Measurement of inclusive forward neutron production cross section in proton-proton collisions at $$ \sqrt{s}=13 $$ TeV with the LHCf Arm2 detector

Адриани, О.; Berti, Eugenio; Bonechi, L.; Bongi, M.; D’Alessandro, R.; Detti, S.; Haguenauer, M.; Itow, Y.; Kasahara, K.; Makino, Yuya; Masuda, K.; Menjo, H.; Muraki, Y.; Ohashi, K.; Papini, P.; Ricciarini, S.; Sako, Takashi; Sakurai, N.; Sato, Kenta; Shinoda, M.; Suzuki, T.; Tamura, T.; Tiberio, A.; Torii, Shoji; Tricomi, A.; Turner, W. C.; Ueno, M.; Zhou, Q.

doi:10.1007/jhep11(2018)073

Cited by 33 publications

(34 citation statements)

References 32 publications

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“…Understanding the scaling of the forward particle distributions at collider energies is the key to extrapolating to higher interaction energies. LHCf (Adriani et al, 2018) is a good example that such detectors can be built even though there are large technical challenges and limitations.…”

Section: Hadronic Interactions At Ultrahigh Energiesmentioning

confidence: 99%

Open Questions in Cosmic-Ray Research at Ultrahigh Energies

Batista

Biteau

Bustamante

et al. 2019

Front. Astron. Space Sci.

205

119

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We review open questions and prospects for progress in ultrahigh-energy cosmic ray (UHECR) research, based on a series of discussions that took place during the "The High-Energy Universe: Gamma-Ray, Neutrino, and Cosmic-ray Astronomy" MIAPP workshop in 2018. Specifically, we overview open questions on the origin of the bulk of UHECRs, the UHECR mass composition, the origin of the end of the cosmic-ray spectrum, the transition from Galactic to extragalactic cosmic rays, the effect of magnetic fields on the trajectories of UHECRs, anisotropy expectations for specific astrophysical scenarios, hadronic interactions, and prospects for discovering neutral particles as well as new physics at ultrahigh energies. We also briefly overview upcoming and proposed UHECR experiments and discuss their projected science reach.

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Section: Hadronic Interactions At Ultrahigh Energiesmentioning

confidence: 99%

Open Questions in Cosmic-Ray Research at Ultrahigh Energies

Batista

Biteau

Bustamante

et al. 2019

Front. Astron. Space Sci.

205

119

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“…Because of the key role that forward baryons have in the development of the air showers and in the abundance of the muonic component [24], a large activity of the LHCf collaboration is dedicated to neutron measurements. A first result relative to the inclusive differential production cross section of very forward neutrons+antineutrons (hereafter simply called neutrons) produced in p-p collisions at √ s = 13 TeV was already published [25]. Here this analysis is extended from three to six pseudorapidity regions, in order to have enough data points to derive three important quantities that are directly connected to EAS development: neutron energy flow, cross section and average inelasticity.…”

Section: Jhep07(2020)016mentioning

confidence: 99%

“…Monte Carlo simulations with the same experimental configuration used for LHC data taking are necessary for four different purposes: estimation of correction factors and systematic uncertainties, validation of the whole analysis procedure, energy spectra unfolding, and data-model comparison. A description of all the simulation data sets, detailing how they were generated, which models were used and which effects were considered, can be found in [25]. Here it is important to remind that, depending on the purpose, a given sample is generated taking into account one or more of the following steps: hadronic collision, transport of secondary products from IP1 to TAN, and detector interactions.…”

Section: Jhep07(2020)016 4 Simulation Data Setmentioning

confidence: 99%

“…Apart from small refinements, event reconstruction algorithms and event selection criteria are similar to the ones described in [25]. The incident energy is reconstructed from the total energy deposit in the calorimeter, properly weighting the release in each scintillator layer for the energy lost in the corresponding front tungsten layer and applying position dependent correction factors for shower lateral leakage and light collection efficiency.…”

Section: Event Reconstructionmentioning

confidence: 99%

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Measurement of energy flow, cross section and average inelasticity of forward neutrons produced in $$ \sqrt{s} $$ = 13 TeV proton-proton collisions with the LHCf Arm2 detector

Adriani

Berti

Bonechi³

et al. 2020

J. High Energ. Phys.

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In this paper, we report the measurement of the energy flow, the cross section and the average inelasticity of forward neutrons (+ antineutrons) produced in √ s = 13 TeV proton-proton collisions. These quantities are obtained from the inclusive differential production cross section, measured using the LHCf Arm2 detector at the CERN Large Hadron Collider. The measurements are performed in six pseudorapidity regions: three of them (η > 10.75, 8.99 < η < 9.21 and 8.80 < η < 8.99), albeit with smaller acceptance and larger uncertainties, were already published in a previous work, whereas the remaining three (10.06 < η < 10.75, 9.65 < η < 10.06 and 8.65 < η < 8.80) are presented here for the first time. The analysis was carried out using a data set acquired in June 2015 with a corresponding integrated luminosity of 0.194 nb −1. Comparing the experimental measurements with the expectations of several hadronic interaction models used to simulate cosmic ray air showers, none of these generators resulted to have a satisfactory agreement in all the phase space selected for the analysis. The inclusive differential production cross section for η > 10.75 is not reproduced by any model, whereas the results still indicate a significant but less serious deviation at lower pseudorapidities. Depending on the pseudorapidity region, the generators showing the best overall agreement with data are either SIBYLL 2.3 or EPOS-LHC. Furthermore, apart from the most forward region, the derived energy flow and cross section distributions are best reproduced by EPOS-LHC. Finally, even if none of the models describe the elasticity distribution in a satisfactory way, the extracted average inelasticity is consistent with the QGSJET II-04 value, while most of the other generators give values that lie just outside the experimental uncertainties.

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“…Finally, hadron simulations are required to estimate the sensitivity of future gamma-ray observatories, such as the Cherenkov Telescope Array (CTA) [13], the Southern Gamma-ray Survey Observatory (SGSO) [14], and the Large High Altitude Air Shower Observatory (LHAASO) [15] which could be affected by the choice of models. The advent of LHC measurements has provided large amounts of data at never before probed energies [16] and at extreme rapidities [17,18]. This data glut promises improvements to hadronic interaction models by facilitating model tuning in energy ranges not before possible and has resulted in the creation of a new generation of air shower focused hadronic interaction models [19][20][21] tuned to this data set.…”

Section: Introductionmentioning

confidence: 99%

Systematic differences due to high energy hadronic interaction models in air shower simulations in the 100 GeV-100 TeV range

Parsons

Schoorlemmer

2019

Phys. Rev. D

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The predictions of hadronic interaction models for cosmic-ray induced air showers contain inherent uncertainties due to limitations of available accelerator data and theoretical understanding in the required energy and rapidity regime. Differences between models are typically evaluated in the range appropriate for cosmic-ray air shower arrays (10 15 -10 20 eV). However, accurate modelling of charged cosmic-ray measurements with ground based gamma-ray observatories is becoming more and more important.We assess the model predictions on the gross behaviour of measurable air shower parameters in the energy (0.1-100 TeV) and altitude ranges most appropriate for detection by ground-based gammaray observatories. We go on to investigate the particle distributions just after the first interaction point, to examine how differences in the micro-physics of the models may compound into differences in the gross air shower behaviour. Differences between the models above 1 TeV are typically less than 10%. However, we find the largest variation in particle densities at ground at the lowest energy tested (100 GeV), resulting from striking differences in the early stages of shower development.

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Measurement of inclusive forward neutron production cross section in proton-proton collisions at $$ \sqrt{s}=13 $$ TeV with the LHCf Arm2 detector

Cited by 33 publications

References 32 publications

Open Questions in Cosmic-Ray Research at Ultrahigh Energies

Open Questions in Cosmic-Ray Research at Ultrahigh Energies

Measurement of energy flow, cross section and average inelasticity of forward neutrons produced in $$ \sqrt{s} $$ = 13 TeV proton-proton collisions with the LHCf Arm2 detector

Systematic differences due to high energy hadronic interaction models in air shower simulations in the 100 GeV-100 TeV range

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