| Author | Brecht, Donvil | dc.contributor.author |
| Author | Muratore-Ginanneschi, Paolo | dc.contributor.author |
| Date of accession | 2023-03-30T14:39:16Z | dc.date.accessioned |
| Available in OPARU since | 2023-03-30T14:39:16Z | dc.date.available |
| Date of first publication | 2022-07-16 | dc.date.issued |
| Abstract | Master equations are one of the main avenues to study open quantum systems. When the master equation is of the Lindblad–Gorini–Kossakowski–Sudarshan form, its solution can be “unraveled in quantum trajectories” i.e., represented as an average over the realizations of a Markov process in the Hilbert space of the system. Quantum trajectories of this type are both an element of quantum measurement theory as well as a numerical tool for systems in large Hilbert spaces. We prove that general time-local and trace-preserving master equations also admit an unraveling in terms of a Markov process in the Hilbert space of the system. The crucial ingredient is to weigh averages by a probability pseudo-measure which we call the “influence martingale”. The influence martingale satisfies a 1d stochastic differential equation enslaved to the ones governing the quantum trajectories. We thus extend the existing theory without increasing the computational complexity. | dc.description.abstract |
| Language | en | dc.language.iso |
| Publisher | Universität Ulm | dc.publisher |
| License | CC BY 4.0 International | dc.rights |
| Link to license text | https://creativecommons.org/licenses/by/4.0/ | dc.rights.uri |
| Dewey Decimal Group | DDC 530 / Physics | dc.subject.ddc |
| LCSH | Quantum theory | dc.subject.lcsh |
| LCSH | Theoretical physics | dc.subject.lcsh |
| Title | Quantum trajectory framework for general time-local master equations | dc.title |
| Resource type | Wissenschaftlicher Artikel | dc.type |
| Version | publishedVersion | dc.description.version |
| DOI | http://dx.doi.org/10.18725/OPARU-48016 | dc.identifier.doi |
| URN | http://nbn-resolving.de/urn:nbn:de:bsz:289-oparu-48092-0 | dc.identifier.urn |
| GND | Quantenmechanik | dc.subject.gnd |
| GND | Theoretische Physik | dc.subject.gnd |
| Faculty | Fakultät für Naturwissenschaften | uulm.affiliationGeneral |
| Institution | Institut für Komplexe Quantensysteme | uulm.affiliationSpecific |
| Institution | Center for Integrated Quantum Science and Technology (IQST) | uulm.affiliationSpecific |
| Peer review | ja | uulm.peerReview |
| DCMI Type | Text | uulm.typeDCMI |
| Category | Publikationen | uulm.category |
| DOI of original publication | 10.1038/s41467-022-31533-8 | dc.relation1.doi |
| Source - Title of source | Nature Communications | source.title |
| Source - Place of publication | Nature Research | source.publisher |
| Source - Volume | 13 | source.volume |
| Source - Year | 2022 | source.year |
| Source - Article number | 4140 | source.articleNumber |
| Source - eISSN | 2041-1723 | source.identifier.eissn |
| Bibliography | uulm | uulm.bibliographie |
| Is Supplemented By | https://www.nature.com/articles/s41467-022-31533-8#Sec17 | dc.relation.isSupplementedBy |
