Confining solitons in the Higgs phase of CPN −1 model: self-consistent exact solutions in large-N limit

Muneto Nitta; Ryosuke Yoshii

doi:10.1007/JHEP08(2018)007

Confining solitons in the Higgs phase of CP^{N −1} model: self-consistent exact solutions in large-N limit

Muneto Nitta, Ryosuke Yoshii

Faculty of Business and Commerce

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

The quantum CP^{N −1} model is in the confining (or unbroken) phase with a full mass gap in an infinite space, while it is in the Higgs (broken or deconfinement) phase accompanied with Nambu-Goldstone modes in a finite space such as a ring or finite interval smaller than a certain critical size. We find a new self-consistent exact solution describing a soliton in the Higgs phase of the CP^{N −1} model in the large-N limit on a ring. We call it a confining soliton. We show that all eigenmodes have real and positive energy and thus it is stable.

Original language	English
Article number	7
Journal	Journal of High Energy Physics
Volume	2018
Issue number	8
DOIs	https://doi.org/10.1007/JHEP08(2018)007
Publication status	Published - 2018 Aug 1

Keywords

1/N Expansion
Field Theories in Lower Dimensions
Sigma Models
Solitons Monopoles and Instantons

ASJC Scopus subject areas

Nuclear and High Energy Physics

Access to Document

10.1007/JHEP08(2018)007

Cite this

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title = "Confining solitons in the Higgs phase of CPN −1 model: self-consistent exact solutions in large-N limit",

abstract = "The quantum CPN −1 model is in the confining (or unbroken) phase with a full mass gap in an infinite space, while it is in the Higgs (broken or deconfinement) phase accompanied with Nambu-Goldstone modes in a finite space such as a ring or finite interval smaller than a certain critical size. We find a new self-consistent exact solution describing a soliton in the Higgs phase of the CPN −1 model in the large-N limit on a ring. We call it a confining soliton. We show that all eigenmodes have real and positive energy and thus it is stable.",

keywords = "1/N Expansion, Field Theories in Lower Dimensions, Sigma Models, Solitons Monopoles and Instantons",

author = "Muneto Nitta and Ryosuke Yoshii",

note = "Funding Information: Article funded by SCOAP3. Publisher Copyright: {\textcopyright} 2018, The Author(s).",

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AU - Yoshii, Ryosuke

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N2 - The quantum CPN −1 model is in the confining (or unbroken) phase with a full mass gap in an infinite space, while it is in the Higgs (broken or deconfinement) phase accompanied with Nambu-Goldstone modes in a finite space such as a ring or finite interval smaller than a certain critical size. We find a new self-consistent exact solution describing a soliton in the Higgs phase of the CPN −1 model in the large-N limit on a ring. We call it a confining soliton. We show that all eigenmodes have real and positive energy and thus it is stable.

AB - The quantum CPN −1 model is in the confining (or unbroken) phase with a full mass gap in an infinite space, while it is in the Higgs (broken or deconfinement) phase accompanied with Nambu-Goldstone modes in a finite space such as a ring or finite interval smaller than a certain critical size. We find a new self-consistent exact solution describing a soliton in the Higgs phase of the CPN −1 model in the large-N limit on a ring. We call it a confining soliton. We show that all eigenmodes have real and positive energy and thus it is stable.

KW - 1/N Expansion

KW - Field Theories in Lower Dimensions

KW - Sigma Models

KW - Solitons Monopoles and Instantons

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