Lindbladian reverse engineering for general non-equilibrium steady states: A scalable null-space approach

da Silva Souza, Leonardo; Iemini, Fernando

doi:10.21468/SciPostPhys.20.1.009

SciPost Physics

Lindbladian reverse engineering for general non-equilibrium steady states: A scalable null-space approach

Leonardo da Silva Souza, Fernando Iemini

SciPost Phys. 20, 009 (2026) · published 16 January 2026

doi: 10.21468/SciPostPhys.20.1.009
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Abstract

The study of open system dynamics is of paramount importance both from its fundamental aspects as well as from its potential applications in quantum technologies. In the simpler and most commonly studied case, the dynamics of the system can be described by a Lindblad master equation. However, identifying the Lindbladian that leads to general non-equilibrium steady states (NESS) is usually a non-trivial and challenging task. Here we introduce a method for reconstructing the corresponding Lindbladian master equation given any target NESS, i.e., a Lindbladian Reverse Engineering ($\mathcal{L}$RE) approach. The method maps the reconstruction task to a simple linear problem. Specifically, to the diagonalization of a correlation matrix whose elements are NESS observables and whose size scales linearly (at most quadratically) with the number of terms in the Hamiltonian (Lindblad jump operator) ansatz. The kernel (null-space) of the correlation matrix corresponds to Lindbladian solutions. Moreover, the map defines an iff condition for $\mathcal{L}$RE, which works as both a necessary and a sufficient condition; thus, it not only defines, if possible, Lindbladian evolutions leading to the target NESS, but also determines the feasibility of such evolutions in a proposed setup. We illustrate the method in different systems, ranging from bosonic Gaussian systems, dissipative-driven collective spins and random local spin models.

TY  - JOUR
PB  - SciPost Foundation
DO  - 10.21468/SciPostPhys.20.1.009
TI  - Lindbladian reverse engineering for general non-equilibrium steady states: A scalable null-space approach
PY  - 2026/01/16
UR  - https://scipost.org/SciPostPhys.20.1.009
JF  - SciPost Physics
JA  - SciPost Phys.
VL  - 20
IS  - 1
SP  - 009
A1  - da Silva Souza, Leonardo
AU  - Iemini, Fernando
AB  - The study of open system dynamics is of paramount importance both from its fundamental aspects as well as from its potential applications in quantum technologies. In the simpler and most commonly studied case, the dynamics of the system can be described by a Lindblad master equation. However, identifying the Lindbladian that leads to general non-equilibrium steady states (NESS) is usually a non-trivial and challenging task. Here we introduce a method for reconstructing the corresponding Lindbladian master equation given any target NESS, i.e., a Lindbladian Reverse Engineering ($\mathcal{L}$RE) approach. The method maps the reconstruction task to a simple linear problem. Specifically, to the diagonalization of a correlation matrix whose elements are NESS observables and whose size scales linearly (at most quadratically) with the number of terms in the Hamiltonian (Lindblad jump operator) ansatz. The kernel (null-space) of the correlation matrix corresponds to Lindbladian solutions. Moreover, the map defines an iff condition for $\mathcal{L}$RE, which works as both a necessary and a sufficient condition; thus, it not only defines, if possible, Lindbladian evolutions leading to the target NESS, but also determines the feasibility of such evolutions in a proposed setup. We illustrate the method in different systems, ranging from bosonic Gaussian systems, dissipative-driven collective spins and random local spin models.
ER  -

@Article{10.21468/SciPostPhys.20.1.009,
	title={{Lindbladian reverse engineering for general non-equilibrium steady states: A scalable null-space approach}},
	author={Leonardo da Silva Souza and Fernando Iemini},
	journal={SciPost Phys.},
	volume={20},
	pages={009},
	year={2026},
	publisher={SciPost},
	doi={10.21468/SciPostPhys.20.1.009},
	url={https://scipost.org/10.21468/SciPostPhys.20.1.009},
}

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Open quantum systems

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¹ ² Leonardo da Silva Souza,
¹ Fernando Iemini

Funders for the research work leading to this publication