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10Be in Polar Ice and Atmospheres

Published online by Cambridge University Press:  20 January 2017

G.M. Raisbeck
Affiliation:
Laboratoire René Bernas, Bat. 108, 91406 Orsay, France
F. Yiou
Affiliation:
Laboratoire René Bernas, Bat. 108, 91406 Orsay, France
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Abstract

We briefly review the application of cosmogenic 10Be measurements in ice and polar atmospheres to: (i) the dating of ice cores, (ii) the deduction of past accumulation rates, (iii) information on the influx of stratospheric aerosols in polar regions, and the mechanism of incorporation of aerosols into the ice. We find that at high latitudes (>74°), the 10Be deposition rate in the ice is more constant than the 10Be concentration.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1985

Introduction

The cosmogenic isotope 10Be (half–life 1.5 Ma) is formed by cosmic-ray interactions in the Earth’s atmosphere. 10Be atoms quickly become associated with aerosol particles, and are deposited at the Earth’s surface by precipitation and dry fallout, with residence times similar to these aerosols. 10Be then accumulates in various geological reservoirs, such as polar ice, and marine and lacustrine sediments. The technique of accelerator mass spectrometry (Reference Raisbeck, Yiou, Fruneau and LoiseauxRaisbeck and others 1978) now makes it possible to measure this isotope in samples of reasonable sizes (<10 m3 stratospheric air, <103 m3 tropospheric air, <1 g of sediments, <1 kg of ice).

Such measurements can give information on past rates of production of 10Be, and thus on the factors which influence this production, namely primary cosmic-ray flux, solar activity, and geomagnetic field intensity. Secondly, the study of l0Be, either alone or in conjunction with other cosmogenic isotopes, can give information, such as origin, age, transport mechanism, etc., on the reservoir material in which it is measured (Reference Raisbeck and YiouRaisbeck and Yiou 1984). It is this latter aspect, with particular reference to polar atmospheres and ice, that we briefly review here.

Ice-Core Dating

Perhaps the most obvious potential application of radioactive cosmogenic isotopes in polar ice is that of dating the ice. Indeed, for a number of years it has been proposed that the measurements of 14C in CO2 trapped in the ice might serve such a purpose. It now appears that accelerator mass spectrometry will make such measurements feasible in the near future (Reference AndréeAndrée and others 1984). However, a polar ice sample of 55 ka will contain only ~1 atom of 14C per gram of ice. Thus, even with the accelerator technique, ice of this age and older will pose a serious problem for 14C dating. Fortunately there are other longer–lived cosmogenic isotopes which can overcome this difficulty.

Unlike 14C, however, most of these other cosmogenic species are not in equilibrium with their stable isotopes in the environment. Thus, in order to use them it is desirable to measure a pair of these isotopes having different half-lives. Such a procedure has the further advantage that it will minimize the effects of production variations due to the causes mentioned earlier. For ice older than 50 ka the most useful of these isotope pairs is probably 36Cl/10Be, which has an “effective” half-life of 370 ka. For even older ice (if it is ever recovered) it would also be possible to use 26A1/10Be (effective half-life 1.4 Ma). For young ice 14C dating is also limited because of the uncertain and variable time for “close-off” of the ice bubbles to the atmosphere. Here the ratio 32Si/10Be (effective half-life ~110 a) should be useful. It should be mentioned that polar ice (at least in regions where it never melts) is a particularly attractive reservoir for such dating, because there is little probability that there will be “fractionation” of the different isotopes in the reservoir.

Past Accumulation Rates

Reference Paterson and WaddingtonPaterson and Waddington (1984) have recently emphasized that even an accurately dated ice core will not necessarily permit a calculation of past precipitation rates, because of limitations caused by the assumptions made when modelling the thinning of the ice during burial. They have also pointed out that the measurement of 10Be in such ice might provide one of the few ways of avoiding such problems (since the concentration of the 10Be is not affected by thinning). Indeed, our earliest measurements of an increase in the 10Be concentration, in ice of the last glacial period at Dome C, Antarctica, led us to suggest that the most probable cause was a decreased precipitation rate during this time (Reference RaisbeckRaisbeck and others 1981[a]). More recent measurements in a core at Vostok station have reinforced our belief in such an interpretation (Reference Yiou, Raisbeck, Bourles, Lorius and BarkovYiou and others in press) A collaboration between research groups in Bern and Zurich has found similar evidence for ice at Dye 3 in Greenland (Reference BeerBeer and others 1983[a]). Interestingly, we have not found this increase in Wisconsin ice at the Agassiz Ice Cap on Ellesmere Island (unpublished). Whether this is due to our limited sampling, more complicated ice flow, or actually reflects a real precipitation difference at this site, is not yet clear.

In order to use 10Be to deduce past precipitation rates in this way, it is necessary to take into consideration effects due to possible changes in production rate or in atmospheric circulation. As pointed out by Reference Paterson and WaddingtonPaterson and Waddington (1984), it may be possible to use data from one polar site, where the modelling parameters or experimental information are favourable, to monitor 10Be changes, and thus deduce accumulation changes at less favourable sites. In cases where the ice is from a site away from an ice ridge it will also be necessary to take into consideration a possible difference in the 10Be concentration at the location of the original precipitation (see below).

Atmosphere-Ice Transfer Functions

One of the main objectives in studying ice cores is to obtain information about past environmental conditions. To do this, one needs to be able to “translate” the ice-derived data. Since 10Be has been formed continuously in the past, in a fairly well-defined way, it can be used as a sort of reference when interpreting deposition mechanisms of certain other components in the ice, and their variations. As an example of such a procedure, we show in Table I our available data on contemporary average 10Be concentrations in ice as a function of precipitation rate at three locations on the Antarctic plateau (Dome C, South Pole and Vostok). We stress that for the latter two sites the results represent relatively few measurements, and are thus subject to improvement in the future. The most obvious observation that can be made from Table I is that there is apparently an inverse correlation of 10Be concentration with precipitation rate. This is in contrast with observations involving cosmogenic and bomb-produced radioactive isotopes in precipitation in many locations, where the concentration is relatively independent of the precipitation rate for a given latitude (Reference Lai, Peters and FlüggeLai and Peters 1967). In the present case it is the deposition rate of 10Be which is most nearly constant.

Table I 10Be in Polar Ice

One can think of at least two possible explanations for this peculiar situation in the polar regions. One is that, because of a small stratospheric component (see below), most of the 10Be deposition takes place near the site of its formation in the troposphere. A second explanation would be that a large fraction of the 10Be on the Antarctic plateau is deposited as dry fallout. In the limit of total deposition by this mechanism, it is obvious that the 10Be concentration will be inversely proportional to the precipitation rate. Using nuclear bomb-produced fallout, Reference Pourchet, Pinglot and LoriusPourchet and others (1983) have previously suggested that dry deposition accounts for as much as 60% of total deposition in central Antarctica. To account for our results by this mechanism would require an even larger fraction for l0Be.

We have also included in Table I results of 10Be deposition at the Agassiz Ice Cap on Ellesmere Island, and Camp Century, Greenland, two high-latitude sites in the Arctic. Once again it can be seen that deposition rather than concentration appears most constant, and even the absolute deposition rates are surprisingly similar to the Antarctic ones. In fact between Vostok and Camp Century there is more than an order-of-magnitude difference in precipitation rate, but approximately only a 25% difference in the 10Be deposition rate. At two other Greenland sites included in Table I (Dye 3 and Milcent) the l0Be deposition rates are larger. We feel that this may reflect a greater stratospheric input at these lower-latitude sites, as predicted by the deposition curve of Reference Lai, Peters and FlüggeLai and Peters (1967).

We can now use the above data to try to estimate the influx of stratospheric aerosols to the ice caps. Let us for the moment ignore tropospheric production, and assume that all the 10Be in the ice cores comes from the stratosphere. We thus have

(1)

where D is the 10Be deposition rate, F the influx of stratospheric air , and S the concentration of 10Be in the polar stratosphere. We have measured 10Be in 12 high-latitude (58° to 75°) stratospheric air filters (Reference Raisbeck, Yiou, Fruneau, Loiseaux, Lieuvin and RavelRaisbeck and others 1981[b], and unpublished) and find values ranging from 6.6 to 12.3×106 atoms SCM−1, If we adopt a value of 9×106 atoms SCM−1 (=7×103 atoms g−1) for S, and 2.2×105 atoms cm−2 a−1 for D, we get F ~ 30 g cm−2 a−1. Since the total mass of stratospheric air in the polar regions is ~300 g cm”, we see that only a very small fraction of stratospheric aerosols are input directly to the ice. Even allowing for a larger 10Be deposition rate in Antarctic coastal regions, the above results would seem to be incompatible with the massive (5 to 6 g cm−2 d−1) stratospheric influx rates suggested by Reference SanakSanak (unpublished) for certain periods at Dumont d'Urville, Antarctica.

Even the stratospheric influx calculated above is clearly an upper limit, however, since we have ignored the 10Be produced in the troposphere. The estimate of this contribution is complicated by the fact that there is still an uncertainty in the total 10Be production rate, with estimates ranging from 1.8 to 4.2×10−2 atoms cm−2 s−1 (Reference Raisbeck, Yiou, Fruneau, Loiseaux, Lieuvin and RavelRaisbeck and others 1979). Using the relationship of Reference Lai, Peters and FlüggeLai and Peters (1967), these give a troposphere production rate in the polar regions of ~1.4 to 3.3×105 atoms cm−2 a−1, respectively. Thus we find that tropospheric production can account for anywhere from 60% to essentially all of the 10Be deposition rates observed on the Antarctic plateau and high Arctic sites of Table I. We thus conclude that only a very small fraction of stratospheric aerosols are deposited in these regions (<15% of the global average rate). It will be interesting to see whether a similar distribution occurred in pre-Holocene climates. This information can then be used to help interpret ice-core data of other stratospherically transported species (volcanic emissions, trace metals, dust, etc.).

If the above interpretation is correct, it will also influence the analysis of ice cores as records of 10Be production variations. For example, Reference BeerBeer and others (1984) have interpreted the absence of 10Be variations in the Camp Century ice core during the last 5000 a as evidence that the geomagnetic dipole has not varied significantly in intensity over this period. However, the production variations due to geomagnetic field variations are most pronounced in the equatorial regions, and will only be reflected in polar ice by the input of stratospheric air from these equatorial latitudes. Thus the absence of a geomagnetic signal in the Camp Century ice may simply reflect a small stratospheric component in this ice.

Conclusions

The technique of accelerator mass spectrometry permits greatly expanded applications of 10Be and other long-lived cosmogenic nuclides. We have tried above to outline several ways in which such studies can contribute to an improved understanding of present-day incorporation of atmospheric species into polar ice, and to improved interpretation of polar ice records as indicators of past environments. It appears that at latitudes above 74° there is a very small stratospheric influx of aerosols, and that the 10Be deposition rate is much more constant than 10Be concentration.

Acknowledgements

We thank C Lorius, M Pourchet, R M Koerner, D A Fisher, B C Parker and E J Zeller for making ice samples available. Many of the 10Be measurements cited here have been made in collaboration with J M Loiseaux and M Lieuvin at the Grenoble cyclotron, and J Klein and R Middleton at the University of Pennsylvania tandem accelerator. We also thank J Lestringuez for help in preparing samples.

References

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Figure 0

Table I 10Be in Polar Ice