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Main Author: Nisse, Mounir
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.21116
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author Nisse, Mounir
author_facet Nisse, Mounir
contents The topology of amoebas of complex algebraic hypersurfaces is deeply connected to the combinatorics of the Newton polytope and the convex geometry of the Ronkin function. A long-standing conjecture of Passare and Rullgard asserts that the amoeba of a maximally sparse Laurent polynomial, whose support consists exactly of the vertices of its Newton polytope, must be solid, meaning that the complement of the amoeba has precisely as many connected components as the number of vertices of the Newton polytope. In this paper we prove this conjecture. The proof is based on a detailed analysis of the stability of the linearity domains of the Ronkin function under tropical degenerations of Laurent polynomials. We show that in the maximally sparse case no new slopes corresponding to interior lattice points can appear, forcing the amoeba complement to have the minimal possible topology. In addition, we establish stability results for the spines of degenerating amoebas, prove that the associated Newton subdivision stabilizes and coincides with the tropical subdivision for sufficiently small parameters, and derive geometric criteria controlling the appearance of lattice points in the dual subdivision. These results lead to a classification of three distinct regimes governing the topology of amoeba complements according to the position of the support relative to the Newton polytope.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Solid Amoebas of Maximally Sparse Polynomials
Nisse, Mounir
Algebraic Geometry
14H50, 14T05, 30F15
The topology of amoebas of complex algebraic hypersurfaces is deeply connected to the combinatorics of the Newton polytope and the convex geometry of the Ronkin function. A long-standing conjecture of Passare and Rullgard asserts that the amoeba of a maximally sparse Laurent polynomial, whose support consists exactly of the vertices of its Newton polytope, must be solid, meaning that the complement of the amoeba has precisely as many connected components as the number of vertices of the Newton polytope. In this paper we prove this conjecture. The proof is based on a detailed analysis of the stability of the linearity domains of the Ronkin function under tropical degenerations of Laurent polynomials. We show that in the maximally sparse case no new slopes corresponding to interior lattice points can appear, forcing the amoeba complement to have the minimal possible topology. In addition, we establish stability results for the spines of degenerating amoebas, prove that the associated Newton subdivision stabilizes and coincides with the tropical subdivision for sufficiently small parameters, and derive geometric criteria controlling the appearance of lattice points in the dual subdivision. These results lead to a classification of three distinct regimes governing the topology of amoeba complements according to the position of the support relative to the Newton polytope.
title Solid Amoebas of Maximally Sparse Polynomials
topic Algebraic Geometry
14H50, 14T05, 30F15
url https://arxiv.org/abs/2603.21116