Evidence for large century time-scale changes in solar activity in the past 32 Kyr, based on in-situ cosmogenic 14C in ice at Summit, Greenland

Devendra Lal, A. J.T. Jull, David Pollard, Loic Vacher

Research output: Contribution to journalArticle

25 Citations (Scopus)

Abstract

We present results of estimates of cosmic ray flux in Greenland at the Summit (3200 m.a.s.l, 72.6°N, 38.5°W), during the past 32 Kyr. We derive these estimates based on concentrations of in-situ cosmogenic 14C produced in ice crystals. Based on the secular equilibrium concentration of in-situ produced 14C in quartz in terrestrial rocks, we find that on century time-scales, the cosmic ray production rate of 14C at the Summit was close to its estimated long-term average production rate, except during 3 periods: (i) during 8500-9500 yr B.P. and 27,000-32,000 yr B.P, when the production rate was higher by about a factor of 2, and (ii) during 12,000-16,000 yr B.P, when the production rate was lower by a factor of 1.5. The observed variation in cosmic ray flux at the polar site is best attributed to changes in solar activity resulting in variable modulation of terrestrial cosmic ray flux. Changes in the geomagnetic field in the past do not affect the cosmic ray flux at polar latitudes. Likewise, climate changes do not affect the in-situ 14C record in ice. During the first two epochs, the solar activity must have been very low, as during Maunder Minimum (virtually no sunspots), resulting in essentially no modulation of the cosmic ray flux by the solar plasma. During the low cosmic ray flux epoch, 12,000-16,000 yr B.P., the observed decrease in cosmic ray flux corresponds to high solar activity as seen in 1958 (sun-spot number ∼ 190). We discuss the proxy evidence from tree ring and sediment based records of atmospheric 14C/12C ratios during the three epochs. These records have been used as a measure of changes in cosmic ray flux, and solar activity in the past. However, since they are also appreciably affected by climatic changes, a comparison of the two records is potentially valuable for delineating the nature of past changes in solar activity, and large-scale ocean circulation and air-sea exchange.

Original languageEnglish (US)
Pages (from-to)335-349
Number of pages15
JournalEarth and Planetary Science Letters
Volume234
Issue number3-4
DOIs
StatePublished - Jun 15 2005

Fingerprint

Cosmic rays
Greenland
Ice
solar activity
cosmic ray
cosmic rays
ice
timescale
Fluxes
time measurement
Modulation
Maunder Minimum
in situ
modulation
climate change
Quartz
ice crystal
geomagnetism
estimates
sunspots

All Science Journal Classification (ASJC) codes

  • Geophysics
  • Geochemistry and Petrology
  • Earth and Planetary Sciences (miscellaneous)
  • Space and Planetary Science

Cite this

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title = "Evidence for large century time-scale changes in solar activity in the past 32 Kyr, based on in-situ cosmogenic 14C in ice at Summit, Greenland",
abstract = "We present results of estimates of cosmic ray flux in Greenland at the Summit (3200 m.a.s.l, 72.6°N, 38.5°W), during the past 32 Kyr. We derive these estimates based on concentrations of in-situ cosmogenic 14C produced in ice crystals. Based on the secular equilibrium concentration of in-situ produced 14C in quartz in terrestrial rocks, we find that on century time-scales, the cosmic ray production rate of 14C at the Summit was close to its estimated long-term average production rate, except during 3 periods: (i) during 8500-9500 yr B.P. and 27,000-32,000 yr B.P, when the production rate was higher by about a factor of 2, and (ii) during 12,000-16,000 yr B.P, when the production rate was lower by a factor of 1.5. The observed variation in cosmic ray flux at the polar site is best attributed to changes in solar activity resulting in variable modulation of terrestrial cosmic ray flux. Changes in the geomagnetic field in the past do not affect the cosmic ray flux at polar latitudes. Likewise, climate changes do not affect the in-situ 14C record in ice. During the first two epochs, the solar activity must have been very low, as during Maunder Minimum (virtually no sunspots), resulting in essentially no modulation of the cosmic ray flux by the solar plasma. During the low cosmic ray flux epoch, 12,000-16,000 yr B.P., the observed decrease in cosmic ray flux corresponds to high solar activity as seen in 1958 (sun-spot number ∼ 190). We discuss the proxy evidence from tree ring and sediment based records of atmospheric 14C/12C ratios during the three epochs. These records have been used as a measure of changes in cosmic ray flux, and solar activity in the past. However, since they are also appreciably affected by climatic changes, a comparison of the two records is potentially valuable for delineating the nature of past changes in solar activity, and large-scale ocean circulation and air-sea exchange.",
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Evidence for large century time-scale changes in solar activity in the past 32 Kyr, based on in-situ cosmogenic 14C in ice at Summit, Greenland. / Lal, Devendra; Jull, A. J.T.; Pollard, David; Vacher, Loic.

In: Earth and Planetary Science Letters, Vol. 234, No. 3-4, 15.06.2005, p. 335-349.

Research output: Contribution to journalArticle

TY - JOUR

T1 - Evidence for large century time-scale changes in solar activity in the past 32 Kyr, based on in-situ cosmogenic 14C in ice at Summit, Greenland

AU - Lal, Devendra

AU - Jull, A. J.T.

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N2 - We present results of estimates of cosmic ray flux in Greenland at the Summit (3200 m.a.s.l, 72.6°N, 38.5°W), during the past 32 Kyr. We derive these estimates based on concentrations of in-situ cosmogenic 14C produced in ice crystals. Based on the secular equilibrium concentration of in-situ produced 14C in quartz in terrestrial rocks, we find that on century time-scales, the cosmic ray production rate of 14C at the Summit was close to its estimated long-term average production rate, except during 3 periods: (i) during 8500-9500 yr B.P. and 27,000-32,000 yr B.P, when the production rate was higher by about a factor of 2, and (ii) during 12,000-16,000 yr B.P, when the production rate was lower by a factor of 1.5. The observed variation in cosmic ray flux at the polar site is best attributed to changes in solar activity resulting in variable modulation of terrestrial cosmic ray flux. Changes in the geomagnetic field in the past do not affect the cosmic ray flux at polar latitudes. Likewise, climate changes do not affect the in-situ 14C record in ice. During the first two epochs, the solar activity must have been very low, as during Maunder Minimum (virtually no sunspots), resulting in essentially no modulation of the cosmic ray flux by the solar plasma. During the low cosmic ray flux epoch, 12,000-16,000 yr B.P., the observed decrease in cosmic ray flux corresponds to high solar activity as seen in 1958 (sun-spot number ∼ 190). We discuss the proxy evidence from tree ring and sediment based records of atmospheric 14C/12C ratios during the three epochs. These records have been used as a measure of changes in cosmic ray flux, and solar activity in the past. However, since they are also appreciably affected by climatic changes, a comparison of the two records is potentially valuable for delineating the nature of past changes in solar activity, and large-scale ocean circulation and air-sea exchange.

AB - We present results of estimates of cosmic ray flux in Greenland at the Summit (3200 m.a.s.l, 72.6°N, 38.5°W), during the past 32 Kyr. We derive these estimates based on concentrations of in-situ cosmogenic 14C produced in ice crystals. Based on the secular equilibrium concentration of in-situ produced 14C in quartz in terrestrial rocks, we find that on century time-scales, the cosmic ray production rate of 14C at the Summit was close to its estimated long-term average production rate, except during 3 periods: (i) during 8500-9500 yr B.P. and 27,000-32,000 yr B.P, when the production rate was higher by about a factor of 2, and (ii) during 12,000-16,000 yr B.P, when the production rate was lower by a factor of 1.5. The observed variation in cosmic ray flux at the polar site is best attributed to changes in solar activity resulting in variable modulation of terrestrial cosmic ray flux. Changes in the geomagnetic field in the past do not affect the cosmic ray flux at polar latitudes. Likewise, climate changes do not affect the in-situ 14C record in ice. During the first two epochs, the solar activity must have been very low, as during Maunder Minimum (virtually no sunspots), resulting in essentially no modulation of the cosmic ray flux by the solar plasma. During the low cosmic ray flux epoch, 12,000-16,000 yr B.P., the observed decrease in cosmic ray flux corresponds to high solar activity as seen in 1958 (sun-spot number ∼ 190). We discuss the proxy evidence from tree ring and sediment based records of atmospheric 14C/12C ratios during the three epochs. These records have been used as a measure of changes in cosmic ray flux, and solar activity in the past. However, since they are also appreciably affected by climatic changes, a comparison of the two records is potentially valuable for delineating the nature of past changes in solar activity, and large-scale ocean circulation and air-sea exchange.

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