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Geometry and dynamics on Liouville domains in $T^*\mathbb T^2$

Jun Zhang, Antong Zhu

Abstract

Parallel to the study of toric domains, symplectically convex, and dynamically convex domains in $(\mathbb R^4, ω_{\rm std})$, we build an analogous framework and corresponding subclasses for Liouville domains in $(T^*\mathbb T^2,ω_{\rm can})$. A key feature of this framework is the introduction of a new notion of convexity, based on systolic ratios. Via various machinery in quantitative symplectic geometry, including ECH capacities, shape invariant, dynamical zeta function, etc., we investigate the relations between subclasses of Liouville domains in $T^*\mathbb T^2$, obtain large-scale geometry of Liouville domains in $T^*\mathbb T^2$ with respect to coarse Banach-Mazur distance, provide a non-flat codisc bundle of torus even under the action of exact symplectomorphisms, and verify the agreement of normalized capacities for a wide class of Liouville domains in $T^*\mathbb T^2$.

Geometry and dynamics on Liouville domains in $T^*\mathbb T^2$

Abstract

Parallel to the study of toric domains, symplectically convex, and dynamically convex domains in , we build an analogous framework and corresponding subclasses for Liouville domains in . A key feature of this framework is the introduction of a new notion of convexity, based on systolic ratios. Via various machinery in quantitative symplectic geometry, including ECH capacities, shape invariant, dynamical zeta function, etc., we investigate the relations between subclasses of Liouville domains in , obtain large-scale geometry of Liouville domains in with respect to coarse Banach-Mazur distance, provide a non-flat codisc bundle of torus even under the action of exact symplectomorphisms, and verify the agreement of normalized capacities for a wide class of Liouville domains in .

Paper Structure

This paper contains 13 sections, 18 theorems, 260 equations, 13 figures.

Table of Contents

  1. Introduction
  2. Main results
  3. Distinguish subclasses
  4. Large-scale geometry on $T^*\mathbb T^n$
  5. Normalized capacity in $T^*\mathbb T^n$
  6. Proofs
  7. Preparations
  8. Proof of Theorem \ref{['thm-class']}
  9. Proof of Theorem \ref{['thm-non-flat']}
  10. Proof of Theorem \ref{['thm-large-scale-one']} and Theorem \ref{['thm-large-scale-two']}
  11. Proof of Theorem \ref{['thm-normalized']} and Theorem \ref{['thm-ball-normalized']}
  12. Estimation of systolic ratio
  13. Construction of embedding

Key Result

Theorem A

All containment relations in Figure fig:diagram are strict.

Figures (13)

  • Figure 1: Relations between subclasses of star-shaped domains in $\mathbb{R}^4$.
  • Figure 2: Relation between subclasses of fiberwise star-shaped domains in $T^*\mathbb T^2$. Distinguishing examples (1) - (9) will be provided in the proof of Theorem \ref{['thm-class']} in Section \ref{['sec-thm-A']}.
  • Figure 3: Smoothing triangle $A$ at vertex $(-1, -1)$.
  • Figure 4: Example of (1).
  • Figure 5: Example of (2), and also the example where (3) is built from.
  • ...and 8 more figures

Theorems & Definitions (62)

  • Definition 1.1
  • Example 1.2
  • Remark 1.3
  • Remark 1.4
  • Example 1.5
  • Remark 1.6
  • Remark 1.8
  • Conjecture 1.9
  • Theorem A
  • Theorem B
  • ...and 52 more