Artigo Acesso aberto Revisado por pares

The Dilemma of the Rapid Variations in CO2 in Greenland Ice Cores (Abstract)

1988; Cambridge University Press; Volume: 10; Linguagem: Inglês

10.1017/s0260305500004626

ISSN

1727-5644

Autores

H. Oeschger, A. Neftel, T. Staffelbach, B. Stauffer,

Tópico(s)

Atmospheric chemistry and aerosols

Resumo

Stauffer and others (1984) observed in the Greenland ice core from Dye 3 CO 2 variations between low values in the range of 180-200 ppm volume and higher values in the range of 240-260 ppm volume, over a period tentatively dated to 30 000-40 000 years B.P. The low values are observed in samples with low δ 18 O, high particle and chemical impurity contents, representing precipitation from periods of cold climate; the higher CO 2 concentrations are measured in samples which reflect warm climatic conditions because of their high δ 18 O and low impurity contents. The change from one climatic state to the other seems to occur within less than a century. This unexpected observation has received considerable attention from the scientific community. First, the question was posed whether the rapid CO 2 variations do indeed reflect atmospheric CO 2 -concentration changes or whether they are caused by the interaction of gases with chemical constituents in the ice matrix. Secondly, carbon-cycle modellers searched for a mechanism in the carbon system which could produce such rapid changes in atmospheric CO 2 . Here we try to answer the first question. Arguments in favour of an atmospheric origin of the CO 2 variations are: CO 2 measurements on an ice core from Siple Station, Antarctica, show a monotonous increase over the past 250 years, from values around 280 ppm volume to values overlapping closely with the direct atmospheric data which have been obtained since 1958 (Neftel and others 1985). Thus a consistent picture of the anthropogenic CO 2 increase has been obtained which is compatible with estimates of the man-made CO 2 emissions and with the carbon-cycle calculations of the airborne fraction of these emissions. In addition, convincing CO 2 -concentration data have been obtained, from two ice cores from Greenland and four ice cores from Antarctica, for the transition from low (180-200 ppm volume) late-Wisconsin values to the higher (260-300 ppm volume) Holocene values. In spite of considerable differences in temperature, fabrics and chemical properties, the Wisconsin CO 2 -concentration values for ice cores from different locations lie in a narrow band. The Holocene values show a greater scatter; in particular, the values obtained for the Dye 3 core are significantly higher than those for the other cores. This can be explained by a relatively high temperature, which leads to melting in summer. In refrozen melt layers, CO 2 is enriched in comparison with the other air gases. On the basis of these observations we conclude that melt layers are the main factor which can lead to considerable deviations in the CO 2 concentration of the air occluded in ice cores from that of the atmosphere at ice formation. To test if the melt-layer effect was the cause of the rapid changes in CO 2 concentration which were observed in the Dye 3 core, increments of the Camp Century core from north Greenland were measured for CO 2 ; they show similarly rapid Wisconsin δ 18 O and CO 2 changes, though they are less abrupt than in the Dye 3 core. At Camp Century the present mean annual temperature is 4.5 °C lower than at Dye 3, and during the Wisconsin the temperature difference was even greater, as indicated by the δ 18 O values. Because even for Holocene ice in the Camp Century core the melt-layer effect on the CO 2 concentration is relatively small, we exclude any similar significant effect on the Wisconsin ice. On the basis of the Greenland ice-core information alone, therefore, we have no indication that the rapid Wisconsin CO 2 variations do not represent an atmospheric phenomenon. Arguments against an atmospheric origin for the rapid CO 2 variations stem from detailed analyses of the ice core from Byrd Station, Antarctica. Observation of the increase in anthropogenic atmospheric CO 2 in both hemispheres indicates that within a few years CO 2 becomes well mixed throughout the atmosphere. Thus the CO 2 variations observed in the Greenland core should also appear in the Antarctic core increments which represent corresponding periods. A thorough CO 2 study was performed on a Byrd Station core fraction which, according to a tentative time-scale (personal communication from C.U. Hammer, 1987), corresponds to the time interval 5000-55 000 years B.P. (Fig. 1). In what follows, we briefly discuss the data in the 25 000–55 000 years B.P. time interval. A first look reveals that all the data lie in a band between 180 and 220 ppm volume; no values are observed in the 240 and 260 ppm volume band. There are periods showing trends, e.g. from c . 210 ppm volume around 40 000 years B.P. to c . 185 ppm volume around 32 000 years B.P. , and periods of strong scattering of the data, e.g. between 41 000 and 44 000 years B.P. , with values in the 185-215 ppm volume band. At Byrd Station the annual accumulation is 0.16 m of water equivalent, compared to 0.50 m of water equivalent at Dye 3. This means that at Byrd Station, both the difference between the age of the surrounding ice and the mean age of the air, and the width of the age distribution of the gases, are larger than at Dye 3. In addition, the Byrd Station core does not show the rapid δ 18 O changes which indicate warm periods with relatively high accumulation. Thus one might argue that in the Byrd Station core the CO 2 changes are dampened, due to a significantly wider age distribution of the gases in the ice. This effect was modelled by Neftel and others (in press). They applied a deconvolution procedure in order to reinstall the range of possible atmospheric CO 2 concentrations (see Fig. 2). This procedure results in a somewhat wider band of possible CO 2 concentrations; in some periods it is 170-230 ppm volume. But it does not produce the possible high values in the range observed in the Greenland ice cores. All this new information leads to the following ambiguous conclusions: The new CO 2 data for the Camp Century ice core show rapid Wisconsin CO 2 changes similar to those in the Dye 3 data, in spite of the differences in the temperatures and the physical and chemical properties of the two ice cores. However, similar CO 2 changes do not appear in the Byrd Station ice core (from Antarctica) in the core fraction thought to represent the corresponding time interval. There are three possible ways to resolve the apparent discrepancy: (1) In the Wisconsin warm-period ice, CO 2 is artificially enriched, due to a process which has not yet been identified. (2) In the Byrd Station core, the CO 2 changes during the Wisconsin are attenuated to a much higher degree than was assumed in the model calculations by Neftel and others (in press). (3) The increments in both the Greenland and Byrd Station cores which have been investigated do not represent overlapping time intervals, perhaps due to rheological irregularities in the Greenland ice sheet close to bedrock (Staffelbach and others 1988, this volume). With the existing core material it is difficult to resolve this important problem. The dilemma of the rapid Wisconsin CO 2 , variations is one of the many important arguments for the recovery of new deep cores both in Greenland and in Antarctica.

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