algebraic Formulation of States
Famous quotes containing the word matrix:
“As all historians know, the past is a great darkness, and filled with echoes. Voices may reach us from it; but what they say to us is imbued with the obscurity of the matrix out of which they come; and try as we may, we cannot always decipher them precisely in the clearer light of our day.”
—Margaret Atwood (b. 1939)