eprintid: 10151913 rev_number: 7 eprint_status: archive userid: 699 dir: disk0/10/15/19/13 datestamp: 2022-07-13 10:53:04 lastmod: 2022-07-13 10:53:04 status_changed: 2022-07-13 10:53:04 type: article metadata_visibility: show sword_depositor: 699 creators_name: Pedraza, Juan F creators_name: Russo, Andrea creators_name: Svesko, Andrew creators_name: Weller-Davies, Zachary title: Sewing spacetime with Lorentzian threads: complexity and the emergence of time in quantum gravity ispublished: pub divisions: C06 divisions: F60 divisions: B04 divisions: UCL keywords: Science & Technology, Physical Sciences, Physics, Particles & Fields, Physics, AdS-CFT Correspondence, Gauge-Gravity Correspondence, BLACK-HOLE, GEOMETRY, ENTANGLEMENT note: Open Access . This article is distributed under the terms of the Creative Commons Attribution License (CC-BY 4.0), which permits any use, distribution and reproduction in any medium, provided the original author(s) and source are credited. abstract: Holographic entanglement entropy was recently recast in terms of Riemannian flows or ‘bit threads’. We consider the Lorentzian analog to reformulate the ‘complexity=volume’ conjecture using Lorentzian flows — timelike vector fields whose minimum flux through a boundary subregion is equal to the volume of the homologous maximal bulk Cauchy slice. By the nesting of Lorentzian flows, holographic complexity is shown to obey a number of properties. Particularly, the rate of complexity is bounded below by conditional complexity, describing a multi-step optimization with intermediate and final target states. We provide multiple explicit geometric realizations of Lorentzian flows in AdS backgrounds, including their time-dependence and behavior near the singularity in a black hole interior. Conceptually, discretized flows are interpreted as Lorentzian threads or ‘gatelines’. Upon selecting a reference state, complexity thence counts the minimum number of gatelines needed to prepare a target state described by a tensor network discretizing the maximal volume slice, matching its quantum information theoretic definition. We point out that suboptimal tensor networks are important to fully characterize the state, leading us to propose a refined notion of complexity as an ensemble average. The bulk symplectic potential provides a specific ‘canonical’ thread configuration characterizing perturbations around arbitrary CFT states. Consistency of this solution requires the bulk satisfy the linearized Einstein’s equations, which are shown to be equivalent to the holographic first law of complexity, thereby advocating for a principle of ‘spacetime complexity’. Lastly, we argue Lorentzian threads provide a notion of emergent time. This article is an expanded and detailed version of [1], including several new results. date: 2022-02-11 date_type: published publisher: SPRINGER official_url: https://doi.org/10.1007/JHEP02(2022)093 oa_status: green full_text_type: pub language: eng primo: open primo_central: open_green verified: verified_manual elements_id: 1945011 doi: 10.1007/JHEP02(2022)093 lyricists_name: Svesko, Andrew lyricists_id: AMSVE02 actors_name: Kalinowski, Damian actors_id: DKALI47 actors_role: owner funding_acknowledgements: [Simons Foundation through It from Qubit: Simons Collaboration on Quantum Fields, Gravity , and Information]; [EPSRC] full_text_status: public publication: Journal of High Energy Physics volume: 2022 number: 2 article_number: 93 pages: 123 citation: Pedraza, Juan F; Russo, Andrea; Svesko, Andrew; Weller-Davies, Zachary; (2022) Sewing spacetime with Lorentzian threads: complexity and the emergence of time in quantum gravity. Journal of High Energy Physics , 2022 (2) , Article 93. 10.1007/JHEP02(2022)093 <https://doi.org/10.1007/JHEP02%282022%29093>. Green open access document_url: https://discovery.ucl.ac.uk/id/eprint/10151913/1/Svesko_Sewing%20spacetime%20with%20Lorentzian%20threads.%20Complexity%20and%20the%20emergence%20of%20time%20in%20quantum%20gravity_VoR.pdf