# Finite Gap Conditions and Small Dispersion Asymptotics for the Classical   Periodic Benjamin-Ono Equation

**Authors:** Alexander Moll

arXiv: 1901.04089 · 2020-01-01

## TL;DR

This paper characterizes the Nazarov-Sklyanin hierarchy for the periodic Benjamin-Ono equation, linking it to spectral theory, and analyzes the small dispersion limit revealing a concentration on a convex profile related to conserved quantities.

## Contribution

It introduces a dispersive action profile framework using spectral shift functions and characterizes multi-phase solutions and small dispersion limits for the Benjamin-Ono equation.

## Key findings

- Dispersive action profiles have finitely-many gaps for multi-phase data.
- In the small dispersion limit, profiles concentrate on a convex shape encoding conserved quantities.
- Identifies specific profiles for sinusoidal initial data and their limits.

## Abstract

In this paper we characterize the Nazarov-Sklyanin hierarchy for the classical periodic Benjamin-Ono equation in two complementary degenerations: for the multi-phase initial data (the periodic multi-solitons) at fixed dispersion and for bounded initial data in the limit of small dispersion. First, we express this hierarchy in terms of a piecewise-linear function of an auxiliary real variable which we call a dispersive action profile and whose regions of slope $\pm 1$ we call gaps and bands, respectively. Our expression uses Kerov's theory of profiles and Kre\u{\i}n's spectral shift functions. Next, for multi-phase initial data, we identify Baker-Akhiezer functions in Dobrokhotov-Krichever and Nazarov-Sklyanin and prove that multi-phase dispersive action profiles have finitely-many gaps determined by the singularities of their Dobrokhotov-Krichever spectral curves. Finally, for bounded initial data independent of the coefficient of dispersion, we show that in the small dispersion limit, the dispersive action profile concentrates weakly on a convex profile which encodes the conserved quantities of the dispersionless equation. To establish the weak limit, we reformulate Szeg\H{o}'s first theorem for Toeplitz operators using spectral shift functions. To illustrate our results, we identify the dispersive action profile of sinusoidal initial data with a profile found by Nekrasov-Pestun-Shatashvili and its small dispersion limit with the convex profile found by Vershik-Kerov and Logan-Shepp.

## Full text

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## Figures

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## References

76 references — full list in the complete paper: https://tomesphere.com/paper/1901.04089/full.md

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Source: https://tomesphere.com/paper/1901.04089