Digamma, what next?

If the 750 GeV resonance in the diphoton channel is confirmed, what are the measurements necessary to infer the properties of the new particle and understand its nature? We address this question in the framework of a single new scalar particle, called digamma ($\digamma$). We describe it by an effec...

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Autores principales: Franceschini, Roberto, Giudice, Gian F., Kamenik, Jernej F., McCullough, Matthew, Riva, Francesco, Strumia, Alessandro, Torre, Riccardo
Lenguaje:eng
Publicado: 2016
Materias:
Particle Physics - Phenomenology
Acceso en línea:https://dx.doi.org/10.1007/JHEP07(2016)150
http://cds.cern.ch/record/2148143
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author Franceschini, Roberto
Giudice, Gian F.
Kamenik, Jernej F.
McCullough, Matthew
Riva, Francesco
Strumia, Alessandro
Torre, Riccardo
author_facet Franceschini, Roberto
Giudice, Gian F.
Kamenik, Jernej F.
McCullough, Matthew
Riva, Francesco
Strumia, Alessandro
Torre, Riccardo
author_sort Franceschini, Roberto
collection CERN
description If the 750 GeV resonance in the diphoton channel is confirmed, what are the measurements necessary to infer the properties of the new particle and understand its nature? We address this question in the framework of a single new scalar particle, called digamma ($\digamma$). We describe it by an effective field theory, which allows us to obtain general and model-independent results, and to identify the most useful observables, whose relevance will remain also in model-by-model analyses. We derive full expressions for the leading-order processes and compute rates for higher-order decays, digamma production in association with jets, gauge or Higgs bosons, and digamma pair production. We illustrate how measurements of these higher-order processes can be used to extract couplings, quantum numbers, and properties of the new particle.
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institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2016
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spelling cern-21481432022-08-10T12:48:42Zdoi:10.1007/JHEP07(2016)150http://cds.cern.ch/record/2148143engFranceschini, RobertoGiudice, Gian F.Kamenik, Jernej F.McCullough, MatthewRiva, FrancescoStrumia, AlessandroTorre, RiccardoDigamma, what next?Particle Physics - PhenomenologyIf the 750 GeV resonance in the diphoton channel is confirmed, what are the measurements necessary to infer the properties of the new particle and understand its nature? We address this question in the framework of a single new scalar particle, called digamma ($\digamma$). We describe it by an effective field theory, which allows us to obtain general and model-independent results, and to identify the most useful observables, whose relevance will remain also in model-by-model analyses. We derive full expressions for the leading-order processes and compute rates for higher-order decays, digamma production in association with jets, gauge or Higgs bosons, and digamma pair production. We illustrate how measurements of these higher-order processes can be used to extract couplings, quantum numbers, and properties of the new particle.If the 750 GeV resonance in the diphoton channel is confirmed, what are the measurements necessary to infer the properties of the new particle and understand its nature? We address this question in the framework of a single new scalar particle, called digamma (Ϝ). We describe it by an effective field theory, which allows us to obtain general and model-independent results, and to identify the most useful observables, whose relevance will remain also in model-by-model analyses. We derive full expressions for the leading-order processes and compute rates for higher-order decays, digamma production in association with jets, gauge or Higgs bosons, and digamma pair production. We illustrate how measurements of these higher-order processes can be used to extract couplings, quantum numbers, and properties of the new particle.If the 750 GeV resonance in the diphoton channel is confirmed, what are the measurements necessary to infer the properties of the new particle and understand its nature? We address this question in the framework of a single new scalar particle, called digamma ($\digamma$). We describe it by an effective field theory, which allows us to obtain general and model-independent results, and to identify the most useful observables, whose relevance will remain also in model-by-model analyses. We derive full expressions for the leading-order processes and compute rates for higher-order decays, digamma production in association with jets, gauge or Higgs bosons, and digamma pair production. We illustrate how measurements of these higher-order processes can be used to extract couplings, quantum numbers, and properties of the new particle.arXiv:1604.06446CERN-TH-2016-090CERN-TH-2016-090oai:cds.cern.ch:21481432016-04-21
spellingShingle Particle Physics - Phenomenology
Franceschini, Roberto
Giudice, Gian F.
Kamenik, Jernej F.
McCullough, Matthew
Riva, Francesco
Strumia, Alessandro
Torre, Riccardo
Digamma, what next?
title Digamma, what next?
title_full Digamma, what next?
title_fullStr Digamma, what next?
title_full_unstemmed Digamma, what next?
title_short Digamma, what next?
title_sort digamma, what next?
topic Particle Physics - Phenomenology
url https://dx.doi.org/10.1007/JHEP07(2016)150
http://cds.cern.ch/record/2148143
work_keys_str_mv AT franceschiniroberto digammawhatnext
AT giudicegianf digammawhatnext
AT kamenikjernejf digammawhatnext
AT mcculloughmatthew digammawhatnext
AT rivafrancesco digammawhatnext
AT strumiaalessandro digammawhatnext
AT torrericcardo digammawhatnext

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