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dc.contributor.authorCoates, Alexandre R.
dc.contributor.authorLovett, Brendon W.
dc.contributor.authorGauger, Erik M.
dc.identifier.citationCoates , A R , Lovett , B W & Gauger , E M 2023 , ' From Goldilocks to twin peaks : multiple optimal regimes for quantum transport in disordered networks ' , Physical Chemistry Chemical Physics , vol. 25 , no. 14 , pp. 10103-10112 .
dc.identifier.otherPURE: 283923626
dc.identifier.otherPURE UUID: 3113458e-a290-4403-8d89-c8a6d2e38136
dc.identifier.otherJisc: 985633
dc.identifier.otherpublisher-id: d2cp04935j
dc.identifier.otherORCID: /0000-0001-5142-9585/work/132214288
dc.identifier.otherScopus: 85151912502
dc.descriptionFunding: This work was supported by EPSRC Grant No. EP/L015110/1, EP/T007214/1, EP/T01377X/1, and EP/T014032.en
dc.description.abstractUnderstanding energy transport in quantum systems is crucial for an understanding of light-harvesting in nature, and for the creation of new quantum technologies. Open quantum systems theory has been successfully applied to predict the existence of environmental noise-assisted quantum transport (ENAQT) as a widespread phenomenon occurring in biological and artificial systems. That work has been primarily focused on several ‘canonical’ structures, from simple chains, rings and crystals of varying dimensions, to well-studied light-harvesting complexes. Studying those particular systems has produced specific assumptions about ENAQT, including the notion of a single, ideal, range of environmental coupling rates that improve energy transport. In this paper we show that a consistent subset of physically modelled transport networks can have at least two ENAQT peaks in their steady state transport efficiency.
dc.relation.ispartofPhysical Chemistry Chemical Physicsen
dc.rightsCopyright © the author(s). Open Access Article. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence.en
dc.subjectQC Physicsen
dc.titleFrom Goldilocks to twin peaks : multiple optimal regimes for quantum transport in disordered networksen
dc.typeJournal articleen
dc.description.versionPublisher PDFen
dc.contributor.institutionUniversity of St Andrews. School of Physics and Astronomyen
dc.contributor.institutionUniversity of St Andrews. Centre for Designer Quantum Materialsen
dc.contributor.institutionUniversity of St Andrews. Condensed Matter Physicsen
dc.description.statusPeer revieweden

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