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Structure and Complexity of Cosmological Correlators (2404.03716v1)

Published 4 Apr 2024 in hep-th and hep-ph

Abstract: Cosmological correlators capture the spatial fluctuations imprinted during the earliest episodes of the universe. While they are generally very non-trivial functions of the kinematic variables, they are known to arise as solutions to special sets of differential equations. In this work we use this fact to uncover the underlying tame structure for such correlators and argue that they admit a well-defined notion of complexity. In particular, building upon the recently proposed kinematic flow algorithm, we show that tree-level cosmological correlators of a generic scalar field theory in an FLRW spacetime belong to the class of Pfaffian functions. Since Pfaffian functions admit a notion of complexity, we can give explicit bounds on the topological and computational complexity of cosmological correlators. We conclude with some speculative comments on the general tame structures capturing all cosmological correlators and the connection between complexity and the emergence of time.

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References (38)
  1. A. H. Guth, Inflationary universe: A possible solution to the horizon and flatness problems, Physical Review D 23, 347 (1981).
  2. A. H. Guth and S.-Y. Pi, Fluctuations in the New Inflationary Universe, Physical Review Letters 49, 1110 (1982).
  3. A. A. Starobinsky, Dynamics of phase transition in the new inflationary universe scenario and generation of perturbations, Physics Letters B 117, 175 (1982).
  4. J. M. Bardeen, P. J. Steinhardt, and M. S. Turner, Spontaneous creation of almost scale-free density perturbations in an inflationary universe, Physical Review D 28, 679 (1983).
  5. D. N. Spergel and M. Zaldarriaga, CMB polarization as a direct test of Inflation, Physical Review Letters 79, 2180 (1997), arxiv:astro-ph/9705182 .
  6. W. Hu, D. N. Spergel, and M. White, Distinguishing Causal Seeds from Inflation, Physical Review D 55, 3288 (1997), arxiv:astro-ph/9605193 .
  7. S. Dodelson, Coherent Phase Argument for Inflation, in AIP Conference Proceedings, Vol. 689 (2003) pp. 184–196, arxiv:hep-ph/0309057 .
  8. P. McFadden and K. Skenderis, Holography for Cosmology, Physical Review D 81, 021301 (2010), arxiv:0907.5542 [hep-th] .
  9. I. Mata, S. Raju, and S. Trivedi, CMB from CFT, Journal of High Energy Physics 07, 015 (2013), arxiv:1211.5482 [hep-th] .
  10. N. Arkani-Hamed and J. Maldacena, Cosmological Collider Physics,   (2015), arxiv:1503.08043 [hep-th] .
  11. A. Achúcarro et al., Inflation: Theory and Observations,   (2022), arxiv:2203.08128 [astro-ph.CO] .
  12. P. Benincasa, From the flat-space S-matrix to the Wavefunction of the Universe,   (2018), arxiv:1811.02515 [hep-th] .
  13. P. Benincasa, Cosmological Polytopes and the Wavefuncton of the Universe for Light States,   (2019), arxiv:1909.02517 [hep-th] .
  14. S. Jazayeri, E. Pajer, and D. Stefanyszyn, From Locality and Unitarity to Cosmological Correlators, Journal of High Energy Physics 10, 065 (2021), arxiv:2103.08649 [hep-th] .
  15. H. Goodhew, S. Jazayeri, and E. Pajer, The Cosmological Optical Theorem, Journal of Cosmology and Astroparticle Physics 04 (04), 021, arxiv:2009.02898 [hep-th] .
  16. L. Di Pietro, V. Gorbenko, and S. Komatsu, Analyticity and Unitarity for Cosmological Correlators, Journal of High Energy Physics 03, 023 (2022), arxiv:2108.01695 [hep-th] .
  17. S. De and A. Pokraka, Cosmology meets cohomology,  03, 156 (2024), arxiv:2308.03753 [hep-th] .
  18. J. Maldacena, Non-Gaussian features of primordial fluctuations in single field inflationary models, Journal of High Energy Physics 05, 013 (2003), arxiv:astro-ph/0210603 .
  19. C. Sleight, A Mellin Space Approach to Cosmological Correlators, Journal of High Energy Physics 01, 090 (2020), arxiv:1906.12302 [hep-th] .
  20. P. Benincasa, Amplitudes meet Cosmology: A (Scalar) Primer, International Journal of Modern Physics A 37, 2230010 (2022), arxiv:2203.15330 [hep-th] .
  21. D.-G. Wang, G. L. Pimentel, and A. Achúcarro, Bootstrapping Multi-Field Inflation: Non-Gaussianities from light scalars revisited, Journal of Cosmology and Astroparticle Physics 05 (05), 043, arxiv:2212.14035 [astro-ph.CO] .
  22. G. Binyamini and D. Novikov, Tameness in geometry and arithmetic: beyond o-minimality, EMS Press  (2022).
  23. G. Binyamini, D. Novikov, and B. Zack, Sharply o-minimal structures and sharp cellular decomposition,   (2022), arXiv:2209.10972 [math.LO] .
  24. C. Sleight and M. Taronna, Bootstrapping Inflationary Correlators in Mellin Space, Journal of High Energy Physics 02, 098 (2020), arxiv:1907.01143 [hep-th] .
  25. E. Pajer, Building a Boostless Bootstrap for the Bispectrum, Journal of Cosmology and Astroparticle Physics 01 (01), 023, arxiv:2010.12818 [hep-th] .
  26. T. W. Grimm, L. Schlechter, and M. van Vliet, Complexity in Tame Quantum Theories,   (2023), arXiv:2310.01484 [hep-th] .
  27. G. Binyamini and D. Novikov, Tameness in geometry and arithmetic: Beyond o-minimality (2023) pp. 1440–1461.
  28. By a slight abuse of language, we will also use the term wavefunction coefficient to refer to the contribution from a single Feynman graph.
  29. T. W. Grimm, Taming the landscape of effective theories, JHEP 11, 003, arXiv:2112.08383 [hep-th] .
  30. N. Arkani-Hamed, P. Benincasa, and A. Postnikov, Cosmological Polytopes and the Wavefunction of the Universe,   (2017), arxiv:1709.02813 [hep-th] .
  31. F. Caloro and P. McFadden, A-hypergeometric functions and creation operators for Feynman and Witten diagrams,   (2023), arXiv:2309.15895 [hep-th] .
  32. M. H. G. Lee, From amplitudes to analytic wavefunctions, Journal of High Energy Physics 03, 058 (2024), arxiv:2310.01525 [hep-th] .
  33. B. Fan and Z.-Z. Xianyu, Cosmological Amplitudes in Power-Law FRW Universe,   (2024), arxiv:2403.07050 [hep-th] .
  34. T. W. Grimm and A. Hoefnagels, Reducing Differential Equations for Cosmological Correlators and Feynman Integrals, to appear  (2024).
  35. L. Susskind, Computational Complexity and Black Hole Horizons, Fortsch. Phys. 64, 24 (2016), [Addendum: Fortsch.Phys. 64, 44–48 (2016)], arXiv:1403.5695 [hep-th] .
  36. L. Susskind, Three Lectures on Complexity and Black Holes (Springer, 2018) arXiv:1810.11563 [hep-th] .
  37. T. W. Grimm, A. Hoefnagels, and M. van Vliet, in progress  (2024).
  38. .
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