Draft:Open-system formulations in quantum computing.

In an isolated system, the quantum state \(\psi\) evolves unitarily according to a time-dependent Hamiltonian \(H(t)\):

${\displaystyle U(t)={\mathcal {T}}\exp \!\left[-{\frac {i}{\hbar }}\int _{0}^{t}H(t')\,dt'\right]}$ 

where {T} is the time-ordering operator, H is the reduced Planck constant, and U(t) is the time evolution operator.

Realistic quantum devices are not perfectly isolated. Interactions with external degrees of freedom—such as phonons, photons, and control electronics—introduce errors that alter qubit states.^[2] These effects can be described in terms of quantum channels or modifications to the system’s effective dynamics.

Several mathematical approaches exist for modeling open-system dynamics, depending on the noise characteristics and the system–environment coupling.

• Lindblad equation (Markovian noise): For weak and memoryless noise, the evolution of the density matrix \(\rho\) is given by:

${\displaystyle {\frac {d\rho }{dt}}=-{\frac {i}{\hbar }}[H,\rho ]+\sum _{k}\left(L_{k}\rho L_{k}^{\dagger }-{\tfrac {1}{2}}\{L_{k}^{\dagger }L_{k},\rho \}\right)}$ 

where ${\displaystyle L_{k}}$  represent specific noise processes such as dephasing. The commutator is ${\displaystyle [A,B]=AB-BA}$  and the anticommutator is ${\displaystyle \{A,B\}=AB+BA}$ .^[4][5]

• Redfield equation (non-Markovian noise): For environments with memory effects, the Redfield equation is used:

${\displaystyle {\frac {d\rho (t)}{dt}}=-{\frac {i}{\hbar }}[H_{S},\rho (t)]-\int _{0}^{t}d\tau \,\operatorname {Tr} _{E}\left[H_{I}(t),[H_{I}(\tau ),\rho (t)\otimes \rho _{E}]\right]}$ 

where ${\displaystyle H_{I}}$  is the interaction Hamiltonian and ${\displaystyle \rho _{E}}$  is the environment density matrix.

• Collisional decoherence: Environmental particle collisions can reduce spatial coherence:

${\displaystyle C(t)\approx \exp[-\Gamma t],\quad \Gamma \propto n\,v\,\sigma _{\rm {decoh}}}$ 

where ${\displaystyle \sigma _{\rm {decoh}}}$  is the effective cross-section for decoherence.

Open-system models are central to understanding error processes such as dephasing and relaxation in qubit devices. The dominant sources of noise depend on the underlying platform (e.g., trapped ion qubits, neutral atom qubits, or superconducting circuits).^[1][2][3] By providing a unified framework, open-system methods guide both experimental characterization and the design of error-correction strategies.

• Open quantum system
• Quantum decoherence
• Lindblad equation
• Quantum master equation
• Quantum noise
• Density matrix
• Hamiltonian (quantum mechanics)

• Breuer, H.-P.; Laine, E.-M.; Piilo, J.; Vacchini, B. (2016). "Colloquium: Non-Markovian dynamics in open quantum systems". Reviews of Modern Physics. 88 (2): 021002. arXiv:1505.01385. Bibcode:2016RvMP...88b1002B. doi:10.1103/RevModPhys.88.021002. hdl:2434/387123.