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In quantum mechanics, an open quantum system is a system that interacts with its surrounding environment. Such systems cannot be fully described by a single wavefunction; instead, they are described using a density operator ${\displaystyle \rho }$.^[1] This interaction leads to phenomena such as decoherence and dissipation, which cause the loss of quantum coherence and energy into the environment. As a result, the system’s dynamics are typically governed by master equations that account for both unitary evolution and environmental effects.

The density operator provides a general description of quantum states, including both pure states and statistical mixtures:

${\displaystyle \rho =\sum _i{p}_i|{\psi }_i⟩⟨{\psi }_i|,}$

where ${\displaystyle p_i}$ are probabilities.

It satisfies:

• ${\displaystyle \rho \ge 0}$ (positive)
• ${\displaystyle \mathrm{T}\mathrm{r}(\rho )=1}$ (normalized)
• ${\displaystyle {\rho }^{†}=\rho }$ (Hermitian)

The expectation value of an observable ${\displaystyle \hat{A}}$ is

${\displaystyle ⟨\hat{A}⟩=\mathrm{T}\mathrm{r}(\rho \hat{A}).}$

For a system composed of a subsystem ${\displaystyle S}$ and environment ${\displaystyle E}$, the total state lives in

${\displaystyle {{\mathscr{H}}}_S\otimes {{\mathscr{H}}}_E.}$

The state of the subsystem alone is obtained by taking the partial trace over the environment:

${\displaystyle {\rho }_S={\mathrm{T}\mathrm{r}}_E({\rho }_{SE}).}$

This operation removes environmental degrees of freedom.

Even if the combined system ${\displaystyle {\rho }_{SE}}$ is in a pure state, the reduced state ${\displaystyle {\rho }_S}$ is generally mixed. This reflects entanglement between the system and its environment.

The density matrix formalism:

• allows description of open systems,
• captures statistical mixtures and decoherence,
• is essential in quantum information and thermodynamics.

Decoherence is the process by which a quantum system loses its coherent superposition due to interaction with its environment. It provides a mechanism for the emergence of classical behavior from quantum systems.^[2]

When a quantum system interacts with its environment, the combined system becomes entangled:

${\displaystyle |\psi {⟩}_S\otimes |E_0⟩\to \sum _i{c}_i|i{⟩}_S\otimes |E_i⟩.}$

The environment effectively "records" information about the system.

The reduced density matrix of the system becomes

${\displaystyle {\rho }_S={\mathrm{T}\mathrm{r}}_E({\rho }_{SE}).}$

Off-diagonal elements (coherences) in the density matrix decay over time:

${\displaystyle {\rho }_{ij}\to 0(i\ne j).}$

This suppresses interference effects.

Certain states, called pointer states, remain stable under environmental interaction. These states form the preferred basis in which classical behavior emerges.

Decoherence explains why quantum superpositions are not observed at macroscopic scales. It does not by itself select a single outcome, but it explains the apparent collapse of the wavefunction in practical terms.

Decoherence:

• explains the quantum-to-classical transition,
• limits coherence in quantum systems,
• is a major challenge in quantum computing and information processing.

It is a central concept in understanding real-world quantum systems.

In an open quantum system, the system of interest interacts with an external environment (or bath). This interaction is responsible for decoherence, dissipation, and noise.^[3]

The total Hamiltonian is typically written as

${\displaystyle \hat{H}={\hat{H}}_S+{\hat{H}}_E+{\hat{H}}_{\text{int}},}$

where:

• ${\displaystyle {\hat{H}}_S}$ describes the system,
• ${\displaystyle {\hat{H}}_E}$ describes the environment,
• ${\displaystyle {\hat{H}}_{\text{int}}}$ represents the interaction.

In many cases, the interaction between system and environment is weak. This allows approximate descriptions where:

• the environment acts as a reservoir,
• the system evolves with small perturbations.

This regime is often treated using perturbation theory.

If the environment has no memory (fast relaxation), the dynamics are called Markovian. In this case:

• the system evolution depends only on its current state,
• memory effects can be neglected.

This approximation leads to simple evolution equations.

If the environment retains memory, the system exhibits non-Markovian behavior:

• information can flow back from environment to system,
• coherence can partially recover,
• dynamics become more complex.

Environment coupling:

• explains why real quantum systems are never perfectly isolated,
• determines decoherence rates,
• is central to quantum technologies and noise control.

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