Exposure history of the Peekskill (H6) meteorite

Th Graf; K. Marti; S. Xue; G. F. Herzog; J. Klein; R. Middleton; K. Metzler; R. Herd; P. Brown; J. F. Wacker; A. J.T. Jull; J. Masarik; V. T. Koslowsky; H. R. Andrews; R. J.J. Cornett; W. G. Davies; B. F. Greiner; Y. Imahori; J. W. Mckay; G. M. Milton; J. C.D. Milton

doi:10.1111/j.1945-5100.1997.tb01237.x

Exposure history of the Peekskill (H6) meteorite

Th Graf, K. Marti, S. Xue, G. F. Herzog, J. Klein, R. Middleton, K. Metzler, R. Herd, P. Brown, J. F. Wacker, A. J.T. Jull, J. Masarik, V. T. Koslowsky, H. R. Andrews, R. J.J. Cornett, W. G. Davies, B. F. Greiner, Y. Imahori, J. W. Mckay, G. M. MiltonJ. C.D. Milton

School of Arts and Sciences, Chemistry & Chemical Biology

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

16 Scopus citations

Abstract

The Peekskill H6 meteorite fell on 1992 October 9. We report extensive measurements of cosmic-ray produced stable nuclides of He, Ne, and Ar, of the radionuclides ²²Na, ⁶⁰Co, ¹⁴C, ³⁶Cl, ²⁶Al, and ¹⁰Be, and of cosmic-ray track densities. After correction for shielding via the ²²Ne/²¹Ne ratio, the concentrations of cosmic-ray produced ³He, ²¹Ne and ³⁸Ar give an average exposure age of 25 Ma, which is considered to be a lower limit on the true value. The ¹⁰Be/²¹Ne age is 32 Ma and falls onto a peak in the H-chondrite exposure age distribution. The activities of ²⁶Al, ¹⁴C, ³⁶Cl, and ¹⁰Be are all close to the maximum values expected for H-chondrites. Together with cosmic-ray track densities and the ²²Ne/²¹Ne ratio, these radionuclide data place the samples at a depth >20 cm in a meteoroid with a radius >40 cm. In contrast, the ⁶⁰Co activity requires a near-surface location and/or a much smaller body. Calculations show that a flattened geometry for the Peekskill meteoroid does not explain the observations in the context of a one-stage irradiation. A two-stage model can account for the data. We estimate an upper bound of 70 cm on the radius of the earlier stage of irradiation and conclude that Peekskill's radius was <70 cm when it entered the Earth's atmosphere. This size limit is somewhat smaller than the dynamic determinations (Brown et al., 1994).

Original language	English (US)
Pages (from-to)	25-30
Number of pages	6
Journal	Meteoritics and Planetary Science
Volume	32
Issue number	1
DOIs	https://doi.org/10.1111/j.1945-5100.1997.tb01237.x
State	Published - Jan 1997

All Science Journal Classification (ASJC) codes

Geophysics
Space and Planetary Science

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10.1111/j.1945-5100.1997.tb01237.x

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Graf, T., Marti, K., Xue, S., Herzog, G. F., Klein, J., Middleton, R., Metzler, K., Herd, R., Brown, P., Wacker, J. F., Jull, A. J. T., Masarik, J., Koslowsky, V. T., Andrews, H. R., Cornett, R. J. J., Davies, W. G., Greiner, B. F., Imahori, Y., Mckay, J. W., ... Milton, J. C. D. (1997). Exposure history of the Peekskill (H6) meteorite. Meteoritics and Planetary Science, 32(1), 25-30. https://doi.org/10.1111/j.1945-5100.1997.tb01237.x

@article{b6913a65c02e45a8b56251691635f11f,

title = "Exposure history of the Peekskill (H6) meteorite",

abstract = "The Peekskill H6 meteorite fell on 1992 October 9. We report extensive measurements of cosmic-ray produced stable nuclides of He, Ne, and Ar, of the radionuclides 22Na, 60Co, 14C, 36Cl, 26Al, and 10Be, and of cosmic-ray track densities. After correction for shielding via the 22Ne/21Ne ratio, the concentrations of cosmic-ray produced 3He, 21Ne and 38Ar give an average exposure age of 25 Ma, which is considered to be a lower limit on the true value. The 10Be/21Ne age is 32 Ma and falls onto a peak in the H-chondrite exposure age distribution. The activities of 26Al, 14C, 36Cl, and 10Be are all close to the maximum values expected for H-chondrites. Together with cosmic-ray track densities and the 22Ne/21Ne ratio, these radionuclide data place the samples at a depth >20 cm in a meteoroid with a radius >40 cm. In contrast, the 60Co activity requires a near-surface location and/or a much smaller body. Calculations show that a flattened geometry for the Peekskill meteoroid does not explain the observations in the context of a one-stage irradiation. A two-stage model can account for the data. We estimate an upper bound of 70 cm on the radius of the earlier stage of irradiation and conclude that Peekskill's radius was <70 cm when it entered the Earth's atmosphere. This size limit is somewhat smaller than the dynamic determinations (Brown et al., 1994).",

author = "Th Graf and K. Marti and S. Xue and Herzog, {G. F.} and J. Klein and R. Middleton and K. Metzler and R. Herd and P. Brown and Wacker, {J. F.} and Jull, {A. J.T.} and J. Masarik and Koslowsky, {V. T.} and Andrews, {H. R.} and Cornett, {R. J.J.} and Davies, {W. G.} and Greiner, {B. F.} and Y. Imahori and Mckay, {J. W.} and Milton, {G. M.} and Milton, {J. C.D.}",

year = "1997",

month = jan,

doi = "10.1111/j.1945-5100.1997.tb01237.x",

language = "English (US)",

volume = "32",

pages = "25--30",

journal = "Meteoritics and Planetary Science",

issn = "1086-9379",

publisher = "The University of Arkansas Press",

number = "1",

}

Graf, T, Marti, K, Xue, S, Herzog, GF, Klein, J, Middleton, R, Metzler, K, Herd, R, Brown, P, Wacker, JF, Jull, AJT, Masarik, J, Koslowsky, VT, Andrews, HR, Cornett, RJJ, Davies, WG, Greiner, BF, Imahori, Y, Mckay, JW, Milton, GM & Milton, JCD 1997, 'Exposure history of the Peekskill (H6) meteorite', Meteoritics and Planetary Science, vol. 32, no. 1, pp. 25-30. https://doi.org/10.1111/j.1945-5100.1997.tb01237.x

TY - JOUR

T1 - Exposure history of the Peekskill (H6) meteorite

AU - Graf, Th

AU - Marti, K.

AU - Xue, S.

AU - Herzog, G. F.

AU - Klein, J.

AU - Middleton, R.

AU - Metzler, K.

AU - Herd, R.

AU - Brown, P.

AU - Wacker, J. F.

AU - Jull, A. J.T.

AU - Masarik, J.

AU - Koslowsky, V. T.

AU - Andrews, H. R.

AU - Cornett, R. J.J.

AU - Davies, W. G.

AU - Greiner, B. F.

AU - Imahori, Y.

AU - Mckay, J. W.

AU - Milton, G. M.

AU - Milton, J. C.D.

PY - 1997/1

Y1 - 1997/1

N2 - The Peekskill H6 meteorite fell on 1992 October 9. We report extensive measurements of cosmic-ray produced stable nuclides of He, Ne, and Ar, of the radionuclides 22Na, 60Co, 14C, 36Cl, 26Al, and 10Be, and of cosmic-ray track densities. After correction for shielding via the 22Ne/21Ne ratio, the concentrations of cosmic-ray produced 3He, 21Ne and 38Ar give an average exposure age of 25 Ma, which is considered to be a lower limit on the true value. The 10Be/21Ne age is 32 Ma and falls onto a peak in the H-chondrite exposure age distribution. The activities of 26Al, 14C, 36Cl, and 10Be are all close to the maximum values expected for H-chondrites. Together with cosmic-ray track densities and the 22Ne/21Ne ratio, these radionuclide data place the samples at a depth >20 cm in a meteoroid with a radius >40 cm. In contrast, the 60Co activity requires a near-surface location and/or a much smaller body. Calculations show that a flattened geometry for the Peekskill meteoroid does not explain the observations in the context of a one-stage irradiation. A two-stage model can account for the data. We estimate an upper bound of 70 cm on the radius of the earlier stage of irradiation and conclude that Peekskill's radius was <70 cm when it entered the Earth's atmosphere. This size limit is somewhat smaller than the dynamic determinations (Brown et al., 1994).

AB - The Peekskill H6 meteorite fell on 1992 October 9. We report extensive measurements of cosmic-ray produced stable nuclides of He, Ne, and Ar, of the radionuclides 22Na, 60Co, 14C, 36Cl, 26Al, and 10Be, and of cosmic-ray track densities. After correction for shielding via the 22Ne/21Ne ratio, the concentrations of cosmic-ray produced 3He, 21Ne and 38Ar give an average exposure age of 25 Ma, which is considered to be a lower limit on the true value. The 10Be/21Ne age is 32 Ma and falls onto a peak in the H-chondrite exposure age distribution. The activities of 26Al, 14C, 36Cl, and 10Be are all close to the maximum values expected for H-chondrites. Together with cosmic-ray track densities and the 22Ne/21Ne ratio, these radionuclide data place the samples at a depth >20 cm in a meteoroid with a radius >40 cm. In contrast, the 60Co activity requires a near-surface location and/or a much smaller body. Calculations show that a flattened geometry for the Peekskill meteoroid does not explain the observations in the context of a one-stage irradiation. A two-stage model can account for the data. We estimate an upper bound of 70 cm on the radius of the earlier stage of irradiation and conclude that Peekskill's radius was <70 cm when it entered the Earth's atmosphere. This size limit is somewhat smaller than the dynamic determinations (Brown et al., 1994).

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U2 - 10.1111/j.1945-5100.1997.tb01237.x

DO - 10.1111/j.1945-5100.1997.tb01237.x

M3 - Article

AN - SCOPUS:0030844465

SN - 1086-9379

VL - 32

SP - 25

EP - 30

JO - Meteoritics and Planetary Science

JF - Meteoritics and Planetary Science

IS - 1

ER -

Exposure history of the Peekskill (H6) meteorite

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