TY - JOUR
T1 - Luminous efficiency of meteors derived from ablation model after assessment of its range of validity
AU - Drolshagen, E.
AU - Ott, T.
AU - Koschny, D.
AU - Drolshagen, G.
AU - Vaubaillon, J.
AU - Colas, F.
AU - Zanda, B.
AU - Bouley, S.
AU - Jeanne, S.
AU - Malgoyre, A.
AU - Birlan, M.
AU - Vernazza, P.
AU - Gardiol, D.
AU - Nedelcu, D. A.
AU - Rowe, J.
AU - Forcier, M.
AU - Trigo-Rodriguez, J. M.
AU - Peña-Asensio, E.
AU - Lamy, H.
AU - Ferrière, L.
AU - Barghini, D.
AU - Carbognani, A.
AU - Di Martino, M.
AU - Rasetti, S.
AU - Valsecchi, G. B.
AU - Volpicelli, C. A.
AU - Di Carlo, M.
AU - Knapic, C.
AU - Pratesi, G.
AU - Riva, W.
AU - Stirpe, G. M.
AU - Zorba, S.
AU - Hernandez, O.
AU - Grandchamps, A.
AU - Jehin, E.
AU - Jobin, M.
AU - King, A.
AU - Sanchez-Lavega, A.
AU - Toni, A.
AU - Rimola, A.
AU - Poppe, B.
N1 - Funding Information:
Acknowledgements. We thank the European Space Agency and the University of Oldenburg for funding this project. We would especially like to thank Maria Gritsevich for her support and constructive discussions on this matter. A special gratitude goes to the FRIPON Network for providing the data used for this study and to the FRIPON team for their support of this project. FRIPON was initiated by funding from ANR (grant N.13-BS05-0009-03), carried by the Paris Observatory, Muséum National d’Histoire Naturelle, Paris-Saclay University and Institut Pythéas (LAM-CEREGE). Vigie-Ciel was part of the 65 Millions d’Observateurs project, carried by the Muséum National d’Histoire Naturelle and funded by the French Investissements d’Avenir program. FRIPON data are hosted and processed at Institut Pythéas SIP (Service Informatique Pythéas), and a mirror is hosted at IMCCE (Institut de Mécanique Céleste et de Calcul des Éphémérides/Paris Observatory) with the help of IDOC8 (Integrated Data and Operation Center), supported by CNRS and CNES. PRISMA is the Italian Network for Systematic surveillance of Meteors and Atmosphere. It is a collaboration initiated and coordinated by the Italian National Institute for Astrophysics (INAF) that counts members among research institutes, universities, associations and schools. The complete list of PRISMA members is available here: http://www.prisma.inaf.it. PRISMA was funded by 2016/0476 and 2019/0672 Research and Education grants from Fondazione Cassa di Risparmio di Torino and by a 2016 grant from Fondazione Agostino De Mari (Savona). FRIPON-Spain is coordinated from the Institute of Space Sciences (CSIC-IEEC). J.M.T.-R. and E.P.A. acknowledge financial support in research project PGC2018-097374-B-I00 (PI: J.M.T.-R.) funded FEDER/MCI-AEI.
Publisher Copyright:
© ESO 2021.
PY - 2021/8/1
Y1 - 2021/8/1
N2 - Context. The luminous efficiency, τ, can be used to compute the pre-Atmospheric masses of meteoroids from corresponding recorded meteor brightnesses. The derivation of the luminous efficiency is non-Trivial and is subject to biases and model assumptions. This has led to greatly varying results in the last decades of studies. Aims. The present paper aims to investigate how a reduction in various observational biases can be achieved to derive (more) reliable values for the luminous efficiency. Methods. A total of 281 meteors observed by the Fireball Recovery and InterPlanetary Observation Network (FRIPON) are studied. The luminous efficiencies of the events are computed using an ablation-based model. The relations of τ as a function of the pre-Atmospheric meteoroid velocity, ve, and mass, Me, are studied. Various aspects that could render the method less valid, cause inaccuracies, or bias the results are investigated. On this basis, the best suitable meteors were selected for luminous efficiency computations. Results. The presented analysis shows the limits of the used method. The most influential characteristics that are necessary for reliable results for the τ computation were identified. We study the dependence of τ on the assumed meteoroid's density, ρ, and include improved ρ-values for objects with identified meteoroid stream association. Based on the discovered individual biases and constraints we create a pre-debiased subset of 54 well-recorded events with a relative velocity change >80%, a final height <70 km, and a Knudsen number Kn < 0.01; this last value indicates that the events were observed in the continuum-flow regime. We find τ-values in the range between 0.012% and 1.1% for this pre-debiased subset and relations of τ to ve and Me of: τ=7.33â ve-1.10 and τ=0.28â Me-0.33. Conclusions. The derived luminous efficiency of meteoroids depends on the assumed material density. Our results indicate that the applied debiasing method improves the analysis of τ from decelerated meteoroids. The underlying method is only valid for meteors in the continuum-flow regime. These events tend to have low end heights, large masses, and high deceleration.
AB - Context. The luminous efficiency, τ, can be used to compute the pre-Atmospheric masses of meteoroids from corresponding recorded meteor brightnesses. The derivation of the luminous efficiency is non-Trivial and is subject to biases and model assumptions. This has led to greatly varying results in the last decades of studies. Aims. The present paper aims to investigate how a reduction in various observational biases can be achieved to derive (more) reliable values for the luminous efficiency. Methods. A total of 281 meteors observed by the Fireball Recovery and InterPlanetary Observation Network (FRIPON) are studied. The luminous efficiencies of the events are computed using an ablation-based model. The relations of τ as a function of the pre-Atmospheric meteoroid velocity, ve, and mass, Me, are studied. Various aspects that could render the method less valid, cause inaccuracies, or bias the results are investigated. On this basis, the best suitable meteors were selected for luminous efficiency computations. Results. The presented analysis shows the limits of the used method. The most influential characteristics that are necessary for reliable results for the τ computation were identified. We study the dependence of τ on the assumed meteoroid's density, ρ, and include improved ρ-values for objects with identified meteoroid stream association. Based on the discovered individual biases and constraints we create a pre-debiased subset of 54 well-recorded events with a relative velocity change >80%, a final height <70 km, and a Knudsen number Kn < 0.01; this last value indicates that the events were observed in the continuum-flow regime. We find τ-values in the range between 0.012% and 1.1% for this pre-debiased subset and relations of τ to ve and Me of: τ=7.33â ve-1.10 and τ=0.28â Me-0.33. Conclusions. The derived luminous efficiency of meteoroids depends on the assumed material density. Our results indicate that the applied debiasing method improves the analysis of τ from decelerated meteoroids. The underlying method is only valid for meteors in the continuum-flow regime. These events tend to have low end heights, large masses, and high deceleration.
KW - Atmospheric effects
KW - Comets: general
KW - Meteorites, meteors, meteoroids
KW - Methods: data analysis
KW - Minor planets, asteroids: general
KW - Techniques: photometric
UR - http://www.scopus.com/inward/record.url?scp=85112860515&partnerID=8YFLogxK
U2 - 10.1051/0004-6361/202140917
DO - 10.1051/0004-6361/202140917
M3 - Article
AN - SCOPUS:85112860515
SN - 0004-6361
VL - 652
JO - Astronomy and Astrophysics
JF - Astronomy and Astrophysics
M1 - A84
ER -