@article{10765,
  abstract     = {We establish the Hardy-Littlewood property (à la Borovoi-Rudnick) for Zariski open subsets in affine quadrics of the form q(x1,...,xn)=m, where q is a non-degenerate integral quadratic form in  n>3 variables and m is a non-zero integer. This gives asymptotic formulas for the density of integral points taking coprime polynomial values, which is a quantitative version of the arithmetic purity of strong approximation property off infinity for affine quadrics.},
  author       = {Cao, Yang and Huang, Zhizhong},
  issn         = {1090-2082},
  journal      = {Advances in Mathematics},
  number       = {3},
  publisher    = {Elsevier},
  title        = {{Arithmetic purity of the Hardy-Littlewood property and geometric sieve for affine quadrics}},
  doi          = {10.1016/j.aim.2022.108236},
  volume       = {398},
  year         = {2022},
}

@article{11717,
  abstract     = {We study rigidity of rational maps that come from Newton's root finding method for polynomials of arbitrary degrees. We establish dynamical rigidity of these maps: each point in the Julia set of a Newton map is either rigid (i.e. its orbit can be distinguished in combinatorial terms from all other orbits), or the orbit of this point eventually lands in the filled-in Julia set of a polynomial-like restriction of the original map. As a corollary, we show that the Julia sets of Newton maps in many non-trivial cases are locally connected; in particular, every cubic Newton map without Siegel points has locally connected Julia set.
In the parameter space of Newton maps of arbitrary degree we obtain the following rigidity result: any two combinatorially equivalent Newton maps are quasiconformally conjugate in a neighborhood of their Julia sets provided that they either non-renormalizable, or they are both renormalizable “in the same way”.
Our main tool is a generalized renormalization concept called “complex box mappings” for which we extend a dynamical rigidity result by Kozlovski and van Strien so as to include irrationally indifferent and renormalizable situations.},
  author       = {Drach, Kostiantyn and Schleicher, Dierk},
  issn         = {0001-8708},
  journal      = {Advances in Mathematics},
  keywords     = {General Mathematics},
  number       = {Part A},
  publisher    = {Elsevier},
  title        = {{Rigidity of Newton dynamics}},
  doi          = {10.1016/j.aim.2022.108591},
  volume       = {408},
  year         = {2022},
}

@article{9036,
  abstract     = {In this short note, we prove that the square root of the quantum Jensen-Shannon divergence is a true metric on the cone of positive matrices, and hence in particular on the quantum state space.},
  author       = {Virosztek, Daniel},
  issn         = {0001-8708},
  journal      = {Advances in Mathematics},
  keywords     = {General Mathematics},
  number       = {3},
  publisher    = {Elsevier},
  title        = {{The metric property of the quantum Jensen-Shannon divergence}},
  doi          = {10.1016/j.aim.2021.107595},
  volume       = {380},
  year         = {2021},
}

@article{10033,
  abstract     = {The ⊗*-monoidal structure on the category of sheaves on the Ran space is not pro-nilpotent in the sense of [3]. However, under some connectivity assumptions, we prove that Koszul duality induces an equivalence of categories and that this equivalence behaves nicely with respect to Verdier duality on the Ran space and integrating along the Ran space, i.e. taking factorization homology. Based on ideas sketched in [4], we show that these results also offer a simpler alternative to one of the two main steps in the proof of the Atiyah-Bott formula given in [7] and [5].},
  author       = {Ho, Quoc P},
  issn         = {1090-2082},
  journal      = {Advances in Mathematics},
  keywords     = {Chiral algebras, Chiral homology, Factorization algebras, Koszul duality, Ran space},
  publisher    = {Elsevier},
  title        = {{The Atiyah-Bott formula and connectivity in chiral Koszul duality}},
  doi          = {10.1016/j.aim.2021.107992},
  volume       = {392},
  year         = {2021},
}

@article{9588,
  abstract     = {Consider the sum  X(ξ)=∑ni=1aiξi , where  a=(ai)ni=1  is a sequence of non-zero reals and  ξ=(ξi)ni=1  is a sequence of i.i.d. Rademacher random variables (that is,  Pr[ξi=1]=Pr[ξi=−1]=1/2 ). The classical Littlewood-Offord problem asks for the best possible upper bound on the concentration probabilities  Pr[X=x] . In this paper we study a resilience version of the Littlewood-Offord problem: how many of the  ξi  is an adversary typically allowed to change without being able to force concentration on a particular value? We solve this problem asymptotically, and present a few interesting open problems.},
  author       = {Bandeira, Afonso S. and Ferber, Asaf and Kwan, Matthew Alan},
  issn         = {0001-8708},
  journal      = {Advances in Mathematics},
  pages        = {292--312},
  publisher    = {Elsevier},
  title        = {{Resilience for the Littlewood–Offord problem}},
  doi          = {10.1016/j.aim.2017.08.031},
  volume       = {319},
  year         = {2017},
}

@article{8511,
  abstract     = {Here we study an amazing phenomenon discovered by Newhouse [S. Newhouse, Non-density of Axiom A(a) on S2, in: Proc. Sympos. Pure Math., vol. 14, Amer. Math. Soc., 1970, pp. 191–202; S. Newhouse,
Diffeomorphisms with infinitely many sinks, Topology 13 (1974) 9–18; S. Newhouse, The abundance of
wild hyperbolic sets and nonsmooth stable sets of diffeomorphisms, Publ. Math. Inst. Hautes Études Sci.
50 (1979) 101–151]. It turns out that in the space of Cr smooth diffeomorphisms Diffr(M) of a compact
surface M there is an open set U such that a Baire generic diffeomorphism f ∈ U has infinitely many coexisting sinks. In this paper we make a step towards understanding “how often does a surface diffeomorphism
have infinitely many sinks.” Our main result roughly says that with probability one for any positive D a
surface diffeomorphism has only finitely many localized sinks either of cyclicity bounded by D or those
whose period is relatively large compared to its cyclicity. It verifies a particular case of Palis’ Conjecture
saying that even though diffeomorphisms with infinitely many coexisting sinks are Baire generic, they have
probability zero.
One of the key points of the proof is an application of Newton Interpolation Polynomials to study the dynamics initiated in [V. Kaloshin, B. Hunt, A stretched exponential bound on the rate of growth of the number
of periodic points for prevalent diffeomorphisms I, Ann. of Math., in press, 92 pp.; V. Kaloshin, A stretched
exponential bound on the rate of growth of the number of periodic points for prevalent diffeomorphisms II,
preprint, 85 pp.].},
  author       = {Gorodetski, A. and Kaloshin, Vadim},
  issn         = {0001-8708},
  journal      = {Advances in Mathematics},
  keywords     = {General Mathematics},
  number       = {2},
  pages        = {710--797},
  publisher    = {Elsevier},
  title        = {{How often surface diffeomorphisms have infinitely many sinks and hyperbolicity of periodic points near a homoclinic tangency}},
  doi          = {10.1016/j.aim.2006.03.012},
  volume       = {208},
  year         = {2007},
}