1313010.1007/13130.1029-8479Journal of High Energy PhysicsJ. High Energ. Phys.1029-8479Springer Berlin HeidelbergBerlin/HeidelbergJHEP02(2023)021201112210.0290710.1007/JHEP02(2023)021Regular Article - Theoretical PhysicsParity violation in the scalar trispectrum: no-go theorems and yes-go examplesCabassGiovanni1aJazayeriSadra2PajerEnrico3StefanyszynDavid45grid.78989.370000 0001 2160 7918School of Natural Sciences, Institute for Advanced Study08540PrincetonNJUnited Statesgrid.462844.80000 0001 2308 1657Institut d’Astrophysique de ParisGReCO, UMR 7095 du CNRS et de Sorbonne Université98bis boulevard Arago75014ParisFrancegrid.5335.00000000121885934Department of Applied Mathematics and Theoretical PhysicsUniversity of CambridgeWilberforce RoadCB3 0WACambridgeU.K.grid.4563.40000 0004 1936 8868Nottingham Centre of GravityUniversity of NottinghamUniversity ParkNG7 2RDNottinghamU.K.grid.4563.40000 0004 1936 8868School of Mathematical Sciences & School of Physics and AstronomyUniversity of NottinghamUniversity ParkNG7 2RDNottinghamU.K.gcabass@ias.edu222023220232023221222023161020221412023222023© The Author(s) 20232023Open 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.A<sc>bstract</sc>

We derive a set of no-go theorems and yes-go examples for the parity-odd primordial trispectrum of curvature perturbations. We work at tree-level in the decoupling limit of the Effective Field Theory of Inflation and assume scale invariance and a Bunch-Davies vacuum. We show that the parity-odd scalar trispectrum vanishes in the presence of any number of scalar fields with arbitrary mass and any parity-odd scalar correlator vanishes in the presence of any number of spinning fields with massless de Sitter mode functions, in agreement with the findings of Liu, Tong, Wang and Xianyu [1]. The same is true for correlators with an odd number of conformally-coupled external fields. We derive these results using both the (boostless) cosmological bootstrap, in particular the Cosmological Optical Theorem, and explicit perturbative calculations. We then discuss a series of yes-go examples by relaxing the above assumptions one at the time. In particular, we provide explicit results for the parity-odd trispectrum for (i) violations of scale invariance in single-clock inflation, (ii) the modified dispersion relation of the ghost condensate (non-Bunch-Davies vacuum), and (iii) interactions with massive spinning fields. Our results establish the parity-odd trispectrum as an exceptionally sensitive probe of new physics beyond vanilla inflation.

K<sc>eywords</sc>Early Universe Particle PhysicsEffective Field TheoriesSpace-Time Symmetriespublisher-imprint-nameSpringervolume-issue-count12issue-article-count258issue-toc-levels0issue-pricelist-year2023issue-copyright-holderThe Author(s)issue-copyright-year2021article-contains-esmNoarticle-numbering-styleContentOnlyarticle-registration-date-year2023article-registration-date-month2article-registration-date-day2article-toc-levels0toc-levels0volume-typeRegularjournal-productArchiveJournalnumbering-styleUnnumberedarticle-grants-typeOpenChoicemetadata-grantOpenAccessabstract-grantOpenAccessbodypdf-grantOpenAccessbodyhtml-grantOpenAccessbibliography-grantOpenAccessesm-grantOpenAccessonline-firstfalsepdf-file-referenceBodyRef/PDF/13130_2023_Article_20111.pdfpdf-typeTypesettarget-typeOnlinePDFissue-typeRegulararticle-typeOriginalPaperjournal-subject-primaryPhysicsjournal-subject-secondaryElementary Particles, Quantum Field Theoryjournal-subject-secondaryQuantum Field Theories, String Theoryjournal-subject-secondaryClassical and Quantum Gravitation, Relativity Theoryjournal-subject-secondaryQuantum Physicsjournal-subject-collectionPhysics and Astronomyopen-accesstrue

ArXiv ePrint: 2210.02907

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