Secondary decays in atmospheric charm contributions to the flux of muons and muon neutrinos

Pasquali, L.; Reno, Mary Hall; Sarčević, Ina

doi:10.1016/s0927-6505(98)00019-x

“…II Calculations of neutrino fluxes: The earliest prompt neutrino calculations employed a proton-only cosmic ray flux known as the "broken power-law" [61,62,68,102,103]. Recent observations of cosmic ray flux indicate a mixed composition [104][105][106]: the Gaisser 2012 fit [104] with (i) the third component being proton (H3P), or (ii) mixed (H3A), and the Stanev et al, 2014 fit [106] fit with (iii) three (H14A), or (iv) four cosmic ray populations (H14B).…”

mentioning

confidence: 99%

IceCube can constrain the intrinsic charm of the proton

Laha

¹

,

Brodsky

²

2017

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The discovery of extraterrestrial neutrinos in the ∼ 30 TeV -PeV energy range by IceCube provides new constraints on high energy astrophysics. An important background to the signal are the prompt neutrinos which originate from the decay of charm hadrons produced by high energy cosmic-ray particles interacting in the Earth's atmosphere. It is conventional to use the calculations of charm hadroproduction using gluon splitting g → cc alone. However, QCD predicts an additional "intrinsic" component of the heavy quark distribution which arises from diagrams where heavy quarks are multiply connected to the proton's valence quarks. We estimate the prompt neutrino spectrum due to intrinsic charm. We find that the atmospheric prompt neutrino flux from intrinsic charm is comparable to those calculated using QCD computations not including intrinsic charm, once we normalize the intrinsic charm differential cross sections to the ISR and the LEBC-MPS collaboration data. In future, IceCube will constrain the intrinsic charm content of the proton and will contribute to one of the major questions in high energy physics phenomenology.

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“…Although the average multiplicities of different charmed hadrons are very small, they are not inconceivably inconsiderable, because regarding CR showers in the atmosphere, the extremely rare cases of the charmed hadrons production are also very significant, as they can change the traditional shower behaviour completely [7]. This is due to the fact that, as discussed earlier, charmed hadrons are most notable sources of atmospheric prompt leptons, which are very important in understanding the nature of CR as a whole [1,2]. The average multiplicities of different charmed hadrons under study are not much different and approaches approximately the same value, as the values of ffiffi s p goes on increasing beyond 1000 GeV (Fig.…”

Section: General Features Of Charmed Hadroproductionmentioning

confidence: 98%

“…At lower energies (up to GeV), the conventional sources of these fluxes are p and K mesons (relatively long lived particles). In the high energy range (multi-TeV) the most notable sources of these fluxes are considered as charmed particles; these are produced in the atmosphere in cosmic ray interactions [1,2]. However to draw a definite conclusion on the fluxes of prompt muons and neutrinos from the available data obtained with surface and underground detectors, we need a sound physical model which should be based on the extrapolating of proper charmed production data obtained at accelerator energies of the order of magnitudes higher for the relevant cosmic ray collisions.…”

Section: Introductionmentioning

confidence: 99%

Charmed hadron production in pp collision

Goswami

¹

2007

Astroparticle Physics

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“…II Calculations of neutrino fluxes: The earliest prompt neutrino calculations employed a proton-only cosmic ray flux known as the "broken power-law" [62,63,69,103,104]. Recent observations of cosmic ray flux indicate a mixed composition [105][106][107]: the Gaisser 2012 fit [105] with (i) the third component being proton (H3P), or (ii) mixed (H3A), and the Stanev et al, 2014 fit [107] fit with (iii) three (H14A), or (iv) four cosmic ray populations (H14B).…”

Section: Arxiv:160708240v3 [Hep-ph] 7 Dec 2017mentioning

confidence: 99%

IC at IC: IceCube can constrain the intrinsic charm of the proton

Laha

¹

,

Brodsky

²

2016

View full text Add to dashboard Cite

The discovery of extraterrestrial neutrinos in the ∼ 30 TeV -PeV energy range by IceCube provides new constraints on high energy astrophysics. An important background to the signal are the prompt neutrinos which originate from the decay of charm hadrons produced by high energy cosmic-ray particles interacting in the Earth's atmosphere. It is conventional to use the calculations of charm hadroproduction using gluon splitting g → cc alone. However, QCD predicts an additional "intrinsic" component of the heavy quark distribution which arises from diagrams where heavy quarks are multiply connected to the proton's valence quarks. We estimate the prompt neutrino spectrum due to intrinsic charm. We find that the atmospheric prompt neutrino flux from intrinsic charm is comparable to those calculated using QCD computations not including intrinsic charm, once we normalize the intrinsic charm differential cross sections to the ISR and the LEBC-MPS collaboration data. In future, IceCube will constrain the intrinsic charm content of the proton and will contribute to one of the major questions in high energy physics phenomenology.

show abstract

Secondary decays in atmospheric charm contributions to the flux of muons and muon neutrinos

Cited by 12 publications

References 32 publications

IceCube can constrain the intrinsic charm of the proton

IceCube can constrain the intrinsic charm of the proton

Charmed hadron production in pp collision

IC at IC: IceCube can constrain the intrinsic charm of the proton

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