SLAC T-510 experiment for radio emission from particle showers: Detailed simulation study and interpretation

K. Bechtol; K. Belov; K. Borch; P. Chen; J. Clem; P. Gorham; C. Hast; T. Huege; R. Hyneman; K. Jobe; K. Kuwatani; J. Lam; T. C. Liu; K. Mulrey; J. Nam; C. Naudet; R. J. Nichol; C. Paciaroni; B. F. Rauch; A. Romero-Wolf; B. Rotter; D. Saltzberg; H. Schoorlemmer; D. Seckel; B. Strutt; A. Vieregg; C. Williams; S. Wissel; A. Zilles

doi:10.1103/PhysRevD.105.063025

SLAC T-510 experiment for radio emission from particle showers: Detailed simulation study and interpretation

K. Bechtol, K. Belov, K. Borch, P. Chen, J. Clem, P. Gorham, C. Hast, T. Huege, R. Hyneman, K. Jobe, K. Kuwatani, J. Lam, T. C. Liu, K. Mulrey, J. Nam, C. Naudet, R. J. Nichol, C. Paciaroni, B. F. Rauch, A. Romero-WolfB. Rotter, D. Saltzberg, H. Schoorlemmer, D. Seckel, B. Strutt, A. Vieregg, C. Williams, S. Wissel, A. Zilles

Physics

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Abstract

Over the last several decades, radio detection of air showers has been widely used to detect ultrahigh-energy cosmic rays. We developed an experiment under controlled laboratory conditions at SLAC with which we measured the radio-frequency radiation from a charged particle shower produced by bunches of electrons as primaries with known energy. The shower took place in a target made of high density polyethylene located in a strong magnetic field. The experiment was designed so that Askaryan and magnetically-induced components of the radio emission could be measured independently. At the same time, we performed a detailed simulation of this experiment to predict the radio signal using two microscopic formalisms, endpoint and ZHS. In this paper, we present the simulation scheme and make a comparison with data characteristics such as linearity with magnetic field and amplitude. The simulations agree with the measurements within uncertainties and present a good description of the data. In particular, reflections within the target that accounted for the largest systematic uncertainties are addressed. The prediction of the amplitude of Askaryan emission agrees with measurements to within 5% for the endpoint formalism and 11% for the ZHS formalism. The amplitudes of magnetically-induced emission agree to within 5% for the endpoint formalism and less than 1% for the ZHS formalism. The agreement of the absolute scale of emission gives confidence in state-of-the-art air shower simulations which are based on the applied formalisms.

Original language	English (US)
Article number	063025
Journal	Physical Review D
Volume	105
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevD.105.063025
State	Published - Mar 15 2022

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics

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10.1103/PhysRevD.105.063025

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Bechtol, K., Belov, K., Borch, K., Chen, P., Clem, J., Gorham, P., Hast, C., Huege, T., Hyneman, R., Jobe, K., Kuwatani, K., Lam, J., Liu, T. C., Mulrey, K., Nam, J., Naudet, C., Nichol, R. J., Paciaroni, C., Rauch, B. F., ... Zilles, A. (2022). SLAC T-510 experiment for radio emission from particle showers: Detailed simulation study and interpretation. Physical Review D, 105(6), [063025]. https://doi.org/10.1103/PhysRevD.105.063025

@article{04f40e754dda4a9386cdcf4bb856d535,

title = "SLAC T-510 experiment for radio emission from particle showers: Detailed simulation study and interpretation",

abstract = "Over the last several decades, radio detection of air showers has been widely used to detect ultrahigh-energy cosmic rays. We developed an experiment under controlled laboratory conditions at SLAC with which we measured the radio-frequency radiation from a charged particle shower produced by bunches of electrons as primaries with known energy. The shower took place in a target made of high density polyethylene located in a strong magnetic field. The experiment was designed so that Askaryan and magnetically-induced components of the radio emission could be measured independently. At the same time, we performed a detailed simulation of this experiment to predict the radio signal using two microscopic formalisms, endpoint and ZHS. In this paper, we present the simulation scheme and make a comparison with data characteristics such as linearity with magnetic field and amplitude. The simulations agree with the measurements within uncertainties and present a good description of the data. In particular, reflections within the target that accounted for the largest systematic uncertainties are addressed. The prediction of the amplitude of Askaryan emission agrees with measurements to within 5% for the endpoint formalism and 11% for the ZHS formalism. The amplitudes of magnetically-induced emission agree to within 5% for the endpoint formalism and less than 1% for the ZHS formalism. The agreement of the absolute scale of emission gives confidence in state-of-the-art air shower simulations which are based on the applied formalisms.",

author = "K. Bechtol and K. Belov and K. Borch and P. Chen and J. Clem and P. Gorham and C. Hast and T. Huege and R. Hyneman and K. Jobe and K. Kuwatani and J. Lam and Liu, {T. C.} and K. Mulrey and J. Nam and C. Naudet and Nichol, {R. J.} and C. Paciaroni and Rauch, {B. F.} and A. Romero-Wolf and B. Rotter and D. Saltzberg and H. Schoorlemmer and D. Seckel and B. Strutt and A. Vieregg and C. Williams and S. Wissel and A. Zilles",

note = "Funding Information: The authors thank SLAC National Accelerator Laboratory for providing facilities and support and especially Janice Nelson and Carl Hudspeth for their support and dedication that made T-510 possible. We thank D. Z. Besson for helpful discussions and Clancy W. James for helping to investigate the ZHS fallback threshold. This material is based upon work supported by the Department of Energy under Awards No. DE-AC02-76SF00515, No. DE-SC0009937, and others. Work supported in part by grants from the National Aeronautics and Space Administration and the Taiwan Ministry of Science and Technology under Project No. MOST103-2119-M-002-002, among others. Part of this research was funded through the JPL Internal Research and Technology Development program and through the Frost Fund at the California Polytechnic State University in San Luis Obispo, CA. This work was supported in part by the Kavli Institute for Cosmological Physics at the University of Chicago through Grant No. NSF PHY-1125897 and an endowment from the Kavli Foundation and its founder Fred Kavli. K. Belov acknowledges support from the Karlsruher Institut f{\"u}r Technologie under a guest fellowship. B. Rauch was supported in part by the McDonnell Center for the Space Sciences at Washington University in St. Louis. We are grateful to the ANITA collaboration for use of antennas and other equipment. Publisher Copyright: {\textcopyright} 2022 American Physical Society.",

year = "2022",

month = mar,

day = "15",

doi = "10.1103/PhysRevD.105.063025",

language = "English (US)",

volume = "105",

journal = "Physical Review D",

issn = "2470-0010",

publisher = "American Physical Society",

number = "6",

}

Bechtol, K, Belov, K, Borch, K, Chen, P, Clem, J, Gorham, P, Hast, C, Huege, T, Hyneman, R, Jobe, K, Kuwatani, K, Lam, J, Liu, TC, Mulrey, K, Nam, J, Naudet, C, Nichol, RJ, Paciaroni, C, Rauch, BF, Romero-Wolf, A, Rotter, B, Saltzberg, D, Schoorlemmer, H, Seckel, D, Strutt, B, Vieregg, A, Williams, C, Wissel, S & Zilles, A 2022, 'SLAC T-510 experiment for radio emission from particle showers: Detailed simulation study and interpretation', Physical Review D, vol. 105, no. 6, 063025. https://doi.org/10.1103/PhysRevD.105.063025

TY - JOUR

T1 - SLAC T-510 experiment for radio emission from particle showers

T2 - Detailed simulation study and interpretation

AU - Bechtol, K.

AU - Belov, K.

AU - Borch, K.

AU - Chen, P.

AU - Clem, J.

AU - Gorham, P.

AU - Hast, C.

AU - Huege, T.

AU - Hyneman, R.

AU - Jobe, K.

AU - Kuwatani, K.

AU - Lam, J.

AU - Liu, T. C.

AU - Mulrey, K.

AU - Nam, J.

AU - Naudet, C.

AU - Nichol, R. J.

AU - Paciaroni, C.

AU - Rauch, B. F.

AU - Romero-Wolf, A.

AU - Rotter, B.

AU - Saltzberg, D.

AU - Schoorlemmer, H.

AU - Seckel, D.

AU - Strutt, B.

AU - Vieregg, A.

AU - Williams, C.

AU - Wissel, S.

AU - Zilles, A.

N1 - Funding Information: The authors thank SLAC National Accelerator Laboratory for providing facilities and support and especially Janice Nelson and Carl Hudspeth for their support and dedication that made T-510 possible. We thank D. Z. Besson for helpful discussions and Clancy W. James for helping to investigate the ZHS fallback threshold. This material is based upon work supported by the Department of Energy under Awards No. DE-AC02-76SF00515, No. DE-SC0009937, and others. Work supported in part by grants from the National Aeronautics and Space Administration and the Taiwan Ministry of Science and Technology under Project No. MOST103-2119-M-002-002, among others. Part of this research was funded through the JPL Internal Research and Technology Development program and through the Frost Fund at the California Polytechnic State University in San Luis Obispo, CA. This work was supported in part by the Kavli Institute for Cosmological Physics at the University of Chicago through Grant No. NSF PHY-1125897 and an endowment from the Kavli Foundation and its founder Fred Kavli. K. Belov acknowledges support from the Karlsruher Institut für Technologie under a guest fellowship. B. Rauch was supported in part by the McDonnell Center for the Space Sciences at Washington University in St. Louis. We are grateful to the ANITA collaboration for use of antennas and other equipment. Publisher Copyright: © 2022 American Physical Society.

PY - 2022/3/15

Y1 - 2022/3/15

N2 - Over the last several decades, radio detection of air showers has been widely used to detect ultrahigh-energy cosmic rays. We developed an experiment under controlled laboratory conditions at SLAC with which we measured the radio-frequency radiation from a charged particle shower produced by bunches of electrons as primaries with known energy. The shower took place in a target made of high density polyethylene located in a strong magnetic field. The experiment was designed so that Askaryan and magnetically-induced components of the radio emission could be measured independently. At the same time, we performed a detailed simulation of this experiment to predict the radio signal using two microscopic formalisms, endpoint and ZHS. In this paper, we present the simulation scheme and make a comparison with data characteristics such as linearity with magnetic field and amplitude. The simulations agree with the measurements within uncertainties and present a good description of the data. In particular, reflections within the target that accounted for the largest systematic uncertainties are addressed. The prediction of the amplitude of Askaryan emission agrees with measurements to within 5% for the endpoint formalism and 11% for the ZHS formalism. The amplitudes of magnetically-induced emission agree to within 5% for the endpoint formalism and less than 1% for the ZHS formalism. The agreement of the absolute scale of emission gives confidence in state-of-the-art air shower simulations which are based on the applied formalisms.

AB - Over the last several decades, radio detection of air showers has been widely used to detect ultrahigh-energy cosmic rays. We developed an experiment under controlled laboratory conditions at SLAC with which we measured the radio-frequency radiation from a charged particle shower produced by bunches of electrons as primaries with known energy. The shower took place in a target made of high density polyethylene located in a strong magnetic field. The experiment was designed so that Askaryan and magnetically-induced components of the radio emission could be measured independently. At the same time, we performed a detailed simulation of this experiment to predict the radio signal using two microscopic formalisms, endpoint and ZHS. In this paper, we present the simulation scheme and make a comparison with data characteristics such as linearity with magnetic field and amplitude. The simulations agree with the measurements within uncertainties and present a good description of the data. In particular, reflections within the target that accounted for the largest systematic uncertainties are addressed. The prediction of the amplitude of Askaryan emission agrees with measurements to within 5% for the endpoint formalism and 11% for the ZHS formalism. The amplitudes of magnetically-induced emission agree to within 5% for the endpoint formalism and less than 1% for the ZHS formalism. The agreement of the absolute scale of emission gives confidence in state-of-the-art air shower simulations which are based on the applied formalisms.

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U2 - 10.1103/PhysRevD.105.063025

DO - 10.1103/PhysRevD.105.063025

M3 - Article

AN - SCOPUS:85128275215

SN - 2470-0010

VL - 105

JO - Physical Review D

JF - Physical Review D

IS - 6

M1 - 063025

ER -

SLAC T-510 experiment for radio emission from particle showers: Detailed simulation study and interpretation

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