Trajectories is a Book I topic in the Quantum Collection. Quantum trajectories the stochastic time evolution of individual quantum systems interacting with an environment or undergoing continuous measurement. A representation of open quantum dynamics in terms of random pure-state evolutions instead of deterministic density matrix evolution. This approach is also known as the quantum jump method or stochastic unraveling of the master equation. Quantum trajectories the stochastic time evolution of individual quantum systems interacting with an environment or undergoing continuous measurement. A representation of open quantum dynamics in terms of random pure-state evolutions instead of deterministic density matrix evolution.{{cite book |last=Wiseman|first=H. J.|title=Quantum Measurement and Control|publisher=Cambridge University Press|year=2010|doi=10.1017/CBO9780511813948|url=https://www.cambridge.org/core/books/quantum-measurement-and-control/F78F445CD9AF00B10593405E9BAC6B9F This approach is also known as the quantum jump method or stochastic unraveling of the master equation.

Quantum Trajectories

Basic idea

Instead of evolving the density operator $ρ$ , quantum trajectories describe the evolution of a state vector $| ψ (t) ⟩$ subject to stochastic processes.

Ensemble interpretation

The density operator is recovered as an average over trajectories:

$ρ (t) = 𝔼 [| ψ (t) ⟩ ⟨ ψ (t) |] .$

Each trajectory corresponds to a possible physical realization of the system’s evolution.^[1]

Connection to Lindblad equation

Quantum trajectories provide an equivalent formulation of the Lindblad master equation.

Unraveling

The Lindblad equation

$\frac{d ρ}{d t} = - \frac{i}{ℏ} [\hat{H}, ρ] + \sum_{k} (L_{k} ρ L_{k}^{†} - \frac{1}{2} {L_{k}^{†} L_{k}, ρ})$

can be represented as stochastic evolution of pure states.^[2]

Physical meaning

continuous evolution → effective non-Hermitian Hamiltonian
jumps → discrete stochastic events

Together they reproduce the ensemble dynamics.

Quantum jump method

Effective Hamiltonian

Between jumps, the system evolves under

${\hat{H}}_{e f f} = \hat{H} - \frac{i ℏ}{2} \sum_{k} L_{k}^{†} L_{k} .$

This produces non-unitary evolution.^[3]

Jump process

At random times:

$| ψ ⟩ \to \frac{L_{k} | ψ ⟩}{‖ L_{k} | ψ ⟩ ‖} .$

The jump probability depends on $⟨ L_{k}^{†} L_{k} ⟩$ .

Continuous measurement

Quantum trajectories arise naturally in continuous measurement theory.

Measurement interpretation

Each trajectory corresponds to a measurement record.

Examples:

photon counting
homodyne detection
weak measurement

This links stochastic evolution to experimental observations.^[1]

Diffusive trajectories

In some cases, evolution is continuous rather than involving jumps.

Stochastic Schrödinger equation

$d | ψ ⟩ = - \frac{i}{ℏ} \hat{H} | ψ ⟩ d t + noise terms .$

These describe continuous monitoring processes.^[2]

Relation to decoherence

Decoherence emerges from averaging over trajectories:

individual trajectories remain pure
ensemble average produces mixed states

This explains loss of coherence in open systems.

Applications

Quantum optics

Used to model photon emission and detection processes.^[3]

Quantum information

Applied in:

quantum feedback
error correction
qubit monitoring^[1]

Numerical simulation

Trajectory methods are often more efficient than solving master equations directly.^[2]

Physical significance

Quantum trajectories provide a detailed picture of open quantum dynamics at the level of individual realizations. They unify stochastic processes, measurement theory, and quantum evolution.^[1]

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Physics:Quantum Trajectories

Quantum Trajectories

Basic idea

Ensemble interpretation

Connection to Lindblad equation

Unraveling

Physical meaning

Quantum jump method

Effective Hamiltonian

Jump process

Continuous measurement

Measurement interpretation

Diffusive trajectories

Stochastic Schrödinger equation

Relation to decoherence

Applications

Quantum optics

Quantum information

Numerical simulation

Physical significance

See also

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