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The link between hyperuniformity, Coulomb energy, and Wasserstein distance to Lebesgue for two-dimensional point processes

Published 29 Apr 2024 in math.PR | (2404.18588v1)

Abstract: We investigate the interplay between three possible properties of stationary point processes: i) Finite Coulomb energy with short-scale regularization, ii) Finite $2$-Wasserstein transportation distance to the Lebesgue measure and iii) Hyperuniformity. In dimension $2$, we prove that i) implies ii), which is known to imply iii), and we provide simple counter-examples to both converse implications. However, we prove that ii) implies i) for processes with a uniformly bounded density of points, and that i) - finiteness of the regularized Coulomb energy - is equivalent to a certain property of quantitative hyperuniformity that is just slightly stronger than hyperuniformity itself. Our proof relies on the classical link between $H{-1}$-norm and $2$-Wasserstein distance between measures, on the screening construction for Coulomb gases (of which we present an adaptation to $2$-Wasserstein space which might be of independent interest), and on recent necessary and sufficient conditions for the existence of stationary "electric" fields compatible with a given stationary point process.

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References (34)
  1. On optimal matchings. Combinatorica, 4:259–264, 1984.
  2. Local laws and rigidity for Coulomb gases at any temperature. The Annals of Probability, 49(1):46–121, 2021.
  3. A computational fluid mechanics solution to the Monge-Kantorovich mass transfer problem. Numerische Mathematik, 84(3):375–393, 2000.
  4. On the Wasserstein distance between a hyperuniform point process and its mean. https://arxiv.org/pdf/2404.09549.pdf, 04 2024.
  5. Renormalized energy concentration in random matrices. Communications in Mathematical Physics, 320:199–244, 2013.
  6. Simon Coste. Order, fluctuations, rigidities. https://scoste.fr/assets/survey_hyperuniformity.pdf, 2021.
  7. (non)-hyperuniformity of perturbed lattices. (in preparation), 2024.
  8. Optimal transport of stationary point processes: Metric structure, gradient flow and convexity of the specific entropy. arXiv preprint arXiv:2304.11145, 2023.
  9. An Invitation to Optimal Transport, Wasserstein Distances, and Gradient Flows: Second Edition. EMS Press, May 2023.
  10. Andrea Gabrielli. Point processes and stochastic displacement fields. Physical Review E, 70(6):066131, 2004.
  11. Quantitative linearization results for the Monge-Ampère equation. Commun. Pure Appl. Math., 74(12):2483–2560, 2021.
  12. Jean Ginibre. Statistical ensembles of complex, quaternion, and real matrices. Journal of Mathematical Physics, 6(3):440–449, 1965.
  13. Glass-like universe: Real-space correlation properties of standard cosmological models. Physical Review D, 65(8):083523, 2002.
  14. A variational proof of partial regularity for optimal transportation maps. Annales scientifiques de l’École Normale supérieure, 53(5):1209–1233, 2020.
  15. On a problem of Cox concerning point processes in ℝksuperscriptℝ𝑘\mathbb{R}^{k}blackboard_R start_POSTSUPERSCRIPT italic_k end_POSTSUPERSCRIPT of “controlled variability”. The Annals of Probability, 3(4):597–607, 1975.
  16. There is no stationary cyclically monotone Poisson matching in 2d. Probability Theory and Related Fields, 187(3):629–656, 2023.
  17. Optimal transport from Lebesgue to Poisson. Ann. Probab., 41(4):2426–2478, 2013.
  18. Thomas Leblé. Logarithmic, Coulomb and Riesz energy of point processes. Journal of Statistical Physics, 162:887–923, 2016.
  19. Thomas Leblé. The two-dimensional one-component plasma is hyperuniform. arXiv preprint arXiv:2104.05109, 2021.
  20. Michel Ledoux. On optimal matching of Gaussian samples. Journal of Mathematical Sciences, 238(4):495–522, March 2019.
  21. Analysis, volume 14. American Mathematical Soc., 2001.
  22. Grégoire Loeper. Uniqueness of the solution to the Vlasov–Poisson system with bounded density. Journal de mathématiques pures et appliquées, 86(1):68–79, 2006.
  23. Raphaël Lachièze-Rey and D Yogeshwaran. Hyperuniformity and optimal transport of point processes. arXiv preprint arXiv:2402.13705, 2024.
  24. Large deviation principle for empirical fields of Log and Riesz gases. Inventiones mathematicae, 210:645–757, 2017.
  25. Lars Onsager. Electrostatic interaction of molecules. Journal of Physical Chemistry, 43(2):189–196, 1939.
  26. Next order asymptotics and renormalized energy for Riesz interactions. Journal of the Institute of Mathematics of Jussieu, 16(3):501–569, 2017.
  27. Higher-dimensional Coulomb gases and renormalized energy functionals. Communications on Pure and Applied Mathematics, 69(3):519–605, 2016.
  28. Filippo Santambrogio. Optimal transport for applied mathematicians. Calculus of variations, PDEs, and modeling, volume 87 of Prog. Nonlinear Differ. Equ. Appl. Cham: Birkhäuser/Springer, 2015.
  29. From the Ginzburg-Landau model to vortex lattice problems. Communications in Mathematical Physics, 313:635–743, 2012.
  30. 2D Coulomb gases and the renormalized energy. The Annals of Probability, 43(4), 2015.
  31. The random Weierstrass Zeta function i: Existence, uniqueness, fluctuations. Journal of Statistical Physics, 190(10):166, 2023.
  32. Salvatore Torquato. Hyperuniform states of matter. Physics Reports, 745:1–95, 2018.
  33. Local density fluctuations, hyperuniformity, and order metrics. Physical Review E, 68(4):041113, 2003.
  34. Cédric Villani. Optimal transport. Old and new, volume 338 of Grundlehren Math. Wiss. Berlin: Springer, 2009.

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Authors (2)

  1. Martin Huesmann 
  2. Thomas Leblé 

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