A “square-root” method for the density matrix and its applications to Lindblad operators

Abstract: The evolution of open systems, subject to both Hamiltonian and dissipative forces, is studied by writing the nm element of the time (t) dependent density matrix in the formThe so called "square root factors", the γ(t)'s, are non-square matrices and are averaged over A systems (α) of the ensemble. This square-root description is exact. Evolution equations are then postulated for the γ(t) factors, such as to reduce to the Lindblad-type evolution equations for the diagonal terms in the density matrix. For the off… Show more

“…It is clear, that TDVP equations based on NOSSE definitions [Eqs. (20) and ( 21)] conserve the total energy of an isolated system, whereas the DM counterparts [Eqs. (18) and ( 19)] do not.…”

“…18) and ( 19)] and NOSSE [Eqs. (20) and ( 21)] formalisms. A basis set of 41 Gaussians is used in both cases.…”

“…Another approach is propagation of a square root of the density matrix. 20 This approach was developed only for the Lindblad type of QME, 5 and even within the Lindblad scope the resulting equations of motion are not fully equivalent to the initial QME. Yet another alternative has been suggested through constructing an approximate, so-called surrogate Hamiltonian that contains system and selected environmental DOF.…”

“…However, the propagation is stochastic, and simulations must be converged in the number of stochastic trajectories. Another approach is propagation of a square-root of the density matrix 20 . This approach was developed only for the Lindblad type of QME 5 , and even within the Lindblad scope the resulting equations of motion are not fully equivalent to the initial QME.…”

Non-stochastic matrix Schrödinger equation for open systems

“…It is clear, that TDVP equations based on NOSSE definitions [Eqs. (20) and ( 21)] conserve the total energy of an isolated system, whereas the DM counterparts [Eqs. (18) and ( 19)] do not.…”

“…18) and ( 19)] and NOSSE [Eqs. (20) and ( 21)] formalisms. A basis set of 41 Gaussians is used in both cases.…”

“…Another approach is propagation of a square root of the density matrix. 20 This approach was developed only for the Lindblad type of QME, 5 and even within the Lindblad scope the resulting equations of motion are not fully equivalent to the initial QME. Yet another alternative has been suggested through constructing an approximate, so-called surrogate Hamiltonian that contains system and selected environmental DOF.…”

“…However, the propagation is stochastic, and simulations must be converged in the number of stochastic trajectories. Another approach is propagation of a square-root of the density matrix 20 . This approach was developed only for the Lindblad type of QME 5 , and even within the Lindblad scope the resulting equations of motion are not fully equivalent to the initial QME.…”

Non-stochastic matrix Schrödinger equation for open systems

“…For example, the recently developed Ensemble Rank Truncation method (ERT) has at its heart a method for representing a Lindbladian evolution of a density in terms of a weighted sum of wavefunctions [40]. The wave operator has also been used for foundational research [41][42][43], but here we extend this to demonstrate that when combined with purification techniques from quantum information, it provides a natural bridge between the Hilbert space representation of quantum dynamics, the phase space Wigner representation, as well as KvN dynamics [44]. Through this, we are able to derive not only a consistent interpretation of mixed states in the Wigner representation, but also establish a connection between the commonly utilised phase space methods of quantum chemistry, and quantum information.…”

The wave operator representation of quantum and classical dynamics

Environment-effect on the Berry phase of a driven system in a magnetic field by the square-root method