Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams

Peter Jenniskens; Stuart Pilorz; Peter S. Gural; Dave Samuels; Steve Rau; Timothy M.C. Abbott; Jim Albers; Scott Austin; Dan Avner; Jack W. Baggaley; Tim Beck; Solvay Blomquist; Mustafa Boyukata; Martin Breukers; Walt Cooney; Tim Cooper; Marcelo De Cicco; Hadrien Devillepoix; Eric Egland; Elize Fahl; Megan Gialluca; Bryant Grigsby; Toni Hanke; Barbara Harris; Steve Heathcote; Samantha Hemmelgarn; Andy Howell; Emmanuel Jehin; Carl Johannink; Luke Juneau; Erika Kisvarsanyi; Philip Mey; Nick Moskovitz; Mohammad Odeh; Brian Rachford; David Rollinson; James M. Scott; Martin C. Towner; Ozan Unsalan; Rynault van Wyk; Jeff Wood; James D. Wray; Jérémie Vaubaillon; Dante S. Lauretta

doi:10.1016/j.icarus.2024.116034

Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams

Peter Jenniskens, Stuart Pilorz, Peter S. Gural, Dave Samuels, Steve Rau, Timothy M.C. Abbott, Jim Albers, Scott Austin, Dan Avner, Jack W. Baggaley, Tim Beck, Solvay Blomquist, Mustafa Boyukata, Martin Breukers, Walt Cooney, Tim Cooper, Marcelo De Cicco, Hadrien Devillepoix, Eric Egland, Elize FahlMegan Gialluca, Bryant Grigsby, Toni Hanke, Barbara Harris, Steve Heathcote, Samantha Hemmelgarn, Andy Howell, Emmanuel Jehin, Carl Johannink, Luke Juneau, Erika Kisvarsanyi, Philip Mey, Nick Moskovitz, Mohammad Odeh, Brian Rachford, David Rollinson, James M. Scott, Martin C. Towner, Ozan Unsalan, Rynault van Wyk, Jeff Wood, James D. Wray, Jérémie Vaubaillon, Dante S. Lauretta

Research output: Contribution to journal › Article › peer-review

Abstract

While comets eject mass mostly at cm-sizes and larger, that size range of particles is mostly absent from the interplanetary medium. Such particles are thought to be lost from the solar system by grain-grain collisions. Here, we investigate the lifetime of cm-sized meteoroids from their abundance in meteoroid streams of different age. For 487 streams, we measured the orbital element dispersions, the magnitude size distribution index, the ratio of fluffy and dense materials in the stream and their bulk densities, and the meteor light curve shape-parameter. We find that older long-period comet meteoroid streams tend to be more dispersed and evolve towards smaller semi-major axis, higher magnitude size distribution index, and contain relatively more high-density material. Meteoroids that approach the Sun closer than 0.2–0.3 AU are mostly young and composed of denser materials poor in sodium. We compare the observed properties of the streams to age estimates from the literature and to a set of new age estimates for long-period comet streams based on observed dispersions. We find that streams broaden with age inversely proportional to the perihelion distance (q). By selecting narrow ranges of age, we find that their magnitude distribution index changes proportional to 1/√q, less steep than expected from meteoroid destruction by collisions. Instead, this shallow dependence suggests a lifetime inversely proportional to the peak grain temperature along its orbit, with the lifetime limited by thermal stresses if 0.3 < q < 1.02 AU and by sublimation if q < 0.2 AU.

Original language	English (US)
Article number	116034
Journal	Icarus
Volume	415
DOIs	https://doi.org/10.1016/j.icarus.2024.116034
State	Published - Jun 2024

Keywords

Comets, dust
Interplanetary dust
Interplanetary medium
Meteoroids
Meteors
Zodiacal light

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.1016/j.icarus.2024.116034

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Jenniskens, P., Pilorz, S., Gural, P. S., Samuels, D., Rau, S., Abbott, T. M. C., Albers, J., Austin, S., Avner, D., Baggaley, J. W., Beck, T., Blomquist, S., Boyukata, M., Breukers, M., Cooney, W., Cooper, T., De Cicco, M., Devillepoix, H., Egland, E., ... Lauretta, D. S. (2024). Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams. Icarus, 415, Article 116034. https://doi.org/10.1016/j.icarus.2024.116034

Jenniskens, P, Pilorz, S, Gural, PS, Samuels, D, Rau, S, Abbott, TMC, Albers, J, Austin, S, Avner, D, Baggaley, JW, Beck, T, Blomquist, S, Boyukata, M, Breukers, M, Cooney, W, Cooper, T, De Cicco, M, Devillepoix, H, Egland, E, Fahl, E, Gialluca, M, Grigsby, B, Hanke, T, Harris, B, Heathcote, S, Hemmelgarn, S, Howell, A, Jehin, E, Johannink, C, Juneau, L, Kisvarsanyi, E, Mey, P, Moskovitz, N, Odeh, M, Rachford, B, Rollinson, D, Scott, JM, Towner, MC, Unsalan, O, van Wyk, R, Wood, J, Wray, JD, Vaubaillon, J & Lauretta, DS 2024, 'Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams', Icarus, vol. 415, 116034. https://doi.org/10.1016/j.icarus.2024.116034

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title = "Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams",

abstract = "While comets eject mass mostly at cm-sizes and larger, that size range of particles is mostly absent from the interplanetary medium. Such particles are thought to be lost from the solar system by grain-grain collisions. Here, we investigate the lifetime of cm-sized meteoroids from their abundance in meteoroid streams of different age. For 487 streams, we measured the orbital element dispersions, the magnitude size distribution index, the ratio of fluffy and dense materials in the stream and their bulk densities, and the meteor light curve shape-parameter. We find that older long-period comet meteoroid streams tend to be more dispersed and evolve towards smaller semi-major axis, higher magnitude size distribution index, and contain relatively more high-density material. Meteoroids that approach the Sun closer than 0.2–0.3 AU are mostly young and composed of denser materials poor in sodium. We compare the observed properties of the streams to age estimates from the literature and to a set of new age estimates for long-period comet streams based on observed dispersions. We find that streams broaden with age inversely proportional to the perihelion distance (q). By selecting narrow ranges of age, we find that their magnitude distribution index changes proportional to 1/√q, less steep than expected from meteoroid destruction by collisions. Instead, this shallow dependence suggests a lifetime inversely proportional to the peak grain temperature along its orbit, with the lifetime limited by thermal stresses if 0.3 < q < 1.02 AU and by sublimation if q < 0.2 AU.",

keywords = "Comets, dust, Interplanetary dust, Interplanetary medium, Meteoroids, Meteors, Zodiacal light",

author = "Peter Jenniskens and Stuart Pilorz and Gural, {Peter S.} and Dave Samuels and Steve Rau and Abbott, {Timothy M.C.} and Jim Albers and Scott Austin and Dan Avner and Baggaley, {Jack W.} and Tim Beck and Solvay Blomquist and Mustafa Boyukata and Martin Breukers and Walt Cooney and Tim Cooper and {De Cicco}, Marcelo and Hadrien Devillepoix and Eric Egland and Elize Fahl and Megan Gialluca and Bryant Grigsby and Toni Hanke and Barbara Harris and Steve Heathcote and Samantha Hemmelgarn and Andy Howell and Emmanuel Jehin and Carl Johannink and Luke Juneau and Erika Kisvarsanyi and Philip Mey and Nick Moskovitz and Mohammad Odeh and Brian Rachford and David Rollinson and Scott, {James M.} and Towner, {Martin C.} and Ozan Unsalan and {van Wyk}, Rynault and Jeff Wood and Wray, {James D.} and J{\'e}r{\'e}mie Vaubaillon and Lauretta, {Dante S.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors",

year = "2024",

month = jun,

doi = "10.1016/j.icarus.2024.116034",

language = "English (US)",

volume = "415",

journal = "Icarus",

issn = "0019-1035",

publisher = "Academic Press Inc.",

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TY - JOUR

T1 - Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams

AU - Jenniskens, Peter

AU - Pilorz, Stuart

AU - Gural, Peter S.

AU - Samuels, Dave

AU - Rau, Steve

AU - Abbott, Timothy M.C.

AU - Albers, Jim

AU - Austin, Scott

AU - Avner, Dan

AU - Baggaley, Jack W.

AU - Beck, Tim

AU - Blomquist, Solvay

AU - Boyukata, Mustafa

AU - Breukers, Martin

AU - Cooney, Walt

AU - Cooper, Tim

AU - De Cicco, Marcelo

AU - Devillepoix, Hadrien

AU - Egland, Eric

AU - Fahl, Elize

AU - Gialluca, Megan

AU - Grigsby, Bryant

AU - Hanke, Toni

AU - Harris, Barbara

AU - Heathcote, Steve

AU - Hemmelgarn, Samantha

AU - Howell, Andy

AU - Jehin, Emmanuel

AU - Johannink, Carl

AU - Juneau, Luke

AU - Kisvarsanyi, Erika

AU - Mey, Philip

AU - Moskovitz, Nick

AU - Odeh, Mohammad

AU - Rachford, Brian

AU - Rollinson, David

AU - Scott, James M.

AU - Towner, Martin C.

AU - Unsalan, Ozan

AU - van Wyk, Rynault

AU - Wood, Jeff

AU - Wray, James D.

AU - Vaubaillon, Jérémie

AU - Lauretta, Dante S.

PY - 2024/6

Y1 - 2024/6

N2 - While comets eject mass mostly at cm-sizes and larger, that size range of particles is mostly absent from the interplanetary medium. Such particles are thought to be lost from the solar system by grain-grain collisions. Here, we investigate the lifetime of cm-sized meteoroids from their abundance in meteoroid streams of different age. For 487 streams, we measured the orbital element dispersions, the magnitude size distribution index, the ratio of fluffy and dense materials in the stream and their bulk densities, and the meteor light curve shape-parameter. We find that older long-period comet meteoroid streams tend to be more dispersed and evolve towards smaller semi-major axis, higher magnitude size distribution index, and contain relatively more high-density material. Meteoroids that approach the Sun closer than 0.2–0.3 AU are mostly young and composed of denser materials poor in sodium. We compare the observed properties of the streams to age estimates from the literature and to a set of new age estimates for long-period comet streams based on observed dispersions. We find that streams broaden with age inversely proportional to the perihelion distance (q). By selecting narrow ranges of age, we find that their magnitude distribution index changes proportional to 1/√q, less steep than expected from meteoroid destruction by collisions. Instead, this shallow dependence suggests a lifetime inversely proportional to the peak grain temperature along its orbit, with the lifetime limited by thermal stresses if 0.3 < q < 1.02 AU and by sublimation if q < 0.2 AU.

AB - While comets eject mass mostly at cm-sizes and larger, that size range of particles is mostly absent from the interplanetary medium. Such particles are thought to be lost from the solar system by grain-grain collisions. Here, we investigate the lifetime of cm-sized meteoroids from their abundance in meteoroid streams of different age. For 487 streams, we measured the orbital element dispersions, the magnitude size distribution index, the ratio of fluffy and dense materials in the stream and their bulk densities, and the meteor light curve shape-parameter. We find that older long-period comet meteoroid streams tend to be more dispersed and evolve towards smaller semi-major axis, higher magnitude size distribution index, and contain relatively more high-density material. Meteoroids that approach the Sun closer than 0.2–0.3 AU are mostly young and composed of denser materials poor in sodium. We compare the observed properties of the streams to age estimates from the literature and to a set of new age estimates for long-period comet streams based on observed dispersions. We find that streams broaden with age inversely proportional to the perihelion distance (q). By selecting narrow ranges of age, we find that their magnitude distribution index changes proportional to 1/√q, less steep than expected from meteoroid destruction by collisions. Instead, this shallow dependence suggests a lifetime inversely proportional to the peak grain temperature along its orbit, with the lifetime limited by thermal stresses if 0.3 < q < 1.02 AU and by sublimation if q < 0.2 AU.

KW - Comets, dust

KW - Interplanetary dust

KW - Interplanetary medium

KW - Meteoroids

KW - Meteors

KW - Zodiacal light

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UR - http://www.scopus.com/inward/citedby.url?scp=85188446930&partnerID=8YFLogxK

U2 - 10.1016/j.icarus.2024.116034

DO - 10.1016/j.icarus.2024.116034

M3 - Article

AN - SCOPUS:85188446930

SN - 0019-1035

VL - 415

JO - Icarus

JF - Icarus

M1 - 116034

ER -

Lifetime of cm-sized zodiacal dust from the physical and dynamical evolution of meteoroid streams

Abstract

Keywords

ASJC Scopus subject areas

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