Local scale-invariance breaking in the standard model by two-measure theory

We introduce Weyl’s scale invariance as additional local symmetry in the standard model of electroweak interactions. Under this, the gauge symmetry of the standard model now is SU(3)×SU(2)×U(1)×U˜(1), where U˜(1) is for local scale invariance, and its gauge boson is called the Weylon. Also introduce...

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Veröffentlicht in:	Physical review. D 2018-09, Vol.98 (5), Article 055022
Hauptverfasser:	Guendelman, Eduardo I., Nishino, Hitoshi, Rajpoot, Subhash
Format:	Artikel
Sprache:	eng
Schlagworte:	Bosons Broken symmetry Cost sharing Electroweak interactions (field theory) Electroweak model Fermions Fractals Gravitational constant Invariance Neutrinos Scalars Scale (ratio) Scale invariance Symmetry Weight
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container_title	Physical review. D
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creator	Guendelman, Eduardo I. Nishino, Hitoshi Rajpoot, Subhash
description	We introduce Weyl’s scale invariance as additional local symmetry in the standard model of electroweak interactions. Under this, the gauge symmetry of the standard model now is SU(3)×SU(2)×U(1)×U˜(1), where U˜(1) is for local scale invariance, and its gauge boson is called the Weylon. Also introduced are two new scalars σ1 and σ2 with the common scaling weight −1. The mechanism for spontaneous breaking of scale invariance is invoked by coupling σ2 to a metric-independent measure defined in terms of an additional four scalars ϕI(I=1,2,3,4). Weyl’s scale invariance is now implemented by combining it with internal diffeomorphisms of the four scalars ϕi. We show that once local scale invariance is broken, the phenomenon (a) generates Newton’s gravitational constant GN and (b) triggers spontaneous symmetry breaking in the conventional manner resulting in masses for the conventional fermions and bosons. The scale at which Weyl’s scale symmetry breaks is of order Planck mass. If right-handed neutrinos are also introduced, their absence at present energy scales is attributed to their mass being tied to the scale at which scale invariance breaks. New C- and CP-violating effects can also be induced by mixing the Weylon with the hypercharge gauge boson of the standard model.
doi_str_mv	10.1103/PhysRevD.98.055022
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Under this, the gauge symmetry of the standard model now is SU(3)×SU(2)×U(1)×U˜(1), where U˜(1) is for local scale invariance, and its gauge boson is called the Weylon. Also introduced are two new scalars σ1 and σ2 with the common scaling weight −1. The mechanism for spontaneous breaking of scale invariance is invoked by coupling σ2 to a metric-independent measure defined in terms of an additional four scalars ϕI(I=1,2,3,4). Weyl’s scale invariance is now implemented by combining it with internal diffeomorphisms of the four scalars ϕi. We show that once local scale invariance is broken, the phenomenon (a) generates Newton’s gravitational constant GN and (b) triggers spontaneous symmetry breaking in the conventional manner resulting in masses for the conventional fermions and bosons. The scale at which Weyl’s scale symmetry breaks is of order Planck mass. 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D</title><description>We introduce Weyl’s scale invariance as additional local symmetry in the standard model of electroweak interactions. Under this, the gauge symmetry of the standard model now is SU(3)×SU(2)×U(1)×U˜(1), where U˜(1) is for local scale invariance, and its gauge boson is called the Weylon. Also introduced are two new scalars σ1 and σ2 with the common scaling weight −1. The mechanism for spontaneous breaking of scale invariance is invoked by coupling σ2 to a metric-independent measure defined in terms of an additional four scalars ϕI(I=1,2,3,4). Weyl’s scale invariance is now implemented by combining it with internal diffeomorphisms of the four scalars ϕi. We show that once local scale invariance is broken, the phenomenon (a) generates Newton’s gravitational constant GN and (b) triggers spontaneous symmetry breaking in the conventional manner resulting in masses for the conventional fermions and bosons. The scale at which Weyl’s scale symmetry breaks is of order Planck mass. If right-handed neutrinos are also introduced, their absence at present energy scales is attributed to their mass being tied to the scale at which scale invariance breaks. 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D</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Guendelman, Eduardo I.</au><au>Nishino, Hitoshi</au><au>Rajpoot, Subhash</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Local scale-invariance breaking in the standard model by two-measure theory</atitle><jtitle>Physical review. D</jtitle><date>2018-09-18</date><risdate>2018</risdate><volume>98</volume><issue>5</issue><artnum>055022</artnum><issn>2470-0010</issn><eissn>2470-0029</eissn><abstract>We introduce Weyl’s scale invariance as additional local symmetry in the standard model of electroweak interactions. Under this, the gauge symmetry of the standard model now is SU(3)×SU(2)×U(1)×U˜(1), where U˜(1) is for local scale invariance, and its gauge boson is called the Weylon. Also introduced are two new scalars σ1 and σ2 with the common scaling weight −1. The mechanism for spontaneous breaking of scale invariance is invoked by coupling σ2 to a metric-independent measure defined in terms of an additional four scalars ϕI(I=1,2,3,4). Weyl’s scale invariance is now implemented by combining it with internal diffeomorphisms of the four scalars ϕi. We show that once local scale invariance is broken, the phenomenon (a) generates Newton’s gravitational constant GN and (b) triggers spontaneous symmetry breaking in the conventional manner resulting in masses for the conventional fermions and bosons. The scale at which Weyl’s scale symmetry breaks is of order Planck mass. If right-handed neutrinos are also introduced, their absence at present energy scales is attributed to their mass being tied to the scale at which scale invariance breaks. 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subjects	Bosons Broken symmetry Cost sharing Electroweak interactions (field theory) Electroweak model Fermions Fractals Gravitational constant Invariance Neutrinos Scalars Scale (ratio) Scale invariance Symmetry Weight
title	Local scale-invariance breaking in the standard model by two-measure theory
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