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S{sup 1} x S{sup 2} as a bag membrane and its Einstein-Weyl geometry

Abstract

In the hybrid skyrmion in which an anti-de Sitter bag is embedded into the skyrmion configuration a S{sup 1} x S{sup 2} membrane is lying on the compactified spatial infinity of the bag. The connection between the quark degrees of freedom and the mesonic ones is made through the membrane. This 3-dimensional manifold is at the same time Weyl-Einstein space. We present what is known until the present time to people working in the differential geometry of these spaces. (author). 11 refs.
Authors:
Publication Date:
Oct 01, 1992
Product Type:
Technical Report
Report Number:
IC-92/316
Reference Number:
SCA: 662240; 662110; PA: AIX-24:008429; SN: 93000933033
Resource Relation:
Other Information: PBD: Oct 1992
Subject:
72 PHYSICS OF ELEMENTARY PARTICLES AND FIELDS; WEYL UNIFIED THEORY; BAG MODEL; GEODESICS; MATHEMATICAL MANIFOLDS; METRICS; SPACE-TIME; TWISTOR THEORY; 662240; 662110; MODELS FOR STRONG INTERACTIONS; THEORY OF FIELDS AND STRINGS
OSTI ID:
10119613
Research Organizations:
International Centre for Theoretical Physics (ICTP), Trieste (Italy)
Country of Origin:
IAEA
Language:
English
Other Identifying Numbers:
Other: ON: DE93613149; TRN: XA9233100008429
Availability:
OSTI; NTIS (US Sales Only); INIS
Submitting Site:
INIS
Size:
[9] p.
Announcement Date:
Jun 30, 2005

Citation Formats

Rosu, H. S{sup 1} x S{sup 2} as a bag membrane and its Einstein-Weyl geometry. IAEA: N. p., 1992. Web.
Rosu, H. S{sup 1} x S{sup 2} as a bag membrane and its Einstein-Weyl geometry. IAEA.
Rosu, H. 1992. "S{sup 1} x S{sup 2} as a bag membrane and its Einstein-Weyl geometry." IAEA.
@misc{etde_10119613,
title = {S{sup 1} x S{sup 2} as a bag membrane and its Einstein-Weyl geometry}
author = {Rosu, H}
abstractNote = {In the hybrid skyrmion in which an anti-de Sitter bag is embedded into the skyrmion configuration a S{sup 1} x S{sup 2} membrane is lying on the compactified spatial infinity of the bag. The connection between the quark degrees of freedom and the mesonic ones is made through the membrane. This 3-dimensional manifold is at the same time Weyl-Einstein space. We present what is known until the present time to people working in the differential geometry of these spaces. (author). 11 refs.}
place = {IAEA}
year = {1992}
month = {Oct}
}