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8. Open quantum systems: interaction of a biosystem with its environment

As was already emphasized, any biosystem $S$ is fundamentally open. Hence, dynamics of its state has to be modeled via an interaction with surrounding environment $\varepsilon$ . The states of $S$ and $\varepsilon$ are represented in the Hilbert spaces ${\mathcal {H}}$ and ${\mathcal {H}}$ . The compound system $S+\varepsilon$ is represented in the tensor product Hilbert spaces . This system is treated as an isolated system and in accordance with quantum theory, dynamics of its pure state can be described by the Schrödinger equation:

i{\tfrac {d}{dt}}\Psi (t)={\widehat {H}}\Psi (t)(t),\Psi (0)=\Psi _{0}

(21)

where $\psi (t)$ is the pure state of the system $S+\varepsilon$ and ${\hat {\mathcal {H}}}$ is its Hamiltonian. This equation implies that the pure state $\psi (t)$ evolves unitarily : $\psi (t)={\hat {U}}(t)\psi _{0}$ . Here ${\hat {U}}(t)=e^{-it{\hat {\mathcal {H}}}}$ . Hamiltonian (evolution-generator) describing information interactions has the form ${\hat {\mathcal {H}}}={\hat {\mathcal {H}}}_{s}+{\hat {\mathcal {H}}}_{\varepsilon }+{\mathcal {{\hat {H}}_{S,\varepsilon }}}$ , where ${\hat {\mathcal {H}}}_{s}$ , ${\hat {\mathcal {H}}}_{\varepsilon }$ are Hamiltonians of the systems and ${\mathcal {{\hat {H}}_{S,\varepsilon }}}$ is the interaction Hamiltonian.12 This equation implies that evolution of the density operator ${\hat {\mathcal {R}}}(t)$ of the system $S+\varepsilon$ is described by von Neumann equation:

{\tfrac {d{\widehat {R}}}{dt}}(t)=-i[{\widehat {H}},{\widehat {R}},(t)],{\widehat {R}}(0)={\widehat {R}}_{0}

(22)

However, the state ${\hat {\mathcal {R}}}(t)$ is too complex for any mathematical analysis: the environment includes too many degrees of freedom. Therefore, we are interested only the state of $S$ ; its dynamics is obtained via tracing of the state of $S+\varepsilon$ w.r.t. the degrees of freedom of $\varepsilon$ :

{\widehat {\rho }}(t)=Tr_{\mathcal {H}}{\widehat {R}}(t)

(23)

Generally this equation, the quantum master equation, is mathematically very complicated. A variety of approximations is used in applications.

8.1. Quantum Markov model: Gorini–Kossakowski–Sudarshan–Lindbladequation

The simplest approximation of quantum master equation (23) is the quantum Markov dynamics given by the Gorini–Kossakowski–Sudarshan–Lindblad (GKSL) equation (Ingarden et al., 1997)^[1] (in physics, it is commonly called simply the Lindblad equation; this is the simplest quantum master equation):

{\tfrac {d{\widehat {\rho }}}{dt}}(t)=-i[{\widehat {H}},{\widehat {\rho }},(t)]+{\widehat {L}}[{\widehat {\rho }}(t),{\widehat {\rho }}(0)={\widehat {\rho }}_{0}

(24)

where Hermitian operator (Hamiltonian) ${\widehat {\mathcal {H}}}$ describes the internal dynamics of $S$ and the superoperator ${\widehat {L}}$ , acting in the space of density operators, describes an interaction with environment $\varepsilon$ . This superoperator is often called Lindbladian. The GKSL-equation is a quantum master equation for Markovian dynamics. In this paper, we have no possibility to explain the notion of quantum Markovianity in more detail. Quantum master equation (23) describes generally non-Markovean dynamics.

↑ Ingarden R.S., Kossakowski A., OhyaM. Information Dynamics and Open Systems: Classical and Quantum Approach Kluwer, Dordrecht (1997

[1] Ingarden R.S., Kossakowski A., OhyaM. Information Dynamics and Open Systems: Classical and Quantum Approach Kluwer, Dordrecht (1997

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