Basic principles

If an ice core should be dated with the ²¹⁰Pb method several prerequisites need to be fulfilled:

• • The CIC assumption should be fulfilled as well as constant annual precipitation rates. This results in a CRS situation.

• • Post-depositional effects (melting, sublimation and wind drift) should be minimal.

• • In some cases, however, it could be shown that ²¹⁰Pb activity profiles were not much influenced by percolating meltwater. We assume that the ²¹⁰Pb atoms are strongly adsorbed on the surfaces of mineral dust particles contained in the ice matrix (see section ‘²¹⁰Pb dating of temperate glaciers’).

• • A great advantage is the fact that sampling can be made from the outside of the core, which is usually not suited for chemical trace analysis.

• • Continuous sampling is essential – though at low sample resolution.

• • Measurements should be continued to depths where constant values are reached. These indicate the natural background level needed for background correction.

• • With the surface age known (equal to the date of drilling), a fit through the data plotted against depth in meter water equivalent (m w.e., converted from depth in meter by multiplying with density to account for snow/firn densification as observed in the measured density profile) yields the final age–depth relationship by applying the radioactive decay law:

  (1)$$t = \displaystyle{{-s} \over {\ln \lpar 2\rpar }}\cdot T_{1/2}\cdot x\comma \;$$

where t is the age in years since the drill date, s is the slope of the fit, T _½ is the half-life of ²¹⁰Pb (22.3 years) and x is the depth in m w.e. From the uncertainty of the regression slope, the dating uncertainty can be estimated (see Fig. 3). Note that the uncertainty bands are different if the fit relates either to the scale of the measured ²¹⁰Pb concentration activity or to the therefrom-deduced age scale. This is because, for the latter case, the uncertainty is zero at the surface for which the age is known precisely, that is equal to the year of drilling.

Fig. 3. ²¹⁰Pb activity concentration and derived age as a function of depth in an ice core from Belukha. (a) ²¹⁰Pb activity concentration as a function of depth. The thin dotted line indicates the 1σ uncertainty band of the regression fit. The dashed line indicates the average value for the lowermost samples reflecting the input from supported ²¹⁰Pb, that is the natural background determined for this site. (b) The same data of ²¹⁰Pb activity concentration, but with the natural background (supported ²¹⁰Pb) subtracted, together with the derived age scale as shown on the right y-axis as a function of depth. The dotted lines indicate the 1σ dating uncertainty, derived by error propagation, which includes the uncertainty of the regression fit shown in (a). Open gray circles indicate distinct time horizons found in the ice core (³H peak in 1963 from nuclear weapons testing and signals in sulfate related to the known volcanic eruptions from Katmai and Tambora in 1912 and 1815/16, respectively). The fit shown by the thick gray line does account for glacier thinning (see section ‘Effect from thinning of annual layers’). Data from Olivier and others (Reference Olivier2006).

Figure 3 shows an example of ²¹⁰Pb measurements of an ice core from Belukha (Olivier and others, Reference Olivier2006). After the expected exponential decrease with depth or time, respectively, the values reach a plateau, indicating an average background value of 3.6 ± 1.2 mBq kg⁻¹ (value already corrected for the small instrumental background of ~1 mBq kg⁻¹, see section ‘Experimental procedure’). This value represents ²¹⁰Pb from mineral dust contained in the ice. This activity is called supported ²¹⁰Pb. The background value observed at Belukha is typical for many glacier sites. Note that this natural background value has always to be subtracted from all the measured ²¹⁰Pb activity concentrations to deduce the final dating (Fig. 3b).

The time range accessible with the ²¹⁰Pb method depends on the initial activity concentration at the surface and the respective background. The dating time frame is ~80 years for sites with ~40 mBq kg⁻¹ surface activity concentration and increases to ~180 years for the most continental sites such as Tien Shan (400 mBq kg⁻¹) or Belukha (280 mBq kg⁻¹), respectively. From Figure 3b it becomes clear that the dating uncertainty increases as a function of age (in Fig. 3b about ±10 years for the lowermost samples from the mid-19th century). Advantage of the ²¹⁰Pb dating is that it is independent from other approaches such as annual layer counting based on chemical tracers.

Effect from thinning of annual layers

Ice is a plastic solid, therefore increasing pressure induced by overlaying ice layers causes horizontal glacier flow, resulting in a reduction of the original ice layer thickness. This effect is called thinning and becomes significant particularly for deeper ice core sections. Consequently, a deviation of the exponential trend in the ²¹⁰Pb activity concentration with depth is expected. Several mathematical models describe such a thinning. We use here the oldest, original one by Haefeli (Reference Haefeli1961) to illustrate the basic principle of this effect. This model describes the time as a function of depth with

(2)$$t = \displaystyle{H \over a}\ln \,\left({\displaystyle{H \over {H-x}}} \right)\comma \;$$

where t is the time in years after deposition, H the ice thickness in m w.e., a the net annual accumulation rate in m w.e. and x is the depth from the surface in m w.e.

If this equation is combined with the exponential decay law for ²¹⁰Pb, the following equation results for the ²¹⁰Pb activity concentration A as a function of depth (Gäggeler and others, Reference Gäggeler, von Gunten, Rössler, Oeschger and Schotterer1983):

(3)$$A = A_0\left({\displaystyle{H \over {H-x}}} \right)^c\comma \;$$

with

(4)$$c ={-}\displaystyle{{\lambda H} \over a}\comma \;$$

where λ is the decay constant of ²¹⁰Pb (0.0311 a⁻¹).

An example from Colle Gnifetti is shown in Figure 4, highlighting the potential importance to consider the thinning effect when dating by ²¹⁰Pb. The fit derived based on Eqn (3) accounting for thinning (R ² = 0.89, n = 13; residual sum of squares (RSS) = 380.0) is a better description of the observed data than the fit based on the law of exponential decay which does not consider any thinning (R ² = 0.85, n = 13; RSS = 557.7).

Fig. 4. ²¹⁰Pb activity concentration as a function of depth in m w.e. at Colle Gnifetti (adapted from Gäggeler and others, Reference Gäggeler, von Gunten, Rössler, Oeschger and Schotterer1983). The solid thick line shows a fit through the data accounting for thinning (according to Eqn (2)), whereas the thin line is a fit solely derived from the exponential decay law. Horizontal bars indicate sampling depth ranges and vertical bars the std dev. of the averaged values from individual measurements performed in higher sampling resolution.

Special cases

²¹⁰Pb dating of temperate glaciers

Temperate glaciers are characterized by an ice temperature close to the melting point and the presence of liquid water formed by melting of ice and/or originating from rain or snow melt. Water percolation may therefore influence the ²¹⁰Pb activity concentration profiles by downward relocation and, in the extreme case, by removal of ²¹⁰Pb through run-off with meltwater. As an example, Figure 5 shows ²¹⁰Pb data of an ice core from the temperate Vernagtferner (Austria), with the ice core sampling site located at an elevation of 3150 m a.s.l. (von Gunten and others, Reference von Gunten, Rössler and Gäggeler1982). Obviously, relocation of ²¹⁰Pb with meltwater resulted in high variability. It is interesting to note that often the maxima of the ²¹⁰Pb activity concentrations coincide with high levels of mineral dust.

Fig. 5. Continuous ²¹⁰Pb activity concentration profile in the ice core from the Vernagtferner (3150 m a.s.l., Austria) drilled in 1979 (open symbols with 1σ analytical uncertainty bars). The profile includes three replicate samples. Depicted is a best fit through all ²¹⁰Pb data. The fit directly relates to the age scale indicated by the right-hand y-axis with the 1σ dating uncertainty shown by the dashed lines. Figure deduced from von Gunten and others (Reference von Gunten, Rössler and Gäggeler1982).

Another example is from the temperate Silvretta Glacier (Switzerland) with the drilling site located at 2927 m a.s.l. (Fig. 6, Pavlova and others, Reference Pavlova2015). Again, despite fluctuating ²¹⁰Pb values, on average the inventory of ²¹⁰Pb and the exponential decrease looks very reasonable. In this case, the 1963 horizon identified via tritium measurements is predicted slightly older by the ²¹⁰Pb dating at 1953 but still in agreement within the 1σ uncertainty estimate.

Fig. 6. ²¹⁰Pb activity concentrations along an ice core from Silvretta, drilled in 2011. The red dot shows the 1963 peak in ³H related to nuclear bomb testing, indicating the accuracy of the dating by ²¹⁰Pb with uncertainties (1σ) depicted by the shaded area. Adapted from Pavlova and others (Reference Pavlova2015).

Surface age in case of negative mass balance

Due to climate warming, glaciers in most mountain regions of the world have been retreating and even disappearing at an accelerated rate in recent decades (e.g. Zemp and others, Reference Zemp2015). This increasingly affects also the accumulation areas, for which widespread surface loss is often observed. ²¹⁰Pb may serve to identify such cases since melting of surface layers may lead to enrichment of ²¹⁰Pb activity concentrations at the surface. An example is shown in Figure 7 for the Mount Geladaindong Glacier, central Tibetan Plateau (5750 m a.s.l.) (Kang and others, Reference Kang2015).

Fig. 7. ²¹⁰Pb activity concentrations in an ice core from Mount Geladaindong (5750 m a.s.l.) (open and solid diamonds); adapted from Kang and others (Reference Kang2015). For details see text.

In Figure 7, the ²¹⁰Pb activity concentrations at depths below ~5 m (solid diamonds) follow an exponential decrease. However, the topmost two values (open diamonds) strongly deviate from this trend, seemingly being far too high. We assume that these two data points represent enriched values. The hypothesis is that while matrix water was removed by melting, ²¹⁰Pb was enriched in the surface layers due to adsorption on rather immobile dust particles. A significant loss of surface mass is corroborated by the presence of the nuclear fallout layer at a shallow depth of only 5.74 m, identified by the prominent peak in the tritium activity concentration (red dot) (Kang and others, Reference Kang2015). The resulting net accumulation between the date of ice core drilling (October 2005, i.e. surface) and 1963 (at 5.74 m depth) of 14 cm a⁻¹ is much smaller than the 30 cm a⁻¹ deduced for the lower part of the core from the slope of the exponential decrease (see Fig. 7). A more recent change in the mass balance to negative values thus seems to be a reasonable assumption for this site. Accordingly, the age of the surface can be assumed to differ from the date of drilling (October 2005). The age of the surface was estimated by anchoring the ²¹⁰Pb profile to the year 1963 represented by the tritium peak at 5.74 m depth, resulting in the time axis depicted on the right y-axis. An extrapolation to the surface results in a surface age of 1982 ± 5, hence in a loss of 2005–1982 = 23 ± 5 years of accumulation, and a deduced surface ²¹⁰Pb activity concentration of 89 mBq kg⁻¹ (gray cross), which is a very reasonable value (see Table 1). A final proof of evidence for the validity of the chosen approach can be derived, based on the ²¹⁰Pb activity concentration observed in the first two values. Under the assumption of surface enrichment, they should reflect the integrated activity of 23 years of ²¹⁰Pb deposition with the determined initial activity A ₀ (89 mBq kg⁻¹). Indeed, the observed high values do account for 81% of the expected activity, suggesting only moderate removal, that is run-off of the deposited ²¹⁰Pb of ~ 20%. This is in close agreement with the determined preservation of lead in snow and ice under the influence of percolating meltwater of ~70% (Avak and others, Reference Avak, Schwikowski and Eichler2018, Reference Avak2019).

Effect of sublimation on the ²¹⁰Pb profile

Andean glaciers located in the South American dry diagonal are often influenced by strong sublimation. A consequence is the formation of penitents. Sublimation means evaporation of water from the solid phase to the gas phase while non-volatile species such as ²¹⁰Pb remain in the matrix. Such a situation was extensively studied at Cerro Tapado (30°08′S; 69°55′W; 5534 m a.s.l.) in the Chilean Andes (Ginot and others, Reference Ginot2002, Reference Ginot, Kull, Schotterer, Schwikowski and Gäggeler2006). A large year-to-year variability in loss of H₂O due to sublimation was observed (Ginot, Reference Ginot2001). The sublimation rate was determined by chemical means via measurement of chloride concentrations: at this glacier, most precipitation comes from the nearby Pacific by westerly winds that contains much sea salt. As a consequence, the chloride concentration is rather high and constant in fresh snow. Deviations of the chloride concentration measured in individual ice samples compared to those in fresh snow then yield the enrichment factor due to sublimation. On average, sublimation turned out to result in a mass loss of 60%. This means that a determination of annual net accumulation rates from measured ²¹⁰Pb profiles differs from total accumulation rates. Figure 8 depicts the situation observed at Cerro Tapado. The trend in the measured chronology of ²¹⁰Pb activity concentrations as a function of depth indicates an annual accumulation rate of 235 mm w.e. a⁻¹ (Fig. 8a). Correcting the ²¹⁰Pb activity concentration profile by accounting for loss of snow by sublimation using the chloride concentration record (Fig. 8b) results in a revised annual accumulation rate of 405 ± 50 mm w.e., in reasonable agreement with 470 ± 70 mm w.e. from a glaciological estimate (see Ginot, Reference Ginot2001).

Fig. 8. Effect of sublimation on the ²¹⁰Pb profile. (a) Measured ²¹⁰Pb activity concentration in an ice core from Cerro Tapado as a function of depth in m w.e. (b) The same data but here accounting for sublimation resulting in a corrected depth (see text for details). Dashed lines indicate the measured ²¹⁰Pb activity concentration, and respective trend line. Hatched areas indicate the depth range where ²¹⁰Pb activity reached the background level from supported ²¹⁰Pb. The solid lines depict the measured data (and respective trend lines) after substraction of this background (average value within hatched areas). Figure adapted from Ginot and others (Reference Ginot, Kull, Schotterer, Schwikowski and Gäggeler2006).

Determination of the annual deposition rate

At remote sites with no possibility to get meteorological information or to return for stake measurements, the last year's deposition can be determined using the ratio of the grand-daughter radionuclide ²¹⁰Po and its mother nuclide ²¹⁰Pb. As stated previously, after ~1½ years the secular equilibrium between these two radionuclides is nearly reached (see Introduction). Between time zero and equilibrium, the relationship between the activity concentrations of ²¹⁰Po and ²¹⁰Pb approximately follows the below equation:

(5)$$A_{\lpar {}_\;^{210} {\rm Po}\rpar } = A_{\lpar {}_\;^{210} {\rm Pb}\rpar }\lpar {1-{\rm e}^{\lpar -\lambda t\rpar }} \rpar \comma \;$$

where A(x) is the activity concentration of nuclide x, t is the elapsed time between precipitation date and date of sample collection and λ is the decay constant of ²¹⁰Po ( = ln(2)/138.4 days). Equation (5) is only a close approximation, since the intermediate radionuclide ²¹⁰Bi the daughter of ²¹⁰Pb with a half-lie of 5 days is ignored. However, this is justified considering its short half-life compared to those of ²¹⁰Pb and ²¹⁰Po, respectively.

Figure 9 depicts an example of this approach for measurements at Jungfraujoch (Switzerland) (Gäggeler and others, Reference Gäggeler, Tobler and Vogel2009). One half of each firn sample was analyzed for ²¹⁰Po immediately after sampling. The other half was stored for 1½ years and then analyzed again for ²¹⁰Po, but now representing the ²¹⁰Pb activity concentration since equilibrium between the two radionuclides was nearly reached. The red curve depicts the ratio between the activity concentrations. The maximum value of 0.84 at 5.7 m depth indicates that the equilibrium at this depth was almost reached already at the time of sample collection (i.e. the time of first analysis). Using Eqn (5), a value for t of 366 days results (i.e. ~1 year) indicating the annual net accumulation at this site to be 5.7 m of snow. Obviously, the same accumulation rate can be deduced from the profile at any other, shallower depth. Therefore, this application is not dependent on the performed sampling depth, which is important to note if intended to be applied at a site with no initial knowledge (although sampling depths covering close to 1 year or more of deposition is favorable to obtain a better constrained fit and accordingly better precision and accuracy for the finally determined accumulation).

Fig. 9. Activity concentrations of ²¹⁰Po and ²¹⁰Pb in a firn core from Jungfraujoch (Switzerland) sampled on 25 March 2007 (reported in Gäggeler and others, Reference Gäggeler, Tobler and Vogel2009). The red line is the modeled fit according to Eqn (5).

²¹⁰Pb, a potential tool for the determination of net glacier ice flow rates

We tested whether ²¹⁰Pb surface activity concentrations along a trajectory of the Aletsch Glacier (Switzerland) below the equilibrium line do yield time information on the glacier flow rate. The idea behind this approach is that ²¹⁰Pb – incorporated in the ice matrix by initial deposition in the accumulation zone and likely being adsorbed on mineral dust particles – is rather immobile. Moreover, it is assumed that ²¹⁰Pb is not prone to relocation even in the case of percolating meltwater certainly existing in the sampled ablation zone. This seems reasonable based on Avak and others (Reference Avak, Schwikowski and Eichler2018, Reference Avak2019), showing that lead incorporated in snow and ice is one of the well-preserved trace elements under the conditions of percolating water (~70% preservation). However, later, additional input to the now re-exposed sampled surface in the ablation zone, for example by meltwater from the winter snow and from summer rain is assumed to be entirely removed by run-off. Under such assumptions, the ²¹⁰Pb activity concentration profile along a downward trajectory should decrease in correspondence to the elapsed time, following the law of decay for ²¹⁰Pb.

Near-surface samples (after cleaning to remove surface dust layers) of ~10 cm length were taken using a hand-drill device. The sample sites along the trajectory are shown in Figure 10 and are summarized in Table 2, together with the measured ²¹⁰Pb activity concentrations.

Fig. 10. Trajectory along the Jungfraufirn/Aletsch Glacier (Switzerland) along which surface ice samples were collected for ²¹⁰Pb analysis. Map reproduced by permission of swisstopo (JA100121).

Table 2. Sample sites on Jungfraufirn/Aletsch Glacier (Switzerland) along the trajectory depicted in Figure 10, measured ²¹⁰Pb activity concentrations and deduced flow rates (Gäggeler and others, Reference Gäggeler, Szidat, Vogel, Tobler and Boss2010)

Typical uncertainties of ²¹⁰Pb activity concentrations are ±7%. Coordinates refer to the Swiss coordinate system (Swiss Grid) CH1903/LV03.

Obviously, the ²¹⁰Pb values steadily decrease along the trajectory with one exception: in the middle of the Konkordia place, a significantly higher value was measured (sample site 3). Likely the trajectory of ice parcels do not follow the surface at this exceptional site where the Aletsch Glacier is fed from four different sides, from the large firn fields called Jungfraufirn (i.e. the upper part of our trajectory), Ewigschneefeld and Grosser Aletschfirn as well as from the somewhat smaller Grüneggfirn. The value from sample site 3 was therefore discarded. From the ²¹⁰Pb activity ratio between two sample sites, the known half-life for ²¹⁰Pb and the distance, the flow rate was deduced, resulting in an average flow rate of 166 m a⁻¹ along the entire 7.92 km trajectory.

In a recent paper, Jouvet and Funk (Reference Jouvet and Funk2017) modeled the trajectory of the corpses of mountaineers who disappeared on Aletsch Glacier in 1926. According to their modeling results, the relics were transported parallel to our trajectory between sample sites 4 and 6 (see Table 2) for the time interval from 1985 to 2012. The average flow rate given in Jouvet and Funk (Reference Jouvet and Funk2017) for this section is ~150 m a⁻¹, in surprisingly good agreement with our estimated value of 160 m a⁻¹.