NoBLE for Lattice Trees and Lattice Animals

Robert Fitzner; Remco van der Hofstad

doi:10.1007/s10955-021-02816-z

NoBLE for Lattice Trees and Lattice Animals

Robert Fitzner, Remco van der Hofstad (Corresponding author)

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We study lattice trees (LTs) and animals (LAs) on the nearest-neighbor lattice Z^d in high dimensions. We prove that LTs and LAs display mean-field behavior above dimension 16 and 17 , respectively. Such results have previously been obtained by Hara and Slade in sufficiently high dimensions. The dimension above which their results apply was not yet specified. We rely on the non-backtracking lace expansion (NoBLE) method that we have recently developed. The NoBLE makes use of an alternative lace expansion for LAs and LTs that perturbs around non-backtracking random walk rather than around simple random walk, leading to smaller corrections. The NoBLE method then provides a careful computational analysis that improves the dimension above which the result applies. Universality arguments predict that the upper critical dimension, above which our results apply, is equal to d_c= 8 for both models, as is known for sufficiently spread-out models by the results of Hara and Slade mentioned earlier. The main ingredients in this paper are (a) a derivation of a non-backtracking lace expansion for the LT and LA two-point functions; (b) bounds on the non-backtracking lace-expansion coefficients, thus showing that our general NoBLE methodology can be applied; and (c) sharp numerical bounds on the coefficients. Our proof is complemented by a computer-assisted numerical analysis that verifies that the necessary bounds used in the NoBLE are satisfied.

Originele taal-2	Engels
Artikelnummer	13
Aantal pagina's	87
Tijdschrift	Journal of Statistical Physics
Volume	185
Nummer van het tijdschrift	2
DOI's	https://doi.org/10.1007/s10955-021-02816-z
Status	Gepubliceerd - nov. 2021

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Publisher Copyright:
© 2021, The Author(s).

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This work was supported in part by the Netherlands Organisation for Scientific Research (NWO) through VICI Grant 639.033.806 and the Gravitation Networks Grant 024.002.003. We thank David Brydges, Takashi Hara and Gordon Slade for their constant encouragement, as well as for several stimulating discussions. This work builds upon the work by Takashi Hara and Gordon Slade, originally used for self-avoiding walk and percolation. We are indebted to Takashi for his help in the proof of Theorem , which relies on an improved version of this analysis in [] that Takashi shared with us in 2015. Early 2019, Takashi significantly helped us once more by clarifying the requirements for [] to apply for LTs and LAs (see Sect. ). The work of RF was partially performed while being employed by the Institute for Complex Molecular Systems at Eindhoven University of Technology. This work was supported in part by the Netherlands Organisation for Scientific Research (NWO) through VICI Grant 639.033.806 and the Gravitation Networks Grant 024.002.003. We thank David Brydges, Takashi Hara and Gordon Slade for their constant encouragement, as well as for several stimulating discussions. This work builds upon the work by Takashi Hara and Gordon Slade, originally used for self-avoiding walk and percolation. We are indebted to Takashi for his help in the proof of Theorem 1.5 , which relies on an improved version of this analysis in [15] that Takashi shared with us in 2015. Early 2019, Takashi significantly helped us once more by clarifying the requirements for [15] to apply for LTs and LAs (see Sect. 7.3). The work of RF was partially performed while being employed by the Institute for Complex Molecular Systems at Eindhoven University of Technology.

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Correction to: NoBLE for Lattice Trees and Lattice Animals (Journal of Statistical Physics, (2021), 185, 2, (13), 10.1007/s10955-021-02816-z)
Fitzner, R. & van der Hofstad, R. (Corresponding author), feb. 2022, In: Journal of Statistical Physics. 186, 2, 2 blz., 26.
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title = "NoBLE for Lattice Trees and Lattice Animals",

abstract = "We study lattice trees (LTs) and animals (LAs) on the nearest-neighbor lattice Zd in high dimensions. We prove that LTs and LAs display mean-field behavior above dimension 16 and 17 , respectively. Such results have previously been obtained by Hara and Slade in sufficiently high dimensions. The dimension above which their results apply was not yet specified. We rely on the non-backtracking lace expansion (NoBLE) method that we have recently developed. The NoBLE makes use of an alternative lace expansion for LAs and LTs that perturbs around non-backtracking random walk rather than around simple random walk, leading to smaller corrections. The NoBLE method then provides a careful computational analysis that improves the dimension above which the result applies. Universality arguments predict that the upper critical dimension, above which our results apply, is equal to dc= 8 for both models, as is known for sufficiently spread-out models by the results of Hara and Slade mentioned earlier. The main ingredients in this paper are (a) a derivation of a non-backtracking lace expansion for the LT and LA two-point functions; (b) bounds on the non-backtracking lace-expansion coefficients, thus showing that our general NoBLE methodology can be applied; and (c) sharp numerical bounds on the coefficients. Our proof is complemented by a computer-assisted numerical analysis that verifies that the necessary bounds used in the NoBLE are satisfied.",

keywords = "Critical exponents, High-dimensional statistical physics, Lace expansion, Lattice animals, Lattices trees, Mean-field behaviour, NoBLE",

author = "Robert Fitzner and \{van der Hofstad\}, Remco",

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N2 - We study lattice trees (LTs) and animals (LAs) on the nearest-neighbor lattice Zd in high dimensions. We prove that LTs and LAs display mean-field behavior above dimension 16 and 17 , respectively. Such results have previously been obtained by Hara and Slade in sufficiently high dimensions. The dimension above which their results apply was not yet specified. We rely on the non-backtracking lace expansion (NoBLE) method that we have recently developed. The NoBLE makes use of an alternative lace expansion for LAs and LTs that perturbs around non-backtracking random walk rather than around simple random walk, leading to smaller corrections. The NoBLE method then provides a careful computational analysis that improves the dimension above which the result applies. Universality arguments predict that the upper critical dimension, above which our results apply, is equal to dc= 8 for both models, as is known for sufficiently spread-out models by the results of Hara and Slade mentioned earlier. The main ingredients in this paper are (a) a derivation of a non-backtracking lace expansion for the LT and LA two-point functions; (b) bounds on the non-backtracking lace-expansion coefficients, thus showing that our general NoBLE methodology can be applied; and (c) sharp numerical bounds on the coefficients. Our proof is complemented by a computer-assisted numerical analysis that verifies that the necessary bounds used in the NoBLE are satisfied.

AB - We study lattice trees (LTs) and animals (LAs) on the nearest-neighbor lattice Zd in high dimensions. We prove that LTs and LAs display mean-field behavior above dimension 16 and 17 , respectively. Such results have previously been obtained by Hara and Slade in sufficiently high dimensions. The dimension above which their results apply was not yet specified. We rely on the non-backtracking lace expansion (NoBLE) method that we have recently developed. The NoBLE makes use of an alternative lace expansion for LAs and LTs that perturbs around non-backtracking random walk rather than around simple random walk, leading to smaller corrections. The NoBLE method then provides a careful computational analysis that improves the dimension above which the result applies. Universality arguments predict that the upper critical dimension, above which our results apply, is equal to dc= 8 for both models, as is known for sufficiently spread-out models by the results of Hara and Slade mentioned earlier. The main ingredients in this paper are (a) a derivation of a non-backtracking lace expansion for the LT and LA two-point functions; (b) bounds on the non-backtracking lace-expansion coefficients, thus showing that our general NoBLE methodology can be applied; and (c) sharp numerical bounds on the coefficients. Our proof is complemented by a computer-assisted numerical analysis that verifies that the necessary bounds used in the NoBLE are satisfied.

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SN - 0022-4715

VL - 185

JO - Journal of Statistical Physics

JF - Journal of Statistical Physics

IS - 2

M1 - 13

ER -

NoBLE for Lattice Trees and Lattice Animals

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Bibliografische nota

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Correction to: NoBLE for Lattice Trees and Lattice Animals (Journal of Statistical Physics, (2021), 185, 2, (13), 10.1007/s10955-021-02816-z)

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