Abstract
Supraglacial deposits of tephra or volcaniclastics have the potential to cause significant anomalies of glacier ablation and runoff. The intensity of these anomalies is governed by the thermal resistivity of the covering layer and hence the thermal conductivity of the deposited grains. This study concentrates on causal and quantitative relationships between density, geochemical composition and thermal conductivity of volcanic materials based on the analysis of 43 samples from locations across Iceland. Thermal conductivity is primarily influenced by density, whereas geochemical composition has been proved to be of subsidiary importance. Four different multiple regression models were calibrated that calculate the grain thermal conductivity of a volcanic material based on rock properties and geochemical composition. In a subsequent step, the bulk thermal conductivity of the respective deposit is calculated as a function of porosity and degree of water saturation. Examples using volcanic material from the Eyjafjallajökull 2010 and Grímsvötn 2011 eruptions confirm that the presented calculation scheme can be executed using only limited geochemical data as input. This facilitates an easy application of the modeling scheme immediately after a volcanic eruption.
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Introduction
Volcanic tephra and volcaniclastics can be dispersed over vast areas around a source vent by fallout following ejection through an explosive eruption. The generated layers of volcanic material are characterized by high spatial heterogeneity with thicknesses ranging over several orders of magnitude (Brown et al. 2012). The high dispersion of the volcanic materials is often associated with a considerable influence on humans and ecosystems (Machida 2002). Among the abiotic components of the ecosystems, especially permafrost features and glaciers are affected by deposition of volcanic materials (Kellerer-Pirklbauer et al. 2007; Kirkbride and Dugmore 2003).
In the cryosphere, influences related to alterations of the surface energy and mass balance of either the frozen ground, the snow or the glacier ice are crucial (Dragosics et al. 2016; Möller et al. 2018). Two counteracting effects govern the strength of these alterations (Möller et al. 2016). The first is the albedo effect, which enhances ablation due to a darkening of the glacier surface and the related increase of absorbed radiation energy. It increases with thickness of the deposited volcanic material up to full coverage of the glacier surface and remains constant afterwards. The second is the thermal resistance effect, which reduces ablation due to the decrease of heat conducted from the air to the glacier surface. Thermal resistance increases with deposition thickness and it can be quantified either by empirical measurements or by physics-based considerations of the thermal properties of the deposit (Möller et al. 2016; Nicholson and Benn 2013). While deposition thickness is process-related, the thermal properties and, in particular, thermal conductivity are strongly related to the petrographical characteristics of the volcanic material and to the water content of the deposit (Clauser and Huenges 1995; Kuznetsova 2017). Relations between thermal conductivity of rocks and their petrographical characteristics are well documented and calculation methods have long been known (e.g., Horai and Baldridge 1972; Corson 1974; García et al. 1989).
In Iceland, glaciers cover an area of ~ 11,100 km2 (Fig. 1) and thus about 11% of the island (Björnsson and Pálsson 2008). Icelandic volcanoes have experienced a considerable number of eruptions in historical times, several of which were phreatomagmatic and thus of the explosive type (Thordarson and Larsen 2007). Significant amounts of proximal tephra fallout were documented for the eruptions of Hekla, in 1991 (Gudnason et al. 2017), Grímsvötn, in 2004 (Jude-Eton et al. 2012), and Eyjafjallajökull, in 2010 (Gudmundsson et al. 2012). However, volcanic deposits found on Iceland are not always original in situ tephra deposits, but may also be secondary deposits of volcaniclastics after aeolian transport away from their original deposition site (Arnalds et al. 2016; Liu et al. 2014). Frequent strong winds promote wind erosion, especially of fine-grained volcanic ashes (Arnalds et al. 2013; Dagsson-Waldhauserova et al. 2014). Similar to tephra fallout (Möller et al. 2014, 2019), the resulting dust storms have the potential to deposit considerable amounts of petrographically and geochemically different volcanic material on surrounding glaciers (Wittmann et al. 2017).
Based on a collection of 43 samples of volcanic materials from various locations on Iceland, we here investigate the hypothesis that the varying petrographical characteristics of the volcanic materials cause substantially different thermal properties among the associated supraglacial deposits. These in turn may influence glacier ablation and potentially result in altered timings and magnitudes of peak runoff which may exert a significant geohazard impact.
We analyze to which extent the variability of grain thermal conductivity is related to petrographical characteristics, in particular grain density and geochemical composition. We investigate whether this relation can be described by statistical relationships and evaluate the possibility of inferring the grain thermal conductivity of the volcanic materials from their grain density and/or geochemical composition by means of regression modeling. We further present constraints for the bulk thermal conductivity of a deposit of volcanic materials considering its pore space and water content in addition to the grain thermal conductivity.
Finally, we test to which extent it is feasible to estimate grain and bulk thermal conductivity of a volcanic deposit from literature-derived geochemical compositions only. Doing so would facilitate estimations immediately after volcanic eruptions when only the characteristic geochemical fingerprints of the respective source volcanos are known. Such an approach might have the potential to be further developed into a useful and fast-response tool for geohazard assessment.
Study area and sampling sites
Volcanic structures on Iceland are organized into zones, which mainly follow the plate boundaries associated with the continuation of the mid-ocean ridge across the island (Sæmundsson 1979; Thordarson and Larsen 2007). From the south, there are the Reykjanes Volcanic Belt (RVB), the Western Volcanic Zone (WVZ), the Mid-Iceland Belt (MIB) and the Northern Volcanic Zone (NVZ) (Fig. 1). The Eastern Volcanic Zone (EVZ) has developed in the off-rift flank zone since the late Pliocene through propagating axial rifting towards the south and is thought to continue the same in the future (Gudmundsson 1995). Apart from these plate boundary-oriented volcanic zones, two active intraplate zones also exist, the Snæfellsness Volcanic Belt (SVB) and the Öræfi Volcanic Belt (ÖVB).
Along the main axial rift zone, i.e., from RVB to NVZ, volcanic activity is dominated by tholeiitic magmatism while across the off-rift flank zones transitional alkaline or even alkaline magmatism dominates (Jakobsson et al. 2008; Sigmarsson and Steinthórsson 2007). The northern part of the off-rift EVZ is still dominated by tholeiitic magmatism, before it changes into a transitional alkaline magmatism in its central parts and even further into a mildly alkaline magmatism on the Vestmannaeyjar islands (Jakobsson 1979). Magmatism in the ÖVB is closely related to the central parts of the EVZ and is likewise transitional alkaline. In the SVB, in contrast, magmatism is mildly alkaline and thus similar to that on the Vestmannaeyjar islands (Jakobsson et al. 2008).
Active volcanism in Iceland is confined to about thirty active central volcano systems (Fig. 1), characterized by both effusive and explosive eruptions with lava and tephra compositions ranging from basaltic to rhyolitic (Thordarson and Höskuldsson 2008; Thordarson and Larsen 2007). Due to the presence of glacier ice over many of the volcanic vents, even mafic magmas are mostly erupted explosively in a phreatomagmatic style (Jakobsson and Gudmundsson 2008; Larsen and Eiríksson 2007). Only 22% of the historic mafic eruptions were effusive (Thordarson and Höskuldsson 2008). Several volcano systems are known to have characteristic geochemical compositions, i.e., major element oxide ratios (Gudmundsdóttir et al. 2016; Larsen et al. 1998). However, these ratios are not always unambiguous as the affinity of neighboring systems can be large enough to induce at least partly overlapping fingerprints (Neave et al. 2015; Óladóttir et al. 2008).
Volcanic activity in historical times was dominated by four distinct central volcanos all located in the EVZ. About 80% of the total volume of erupted magma can be assigned to the Katla (28%), Grímsvötn (25%), Hekla (15%) and Veiðivötn-Bárðarbunga (12%) volcano systems (Thordarson and Larsen 2007). Among them, Grímsvötn experienced by far the highest number of eruptions including the most recent explosive one in 2011 (Óladóttir et al. 2011; Stevenson et al. 2013). Among the historic eruptions, 88% of the explosive and 45% of the effusive events occurred in this zone, producing 93% of all erupted tephra and 44% of all erupted lava (Thordarson and Höskuldsson 2008).
Our sampling strategy accounts for the variability of volcanic deposits across Iceland. The locations of the sampling points (Figs. 1, 2) were primarily chosen to mirror the major central volcanoes along the volcanic zones with special emphasis on RVB, WVZ, NVZ and EVZ where about 98% of all historic volcanic activity occurred (Thordarson and Höskuldsson 2008). Field sampling covered most of the rock types present on Iceland, despite the broad prevalence of basaltic tephra and lava (Sigmarsson and Steinthórsson 2007).
In the NVZ, we particularly concentrated on locations close to two major central volcanoes, Askja and Krafla. In the EVZ, we concentrated on locations representing two major central volcanoes, i.e., Hekla and Katla. For the latter, sampling locations in the extensive sandur plains of the Myrdalsjökull ice cap were chosen, thus exhibiting fluvial relocation of the original tephra deposits. Moreover, at Eyjafjallajökull and Grímsvötn volcanoes, samples were taken inside the summit caldera and at the caldera rim, respectively, to acquire pristine tephra from the two most recent eruptions.
In the two intraplate volcanic zones ÖVB and SVB, samples were collected to represent the major central volcanos, i.e., Snæfell (ÖVB) and Snæfellsjökull (SVB). In addition, sampling included a couple of extinct volcanoes in the southeast and northwest of the island.
To account for the widespread distribution, the high variability and petrographic diversity of volcanic deposits across Iceland, our sampling encompassed original tephra deposits as well as volcaniclastic sediments. No samples were taken from notably weathered or silt-covered sediments to keep the chemical composition of the volcaniclastics as original as possible. Nevertheless, samples might have been altered by weathering or mixing with ex situ materials.
Three different types of sampling sites have to be distinguished: first, subsurface materials, which crop out in natural scarps; second, surface materials from vegetation- and soil-free sandy plains; third, the calderas of Eyjafjallajökull and Grímsvötn wherein it was necessary to sample surface materials from active geothermal sites to guarantee snow-free access to the volcanic material. From all three types of sampling sites, the same amounts of material were extracted (~ 0.002 m3). Samples were stored in clean plastic bags until preparations for laboratory analyses started.
Laboratory analyses
Methods
Grain thermal conductivity of the volcanic materials was measured using a commercial device (TeKa 04 thermal conductivity meter) that uses a modified hot needle probe method as measuring principle. In contrast to the original and well-established hot needle probe method (Von Herzen and Maxwell 1959) in which a thin, long heating source is inserted into the sample, TeKa 04 uses a disk-shaped device with the heating source mounted at its underside, which is placed on top of the sample.
For preparation, the volcanic materials were sieved. From the sieved samples, the 1–3 mm grain size fractions were extracted. For measurement, the material was filled into a container of known volume and fully saturated with water. Temperature was kept constant (20 °C) during measurements. Prior to the measurement, the probe was installed on the material inside the container and any remaining air is evacuated from the closed measurement system. It cannot be ruled out that the limitation of the sample to its 1–3 mm grain size fraction might impact the measurement somewhat, but we expect those impacts to be small as the majority of the samples fall within this grain size range.
The results of the measurements represent the thermal conductivity of the composite of volcanic material and water. Following Farouki (1981), the bulk thermal conductivity (\(k_{{\text{c}}}\)) can be estimated by:
which represents the geometric mean between the thermal conductivity of the grains (\(k_{{\text{g}}}\)) and the saturating water (\(k_{{\text{w}}}\)) weighed by porosity (\(p\)). Thus, the grain thermal conductivity is given by:
A value of \(k_{{\text{w}}}\) = 0.6 W m−1 K−1 was assumed in calculations. Porosity was calculated as:
where the volume of the saturating water (\(V_{{\text{w}}}\)) was derived by weighing the measured material both in its saturated and in a dried-out state and the volume of the measured material (\(V_{{\text{c}}}\)) is that of the container. Hereby, the density of the volcanic material is derived implicitly.
Grain thermal conductivity and grain density results of the sampled volcanic material are given in Table 1. The chemical composition (ten major element oxides) of the volcanic material derived from X-ray fluorescence (XRF) analysis is given in Table 2. Trace elements are given in the supplementary Table S1.
Based on the anhydrous weight portions of the major element oxides, the volcanic host rock type of each sample is identified using the relation between its total alkali (Na2O + K2O) to silica (SiO2) contents following the total alkali–silica (TAS) diagram classification introduced by Le Bas et al. (1986). The rock types are presented in Table 1.
Results
Measured grain thermal conductivity and grain density of the 43 samples show means of 1.43 ± 0.38 Wm−1 K−1 and 2487 ± 452 kg m−3, respectively (Table 1). For individual samples, thermal conductivities range between 0.69 Wm−1 K−1 (samples 5 and 39) and 2.33 Wm−1 K−1 (sample 18). The relative variability in grain density is slightly smaller. Values range between 1081 kg m−3 (sample 5) and 3667 kg m−3 (sample 2). Characteristic spatial patterns across Iceland do not exist (Fig. 2). Just the spatial consistency of the absolute minima of both quantities at the location of sample 5 is noticeable. The significant correlation (r = 0.66) between grain thermal conductivity and grain density suggests a characteristic relationship between the two (Fig. 3).
The geochemical compositions of the 43 samples are less diverse than their thermal conductivities and densities. The weight portions of the main components (SiO2, Fe2O3 and Al2O3) scatter within narrow limits, albeit some exceptions (Table 2). The silica content shows a mean of 43.1 ± 6.1 wt% (± one sigma). Only a limited number of examples for strongly negative or positive deviations exist. Overall data cover silica contents between 33.2 and 68.0 wt%. The alkali content (Na2O + K2O) shows a mean of 2.8 ± 1.2 wt%, with some apparent outliers. Values for individual samples range between 0.7 and 6.7 wt%.
Geochemical compositions of the samples show a dominance of basalt with almost two-thirds of the samples belonging to this rock type (Table 1, Fig. 4). Basaltic materials dominate in all volcanic zones and belts of Iceland with only few exceptions (Fig. 2). In the WVZ, picrobasalt is the dominating rock type. In the southern EVZ, more evolved and differentiated rock types occur. Silica content (SiO2) is spatially uniformly distributed even if lowest weight portions concentrate in the WVZ (Fig. 2). Samples with extremely high silica contents are limited to the NVZ (samples 27 and 28, Fig. 2). Samples with a high alkali content (Na2O + K2O) occur in the southern EVZ (samples 1 and 6) and at the Askja caldera (sample 28, Fig. 2).
When classifying the samples into different rock types, relationships between geochemical composition on the one hand and grain thermal conductivity and grain density on the other hand are noticeable (Fig. 4). Data suggest a decrease of density with further evolution of the rock type from mafic to felsic. For thermal conductivity, such a trend is mostly obscured by a small number of samples at the felsic edge of the range of rock types. Accordingly, the laboratory results also suggest a variation of the above-described relationship between grain density and grain thermal conductivity with rock type (Fig. 3): the increase of thermal conductivity with density is higher for picrobasalt and andesite than for the overall sample set, whilst it is lower for basaltic andesite. The comparably limited number of all rock type subsets, except for basalt, inhibits any statistically significant inference of characteristic relationships.
In line with this, correlations between the weight portions of individual major element oxides and both the grain thermal conductivity itself and the residuals of the grain density–thermal conductivity relation (cf. Fig. 3) are generally weak (Table 3). Significant correlations occur only for partial correlations, which mask out secondary influences by other than the considered oxide itself. MnO is negatively related to grain thermal conductivity, while Na2O shows a positive relation. CaO and Na2O are positively related to the residuals of the grain density–thermal conductivity relation.
Development of thermal conductivity models
Model description
We propose four different predictive models (A, B, C1 and C2) to estimate grain thermal conductivities from rock properties and compositional data. These models are based on a regression analysis of the data listed in Tables 1 and 2. We further calculate bulk thermal conductivity of a volcanic deposit with variable pore space and water saturation.
In model A, grain thermal conductivity (\(k_{{\text{g,A}}}\)) is only a linear function of density (Table 1):
In model B, grain thermal conductivity (\(k_{{\text{g,B}}}\)) is a function of the major element oxides (\(e_{{\text{i}}}\) in wt%; Table 2):
The coefficients \(c_{{{\text{A}},i}}\) and \(c_{{{\text{B}},i}}\) are shown in Table 4 and are determined from data in Tables 1 and 2.
Other than models A and B, models C1 and C2 do not directly estimate grain thermal conductivity, but aim at explaining the residuals of model A. Hence, the predictand of model A (\(k_{{\text{g,A}}}\)) is added as a predictor.
In model C1, grain thermal conductivity (\(k_{{\text{g,C1}}}\)) is the sum of \(k_{{\text{g,A}}}\) and a function of the major element oxides (\(e_{i}\) in wt%; Table 2):
In model C2, grain thermal conductivity (\(k_{{\text{g,C2}}}\)) is the sum of \(k_{{\text{g,A}}}\) and a function of anhydrous weight portions of the three major element oxides (\(e_{{{\text{anhyd}},i}}\) in wt%) that were previously used to determine rock types (SiO2, Na2O and K2O; cf. Sect. 3.1):
The coefficients \(c_{{{\text{C1}},i}}\) and \(c_{{{\text{C}}2,i}}\) are shown in Table 4 and are again determined from data in Tables 1 and 2.
On the basis of Eq. (1), bulk thermal conductivity of a volcanic deposit (\(k_{{\text{d}}}\)) can be calculated from:
where \(k_{{\text{a}}}\) (0.0262 W m−1 K−1) is the air thermal conductivity.
The three components are weighted according to their respective volume portions in the deposit, which are calculated from the effective porosity of the deposit (\(p\)) and from the degree of water saturation of the related pore space (\(s\)). As porosity and water saturation of the deposit are generally unknown, they were treated as variables here. By varying both of them between 0.0 and 1.0 (0–100%), we calculated the full range of bulk thermal conductivities of a deposit of volcanic material.
Model performance
Model performance is assessed on the basis of three different statistical measures. First, we calculate the root mean square (RMS) error between measured and modeled \(k_{{\text{g}}}\). Second, we calculate the percentage of the variance in measured \(k_{{\text{g}}}\) which is explained by each model, i.e., we calculate R2. And third, we calculate the slope of a linear fit to a scatter plot between measured and modeled \(k_{{\text{g}}}\).
Results indicate that the four regression models A, B, C1 and C2 show distinctly different performances (Fig. 5). Model A (\(k_{{\text{g,A}}}\)) explains 43.4% of the variance in measured \(k_{g}\). The RMS error between \(k_{{\text{g,A}}}\) and \(k_{{\text{g}}}\) of ± 0.282 W m−1 K−1 indicates an accuracy of modeled \(k_{{\text{g,A}}}\) of ~ ± 20%. Model B, as the least accurate model, explains only 33.2% of the variance. Modeled \(k_{{\text{g,B}}}\) show an RMS error of ± 0.306 Wm−1 K−1 and thus an accuracy of ~ ± 21%. The best performing models are C1 and C2. Model C1 explains 58.9% of the variance in measured \(k_{{\text{g}}}\). The RMS error is as low as ± 0.240 Wm−1 K−1 (~ ± 17%). Model C2 explains 44.9% of the variance in measured \(k_{{\text{g}}}\) and an RMS error of ± 0.279 Wm−1 K−1 (~ ± 19%). The thermal conductivities calculated according to all four models show the same kind of systematic error, even though at different magnitudes (Fig. 5). In general, smaller values (< ~ 1.5 Wm−1 K−1) are overestimated, while larger values (> ~ 1.5 Wm−1 K−1) are underestimated. In case of model B, this systematic error is more pronounced. The slope of its linear fit is only 0.33 (Fig. 5). For model C1 the slope reaches 0.59.
Model feasibility test
Procedure
In the following, we evaluate to which extent it is feasible to carry out the thermal conductivity modeling procedure described above, based on limited geochemical input data derived from the literature. For this test, we use major element oxides (Table 5) from the Eyjafjallajökull 2010 (EYV10) and the Grímsvötn 2011 (GRV11) eruptions as direct input in models B, C1 and C2. Apart from the geochemical data, grain densities of the volcanic materials are needed as input in models A, C1 and C2. To derive grain densities from the available geochemical compositions, characteristic median tephra densities for each igneous rock type (Hasterok and Webb 2017) were interpolated over the entire TAS diagram range using ordinary kriging (Fig. 6). In that way, grain densities can be determined from anhydrous weight portions of the SiO2, Na2O and K2O content only.
In the feasibility test, we first compare the performances of all four regression models in calculating grain thermal conductivity (\(k_{{\text{g}}}\)) of the two volcanic materials. We further compare the modeled \(k_{{\text{g}}}\) to the measured thermal conductivities of samples 6 and 8 which were taken at the calderas of Eyjafjallajökull and Grímsvötn, respectively (Fig. 2). Second, we calculate the ranges of possible bulk thermal conductivities \(k_{{\text{d}}}\) for any related deposit (Eq. 8).
The performance of the four regression models is assessed in terms of their modeling uncertainty, i.e., the uncertainty which they introduced into modeled \(k_{{\text{g}}}\). It is described by confidence intervals which are calculated individually for any \(k_{{{\text{g,MOD}},i}}\) according to:
Herein, MOD indicates the respective model (A, B, C1 or C2) and \(i\) the volcanic material (EYV10 and GRV11). \(t_{{\alpha /2,n - n_{{{\text{coef}}}} }}\) is the cutoff value in a Student’s t distribution for a probability \(\alpha\) = 0.05 and \(n - n_{{{\text{coef}}}}\) degrees of freedom, with \(n\) = 43 being the number of samples used for model calibration and \(n_{{{\text{coef}}}}\) the number of coefficients of the respective model (2 for model A, 11 for model B, 13 for model C1 and 6 for model C2). \({\text{SE}}\) is the standard error of the respective model. \(x_{i}\) is the matrix of input variables to the respective model containing the individual values related to volcanic material \(i\) for calculation of \(k_{{{\text{g,MOD}},i}}\). \(X\) is the matrix of input variables containing the values related to all 43 samples used for calibration of the respective regression model.
For the most feasible model, we also calculate the sensitivities of modeled \(k_{{\text{g}}}\) to perturbations of the values of the respective input variables to assess the impact of potential inaccuracies of these values. The sensitivities are calculated by varying the values of the input variables within a range of ± 5%, which represents a rather conservative estimate. XRF analysis, which determines the weight portions of the major elements oxides, usually achieves accuracies with error ranges well below 1% regarding major element oxides (Jenkins 1999). For grain density, the data of Hasterok and Webb (2017; Fig. 6) suggest a spread of approximately ± 3% between the median density of each rock type and the associated upper or lower 5th percentile.
Results
The geochemical compositions EYV10 and GRV11 (Table 5, Fig. 6) characterize the volcanic materials as trachyandesitic and basaltic. The interpolation from point values of median densities per rock type by ordinary kriging assigns grain densities of 2738 kg m−3 (EYV10) and 2938 kg m−3 (GRV11), respectively, to these materials.
Model A and model C2 deliver comparable results in modeling grain thermal conductivities, while the results of calculations with models B and C1 deviate considerably (Fig. 7). The uncertainties, i.e., the 95% confidence intervals, of the thermal conductivities calculated using models B and C1 are in the same order of magnitude. The uncertainties of thermal conductivities calculated using models A and C2, in contrast, are up to one order of magnitude smaller. While the 95% confidence intervals of \(k_{{\text{g,B}}}\) amount to ± 0.662 Wm−1 K−1 (EYV10) and ± 1.064 Wm−1 K−1 (GRV11), those of \(k_{{\text{g,C2}}}\) are distinctly smaller at just ± 0.386 Wm−1 K−1 (EYV10) and ± 0.149 Wm−1 K−1 (GRV11) (Fig. 7).
Based on the four predictive values for \(k_{{\text{g}}}\) of each volcanic material in combination with their respective confidence intervals, it is possible to identify a range of thermal conductivities covered by all four confidence intervals. When accepting the four predictive values as equally reliable, this range (indicated by grey shading in Fig. 7) might be interpreted as that one in which the actual value of \(k_{{\text{g}}}\) can be found with the highest probability. For both volcanic materials, only the predictive values of models A and C2 lie within this range. As model C2 shows the better model performance (Fig. 5) it is rated as the most feasible model. It combines a good model performance with the second smallest range of model uncertainty. In addition, the model sensitivity analysis suggests only a minor sensitivity of \(k_{{\text{g,C2}}}\) to the accuracy of its predictor variables (Table 6). Combined sensitivity to all four predictors only reach ± 0.093 Wm−1 K−1 in case of the EYV10 material and ± 0.092 Wm−1 K−1 in case of the GRV11 material. This means that a simultaneous variation of all four predictor variables (each within a ± 5.0% range) only results in a relative variability of \(k_{{\text{g,C2}}}\) of ± 5.9% (EYV10) and ± 5.3% (GRV11). Individual sensitivities are largest for density in case of both volcanic materials. For the EYV10 material, a ± 5.0% perturbation of density leads to an equal perturbation in \(k_{{\text{g,C2}}}\). For the GRV11 material, a ± 5.0% perturbation of density leads to a slightly smaller perturbation in \(k_{{\text{g,C2}}}\) of 4.9%. Distinctly smaller impact of perturbation of the weight portions of SiO2, Na2O and K2O is observable, with ± 5.0% perturbations of the major element oxide’s weight portion leading to perturbations in \(k_{{\text{g,C2}}}\) of just between ± 0.3% (K2O, GRV11) and ± 2.6% (SiO2, EYV10) (Table 6).
Comparing the modeled \(k_{{\text{g}}}\) of the EYV10 and GRV11 materials to their measured counterparts, i.e., samples 6 and 8, reveals a partly inconsistent result. Sample 6 from Eyjafjallajökull has been identified as trachyandesitic (Table 1). Also, the chemical composition of the EYV10 material suggests trachyandesitic material. The alkali–silica relations of both volcanic materials (Tables 2, 5) are similar at 0.126, even though the individual weight portions are slightly lower in sample 6. The measured grain density of sample 6 is only slightly lower (~ 7%) than the one assumed for the EYV10 material (Table 1, Fig. 6). Accordingly, the measured grain thermal conductivity of sample 6 lies close to \(k_{{\text{g,C2}}}\) of the EYV10 material (Fig. 7). This supports the reliability of the thermal conductivity model C2. The comparison between sample 8 and the GRV11 material, on the other hand, yields less convincing results. Both volcanic materials are identified as basaltic but sample 8 is close to picrobasaltic. Their alkali–silica relations differ by a factor of five due to the very low alkali content in sample 8 (Tables 2, 5). The grain densities are also considerably different. Sample 8 should have a rather high grain density of > 3000 kg m−3 according to Fig. 6, similar to the assumed density of the GRV11 material. However, the measured grain density of sample 8 is only 2457 kg m−3 (Table 1), which is very low for an almost picrobasaltic material. Consequently, the measured grain thermal conductivity of sample 8 is distinctly smaller than \(k_{{\text{g,C2}}}\) of the GRV11 material (Fig. 7). This indicates potentially misleading influences of grain density.
The possible ranges of bulk thermal conductivities of deposits of the EYV10 and GRV11 materials (\(k_{{\text{d}}}\)) are large but show clear relations to the respective thermal conductivities of the grains, which constitute the deposit. In general, bulk thermal conductivities are confined to the interval \(\left] {0.0262,k_{{\text{g,C2}}} } \right]\) (Fig. 8). The theoretical minimum (\(k_{{\text{d}}}\) = \(k_{{\text{a}}}\) = 0.0262 Wm−1 K−1) which represents quasi-complete insulation cannot be reached. It would require a porosity \(p\) = 100% without any water saturation at all (\(s\) = 0%), implying the absence of any volcanic material or pore-filling water. The maximum (\(k_{{\text{d}}}\) = \(k_{{\text{g,C2}}}\)), in turn, requires the absence of any pore space (\(p\) = 0%) and thus a solid, non-porous rock layer. A further boundary exists for the theoretical combination of \(p\) = 100% and \(s\) = 100% which would correspond to a pure water layer with a thermal conductivity \(k_{d}\) = \(k_{w}\) = 0.6 W/mK. The actual values of \(k_{{\text{d}}}\) span between these fixed edges. Thereby, the importance of \(s\) for \(k_{{\text{d}}}\) increases with \(p\) (Fig. 8). For volcanic deposits with little porosity, the degree of water saturation only has a negligible influence on \(k_{{\text{d}}}\). The higher the porosity, the more important is how much of the pore space is filled with water. Thereby it is important to point out that in a dry deposit \(k_{{\text{d}}}\) is characteristically reduced by one half (related to the maximum \(k_{{\text{d}}}\) = \(k_{{\text{g,C2}}}\), i.e., to a solid rock layer) at a porosity of ~ 16%, independent of \(k_{{\text{g,C2}}}\). For a completely water-saturated deposit of EYV10 material, the halving occurs not until \(p\) = 72% while for a completely water-saturated deposit of GRV11 material porosity only needs to reach 65% to achieve a halving of \(k_{d}\) (Fig. 8). This shows that the decrease of \(k_{{\text{d}}}\) with increasing \(p\) in completely water-saturated deposits is more pronounced for deposits of high-conductive volcanic materials than for deposits of low-conductive volcanic materials.
The 95% confidence intervals of \(k_{{\text{d}}}\) increase with decreasing porosity (Fig. 8). The degree of water saturation is of minor importance regarding the confidence intervals, but increases with porosity. For highly porous volcanic deposits, the confidence intervals approach 0 Wm−1 K−1 as the boundary condition at \(p\) = 100% is formed exclusively by linear combinations of the physical constants \(k_{{\text{a}}}\) = 0.0262 Wm−1 K−1 and \(k_{{\text{w}}}\) = 0.6 Wm−1 K−1. The confidence intervals reach their maximum extent at \(p\) = 0% where they equal the ones of \(k_{{\text{g,C2}}}\).
Discussion
The results of the laboratory analysis are consistent with theoretical considerations and with the obtained relationships between rock properties and geochemical compositions. The grain density variation across rock types (Fig. 4) matches expectations as igneous rocks tend to increase in density with decreasing alkali and silica contents (Hasterok and Webb 2017). Moreover, the measured grain thermal conductivity conclusively mirrors the distribution of the samples across the different rock types, and especially the dominance of basaltic materials. The characteristic thermal conductivity of this rock type (1.69 Wm−1 K−1; Sharma 2002) lies well within the one sigma uncertainty range around the mean grain thermal conductivity of the 43 samples (1.43 ± 0.38 Wm−1 K−1). However, the variation of grain thermal conductivity across rock types does not unveil any noteworthy correlations with individual major element oxides. The main contributor to the alkali contents (Na2O) is the only major element oxide that shows a significant positive correlation both to grain thermal conductivity and to the residuals of the grain density–thermal conductivity relation (Table 3). This apparently suggests an increase of grain thermal conductivity with alkali contents, but from a physical–chemical point of view these two properties have to be deemed unrelated as the alkali contents of the 43 samples hardly exceeds 5 wt% in general. Hence, individual components of the geochemical composition that alone control parts of the variation in grain thermal conductivity cannot be identified. This might also explain the poor performance of model B in estimating grain thermal conductivity and also the rather small increase of performance between models A and C1 (Fig. 5).
The observed increase of grain thermal conductivity with alkali contents might, nevertheless, be explainable via the relation of Na2O to the silica content (SiO2). The distribution of the samples in the TAS diagram indicates an increase of silica with alkali content (Fig. 4), and silica-rich, i.e., felsic, rocks tend to contain considerable amounts of quartz, which is a high-conductive mineral (7.69 Wm−1 K−1; Horai 1971).
Overall, the weak correlations between a) geochemical components and grain thermal conductivity and b) geochemical components and residuals of the grain density–thermal conductivity relation (Table 3) suggest that important influences of the major element oxides on thermal conductivity might result only from their effect on density. This might also explain that grain density is needed as a predictor in the regression models to reach more than one-third of variance explanation as it is done by the solely geochemistry-dependent model B (Fig. 5).
However, grain density may also act as a limiting factor for meaningful comparisons between measured and modeled grain thermal conductivities. The comparison between the measured grain thermal conductivity of sample 8 and the one modeled for the GRV11 material using model C2 revealed considerable differences (Fig. 7), which can be related to inconsistent grain density assumptions. Results suggest the presence of considerable isolated porosity or microporosity in the grains of sample 8, which biases their density towards lower values. Assuming model C2 to work correctly, this points to an error in the determination of grain thermal conductivity of sample 8, which is explainable by the fact that the measurement procedure takes no account of any isolated pores in the grains. This means that deviations between modeled and measured grain thermal conductivity do not necessarily indicate a poor model performance. They might also be related to problems with the determination of grain thermal conductivity during the measurement procedure due to a presence of isolated pore space in the grains.
Even the most complete model C1 is not able to explain more than 59% of the variance in measured grain thermal conductivity. This suggests the existence of additional controlling factors. The grain thermal conductivity of volcanic materials also depends on the internal structure of the related mineral content. Orientation of the minerals and thus texture of the material, the degree of anisotropy and the potential inhomogeneity of the volcanic material also influence grain thermal conductivity (Krishnaiah et al. 2004; Stephens and Sinnock 1980). Such factors cannot be accounted for in a modeling procedure that aims at estimating thermal conductivity of volcanic materials immediately after a volcanic eruption. For this purpose, model C2 is the most adequate scheme as it best combines high accuracy with low model uncertainty. It can be run with data of known geochemical compositions of any arbitrary volcanic eruption. The density information can be derived as part of the modeling procedure on the basis of the alkali and silica contents of the erupted volcanic material (Fig. 6). These quantities also qualify for the attribution of a volcanic material to a certain igneous rock type. Therefore, it is even possible to derive approximated density information solely from knowledge of the erupted rock type.
Extending the thermal conductivity modeling from the volcanic grain material to the entire deposit is the most challenging part of the model application. Our procedure covers only the influences of porosity and water saturation. The consideration of porosity includes interconnected, non-isolated pore space within the individual grains of the volcanic material as well as the pore space between them. The former is governed by a direct causal connection to the eruption process, while the latter is determined by grain size distribution and the tightness of the grain packing. The degree of water saturation integrates over the entire pore space, neglecting a potential contribution of adhesive water, which can influence thermal conductivity (Farouki 1981). Also influences of phase changes from liquid to frozen water, which are quite common in supraglacial volcanic deposits are neglected, even though it is known that these may alter thermal conductivity too (Kuznetsova 2017). Since the thermal conductivity of a volcanic deposit is always lower than that of the related volcanic material itself, our modeling approach is, in any case, suitable for deriving the maximum bulk thermal conductivity of such a deposit.
However, as already mentioned, the sample set used in this study shows limitations regarding statistical validity due to the clear dominance of one single rock type, i.e., basalt. From Fig. 3, it can be seen that limiting the sample set to picrobasaltic samples only would induce a distinctly different relation between grain density and grain thermal conductivity and would thus considerably influence the derived regression models. This suggests that from a distinctly larger sample set it would be possible to calibrate the regression models specifically for certain rock types. We expect that such a procedure would yield improved model performance.
Conclusions
Samples of volcanic materials from 43 different locations across Iceland have been analyzed with respect to their petrographic characteristics and geochemical compositions. Most of the samples were classified as basaltic. Mean grain thermal conductivity of the 43 samples is 1.43 ± 0.38 Wm−1 K−1 and mean grain density 2487 ± 452 kg m−3. Grain density was found to be by far the most important single predictor for grain thermal conductivity as indicated by a significant positive correlation of 0.66 (R2 = 0.43). Multiple correlation with all ten major element oxides only reaches 0.58 (R2 = 0.33). Just two out of ten oxides (MnO and Na2O) show statistically significant partial correlations to grain thermal conductivity at a rather low level of maximum 0.42.
Four different regression models for calculation of grain thermal conductivity were set up. They rely on grain density and/or geochemical composition. Models accounting for both (models C1 and C2) show the highest accuracy with R2 values of up to 0.59 and root mean square errors of no more than 0.28 Wm−1 K−1. However, even these models feature a systematic error. Grain thermal conductivities below ~ 1.5 Wm−1 K−1 are overestimated, while those above are underestimated. This means that none of the four models covers the full range of measured grain thermal conductivities.
All four models were evaluated regarding their suitability for an application immediately after a volcanic eruption. In this evaluation, a modeling procedure was carried out that determines the possible range of bulk thermal conductivities of a volcanic deposit from known geochemical characteristics of the source volcano only. It was applied to geochemical data of volcanic materials from the Eyjafjallajökull 2010 and the Grímsvötn 2011 volcanic eruptions. Models C1 and C2 not only show the highest accuracies but also distinctly lower model uncertainties than model B. The model which best combines high accuracy with low model uncertainty is model C2. It shows a root mean square error of ± 0.28 Wm−1 K−1 combined with 95% confidence intervals of ± 0.39 Wm−1 K−1 for the Eyjafjalljökull material or ± 0.15 Wm−1 K−1 for the Grímsvötn material. The rather small confidence intervals are a benefit from only four predictor variables. Applying model C2 yields grain thermal conductivities of the Eyjafjallajökull and Grímsvötn materials of 1.58 Wm−1 K−1 and 1.73 Wm−1 K−1, respectively. In a dry volcanic deposit, these values halve as soon as the porosity of the deposit rises to ~ 16%. In a completely water-saturated deposit, halving occurs at porosities of 72% and 65%, respectively.
Results show that our modeling procedure enables the calculation of the maximum bulk thermal conductivity of a volcanic deposit. However, future refinement is needed with respect to the influence of frozen water content, which is an important factor in supraglacial deposits of volcanic materials. Future work might also increase model accuracy by repeating the calibration of the regression models with an extended and more diverse sample set.
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Acknowledgements
Open Access funding provided by Projekt DEAL. This study was funded by Grants no. KU1476/5-1 and SCHN680/6-1 of the German Research Foundation (DFG). We thank the administration of the Vatnajökull National Park for granting permission for tephra sampling at Grímsvötn caldera and other sites within the national park area. Marianne Dohms is acknowledged for carrying out XRF measurements and an anonymous reviewer for significant improvement of the manuscript.
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Möller, R., Römer, W., Möller, M. et al. Thermal conductivity of supraglacial volcanic deposits in Iceland. Int J Earth Sci (Geol Rundsch) 109, 569–585 (2020). https://doi.org/10.1007/s00531-020-01820-0
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DOI: https://doi.org/10.1007/s00531-020-01820-0