Gustavo E Massaccesi, Ofelia B Oña, Pablo Capuzzi, Juan I Melo, Luis Lain, Alicia Torre, Juan E Peralta, Diego R Alcoba, Gustavo E Scuseria
{"title":"Determining the <i>N</i>-Representability of a Reduced Density Matrix via Unitary Evolution and Stochastic Sampling.","authors":"Gustavo E Massaccesi, Ofelia B Oña, Pablo Capuzzi, Juan I Melo, Luis Lain, Alicia Torre, Juan E Peralta, Diego R Alcoba, Gustavo E Scuseria","doi":"10.1021/acs.jctc.4c01166","DOIUrl":null,"url":null,"abstract":"<p><p>The <i>N</i>-representability problem consists in determining whether, for a given <i>p</i>-body matrix, there exists at least one <i>N</i>-body density matrix from which the <i>p</i>-body matrix can be obtained by contraction, that is, if the given matrix is a <i>p</i>-body reduced density matrix (<i>p</i>-RDM). The knowledge of all necessary and sufficient conditions for a <i>p</i>-body matrix to be <i>N</i>-representable allows the constrained minimization of a many-body Hamiltonian expectation value with respect to the <i>p</i>-body density matrix and, thus, the determination of its exact ground state. However, the number of constraints that complete the <i>N</i>-representability conditions grows exponentially with system size, and hence, the procedure quickly becomes intractable for practical applications. This work introduces a hybrid quantum-stochastic algorithm to effectively replace the <i>N</i>-representability conditions. The algorithm consists of applying to an initial <i>N</i>-body density matrix a sequence of unitary evolution operators constructed from a stochastic process that successively approaches the reduced state of the density matrix on a <i>p</i>-body subsystem, represented by a <i>p</i>-RDM, to a target <i>p</i>-body matrix, potentially a <i>p</i>-RDM. The generators of the evolution operators follow the well-known adaptive derivative-assembled pseudo-Trotter method (ADAPT), while the stochastic component is implemented by using a simulated annealing process. The resulting algorithm is independent of any underlying Hamiltonian, and it can be used to decide whether a given <i>p</i>-body matrix is <i>N</i>-representable, establishing a criterion to determine its quality and correcting it. We apply the proposed hybrid ADAPT algorithm to alleged reduced density matrices from a quantum chemistry electronic Hamiltonian, from the reduced Bardeen-Cooper-Schrieffer model with constant pairing, and from the Heisenberg XXZ spin model. In all cases, the proposed method behaves as expected for 1-RDMs and 2-RDMs, evolving the initial matrices toward different targets.</p>","PeriodicalId":45,"journal":{"name":"Journal of Chemical Theory and Computation","volume":null,"pages":null},"PeriodicalIF":5.7000,"publicationDate":"2024-11-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Chemical Theory and Computation","FirstCategoryId":"92","ListUrlMain":"https://doi.org/10.1021/acs.jctc.4c01166","RegionNum":1,"RegionCategory":"化学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"CHEMISTRY, PHYSICAL","Score":null,"Total":0}
引用次数: 0
Abstract
The N-representability problem consists in determining whether, for a given p-body matrix, there exists at least one N-body density matrix from which the p-body matrix can be obtained by contraction, that is, if the given matrix is a p-body reduced density matrix (p-RDM). The knowledge of all necessary and sufficient conditions for a p-body matrix to be N-representable allows the constrained minimization of a many-body Hamiltonian expectation value with respect to the p-body density matrix and, thus, the determination of its exact ground state. However, the number of constraints that complete the N-representability conditions grows exponentially with system size, and hence, the procedure quickly becomes intractable for practical applications. This work introduces a hybrid quantum-stochastic algorithm to effectively replace the N-representability conditions. The algorithm consists of applying to an initial N-body density matrix a sequence of unitary evolution operators constructed from a stochastic process that successively approaches the reduced state of the density matrix on a p-body subsystem, represented by a p-RDM, to a target p-body matrix, potentially a p-RDM. The generators of the evolution operators follow the well-known adaptive derivative-assembled pseudo-Trotter method (ADAPT), while the stochastic component is implemented by using a simulated annealing process. The resulting algorithm is independent of any underlying Hamiltonian, and it can be used to decide whether a given p-body matrix is N-representable, establishing a criterion to determine its quality and correcting it. We apply the proposed hybrid ADAPT algorithm to alleged reduced density matrices from a quantum chemistry electronic Hamiltonian, from the reduced Bardeen-Cooper-Schrieffer model with constant pairing, and from the Heisenberg XXZ spin model. In all cases, the proposed method behaves as expected for 1-RDMs and 2-RDMs, evolving the initial matrices toward different targets.
N-可再现性问题包括确定对于给定的 p 体矩阵,是否存在至少一个 N 体密度矩阵,可以通过收缩得到 p 体矩阵,即给定矩阵是否是 p 体还原密度矩阵(p-RDM)。掌握了 p 体矩阵可 N 表示的所有必要条件和充分条件,就可以对相对于 p 体密度矩阵的多体哈密顿期望值进行约束最小化,从而确定其精确基态。然而,完成 N-可表示性条件的约束条件数量随系统规模呈指数增长,因此,该过程在实际应用中很快变得难以处理。这项工作引入了一种量子-随机混合算法,以有效取代 N-可再现性条件。该算法包括对初始 N 体密度矩阵应用一串由随机过程构建的单元演化算子,该随机过程将 p 体子系统上密度矩阵的还原状态(由 p-RDM 表示)连续逼近目标 p 体矩阵(可能是 p-RDM)。演化算子的生成遵循著名的自适应导数组装伪特罗特方法(ADAPT),而随机部分则通过使用模拟退火过程来实现。由此产生的算法与任何底层哈密顿无关,可用于判断给定的 p 体矩阵是否可 N 代表示,建立判断其质量的标准并对其进行修正。我们将提出的混合 ADAPT 算法应用于量子化学电子哈密顿、具有恒定配对的还原巴丁-库珀-施里弗模型以及海森堡 XXZ 自旋模型的据称还原密度矩阵。在所有情况下,拟议方法在 1-RDM 和 2-RDM 中的表现都符合预期,初始矩阵朝着不同的目标演化。
期刊介绍:
The Journal of Chemical Theory and Computation invites new and original contributions with the understanding that, if accepted, they will not be published elsewhere. Papers reporting new theories, methodology, and/or important applications in quantum electronic structure, molecular dynamics, and statistical mechanics are appropriate for submission to this Journal. Specific topics include advances in or applications of ab initio quantum mechanics, density functional theory, design and properties of new materials, surface science, Monte Carlo simulations, solvation models, QM/MM calculations, biomolecular structure prediction, and molecular dynamics in the broadest sense including gas-phase dynamics, ab initio dynamics, biomolecular dynamics, and protein folding. The Journal does not consider papers that are straightforward applications of known methods including DFT and molecular dynamics. The Journal favors submissions that include advances in theory or methodology with applications to compelling problems.
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