Abstract
Many interpretations have been proposed to explain the presence of jarosite within Martian surficial sediments, including the possibility that it precipitated within paleo-ice deposits owing to englacial weathering of dust. However, until now a similar geochemical process was not observed on Earth nor in other planetary settings. We report a multi-analytical indication of jarosite formation within deep ice. Below 1000 m depth, jarosite crystals adhering on residual silica-rich particles have been identified in the Talos Dome ice core (East Antarctica) and interpreted as products of weathering involving aeolian dust and acidic atmospheric aerosols. The progressive increase of ice metamorphism and re-crystallization with depth, favours the relocation and concentration of dust and the formation of acidic brines in isolated environments, allowing chemical reactions and mineral neo-formation to occur. This is the first described englacial diagenetic mechanism occurring in deep Antarctic ice and supports the ice-weathering model for jarosite formation on Mars, highlighting the geologic importance of paleo ice-related processes on this planet. Additional implications concern the preservation of dust-related signals in deep ice cores with respect to paleoclimatic reconstructions and the englacial history of meteorites from Antarctic blue ice fields.
Similar content being viewed by others
Introduction
Jarosite, a ferric-potassium hydroxide sulfate [KFe3+3(SO4)2(OH)6], was firstly hypothesized to be a common mineral on Mars by Burns1 despite its rareness on Earth. In 2004 the Opportunity rover reported widespread jarosite at Meridiani Planum2, confirming Burns’ prediction, but the geological context where jarosite was found – in fine-grained sediments within layered formations – was difficult to interpret. Since then, the mineral has been repeatedly identified on Mars3,4,5 and has been regarded as evidence for the occurrence of liquid water6 because on Earth jarosite forms as the result of low-temperature acidic-oxidative weathering of iron-bearing minerals in water-limited settings7.
Limited water is not only necessary for the formation of jarosite, but it is critical to its long-term preservation. Experimental evidence shows that when the local water to rock ratio exceeds 10, jarosite is transformed into goethite8,9. The occurrence of jarosite on Mars has thus been interpreted as an indication that weathering fluids have been active over local scales and for a geologically short time interval10. An apparent paradox concerns the lithology of the protolith in which jarosite occurs, which is composed of mafic (basaltic) volcanic material11,12. The interaction between basalt and acidic solutions has a neutralizing effect incompatible with jarosite formation13. The paradox is solved if the interaction occurs in environments isolated from bedrock, where water–rock interaction is limited and low pH is maintained during the diagenesis14.
Most of the hypotheses about the formation of Martian jarosite involve the interaction between acidic fluids and weathered sediments in transient lacustrine-evaporative basins similar to Earth playas3,5,11 or volcanic settings, such as fumaroles12. An alternative proposal predicted that jarosite formation would occur during weathering of mafic dust or fine-grained ash trapped in massive ice, but this process had not been observed until now14,15. The ice-weathering model suggested that the interior of ice deposits promotes acidic weathering of dust through cryo-concentration of sulfur-rich volcanic aerosols, leading to jarosite precipitation13,14. Experimental evidence has since shown that the weathering rate of basalt-related minerals is elevated at cryogenic temperatures16, in accordance with the identification of jarosite as a weathering product in Antarctica17. But the englacial formation of jarosite is still a speculation. Until this work, Antarctic jarosite has been found in rock varnishes and weathering rinds formed on the surface of erratics17 and of meteorites collected at blue ice fields18,19, or in soils developed from sulfide-rich rocks20, but not in englacial environments.
Here we report the identification of jarosite in deep Antarctic ice, which we hypothesize as authigenic, resulting from the interaction between aeolian dust and acidic species trapped in the ice. The identification of the mineral is confirmed by several evidences, gathered through the application of different and independent techniques. Our results show that weathering and englacial diagenesis is possible deep inside thick ice, potentially affecting the climatic interpretation of dust records in deep ice cores. Given the similarities between our hypothesis and the Martian ice-weathering model, our findings support that ice-mediated weathering is a viable geological mechanism for jarosite formation on Mars, with major implications for past chemical weathering processes on that planet.
Results and discussion
The Talos Dome ice core
The 1620 m long TALDICE (Talos Dome Ice Core 72°49′S, 159°11′E; 2315 m a.s.l.) has been retrieved from a peripheral ice dome of the East Antarctic Plateau21 and dated up to 1439 m deep (along the text we refer to “ice depth” to indicate the distance between the ice sheet surface and the considered point into the ice sheet), where the estimated ice age is ~153,000 years before present (BP)22,23 (Fig. 1). The deeper part of the core is believed to contain climatic information extending to 250,000 years BP and possibly beyond21. Below 1439 m depth, mm-scale visible layers (volcanic ash and cloudy bands) are progressively tilted and folded, and deeper than 1528 m they disappear. In addition, below 1590 m very large ice-crystals (40–50 cm), indicative of ice metamorphism, have been observed24 (Fig. 1a). Ice flow disturbances and anomalous ice-crystal growth in the bottom sections of TALDICE have been related to the presence of an irregular bedrock consisting in buried mesas interrupted by canyons, which disturb the ice-flow and the ice stratigraphy24. Multiple lines of evidence suggest that throughout the late Quaternary the aeolian dust deposited at Talos Dome was mostly local, in particular during interglacials, when the arrival of dust from remote sources was suppressed25. The most important local sources of dust consist in high-elevation ice-free doleritic-basaltic outcrops25,26 and in tephra from proximal Antarctic volcanoes27. The influence of volcanic activity at Talos Dome is notable. More than 100 volcanic horizons have been identified along the core, with a frequency one order of magnitude greater with respect to what is observed at Dome C or Vostok, located at higher elevation in inner East Antarctica28. In addition, the aeolian reworking of volcanic deposits provides a background of volcanic tephra in the atmosphere which is also found in TALDICE27.
Identification of jarosite in Antarctic ice
Most of this work is based on the identification of jarosite in dust from the deep part of TALDICE. Highlighting and quantifying the presence of jarosite within µg-size samples is analytically challenging. Evidences have been gathered through multiple techniques, so as to obtain robust and reliable results. Jarosite minerals have been observed through Scanning Electron Microscopy coupled with Energy Dispersive X-ray spectroscopy (SEM-EDX) as micrometric concretions whose shape and composition resemble jarosite. X-ray absorption spectroscopy has allowed to reconstruct the depth profile of jarosite in TALDICE, exploiting Fe speciation and coordination and a quantitative comparison with mineral standards. Scanning Transmission Electron Microscopy (STEM) and EDX, through diffraction spacings and stoichiometry, have brought a further quantitative confirmation of jarosite presence.
The K-edge absorption energy of the Fe fraction of mineral dust from TALDICE increases with depth (Fig. 1c), pointing to a progressive Fe oxidation29. Samples from the 0–1000 m (n = 20), 1000–1300 m (n = 18) and 1300–1620 m (n = 16) depth intervals present average Fe K-edge absorption energies of 7125.5(0.5), 7126.5(0.4) and 7127.2(0.3) eV (standard deviation), respectively. Considering that the positive shift between Fe2+ and Fe3+ is 4 eV, the one observed along TALDICE corresponds to a 30–40% increase of Fe3+29, in agreement with the absolute determination of Fe oxidation in TALDICE dust. Between 0 and 1000 m, Fe in mineral dust consists in a 70–30% mix of Fe3+–Fe2+, while below 1500 m only Fe3+ is detected30. The trend is indicative of in situ oxidative weathering and involves the core throughout its length, regardless of the climate-related oscillations observed in the stable isotope and dust concentration records (Fig. 1c, e, f). This suggests that Fe oxidation is a signal mostly related to non-climatic processes. Below the depth of 1500 m, the absorption energy presents a plateau at about 7127 eV, consistent with the complete oxidation of Fe. Another evidence of weathering comes from the identification of jarosite within TALDICE dust (Fig. 1b). Above the depth of 1033 m, only 1 of 22 samples presents evidence of jarosite occurrence. Fe K-edge absorption spectra of shallow samples are in fact reproduced using common iron bearing minerals, in particular oxides (mostly goethite, a major component of Earth atmospheric mineral dust31,32), but also silicates (Supplementary Fig. 1). At greater depth, a convex feature between 7135 and 7142 eV, indicative of jarosite30, appears in X-ray absorption (XAS) spectra (Supplementary Figs. 1 and 2) and accordingly between 1033 and 1500 m the contribution of this mineral increases and becomes dominant, meaning that more than 50 % of the information from Fe-related XAS spectra is reproduced by jarosite. Below 1500 m jarosite contribution maintains a stable value with a mean of 54(8)% (standard deviation), similar to the Fe oxidation pattern observed at these depths, which also reaches a high and relatively stable value. The agreement between the records is expected given that jarosite is a ferric mineral.
The morphology and elemental composition of mineral dust from sections of TALDICE deeper than 1500 m has been investigated through SEM-EDX (Fig. 2). Weathering features are observed, including the presence of micrometric to sub-micrometric-sized precipitates ranging from crystalline minerals (Fig. 2a, b, d) to globular concretions presenting irregular surface cracks, poorly ordered aggregates (Fig. 2c, e, f) and scarcity of sharp edges. Only a few volcanic glasses covered by precipitates are recognized (Fig. 2e). Among the precipitates, hexagonal platelets are frequently observed, either as independent (Fig. 2a) or grouped crystals (Fig. 2b, d), a habit compatible with the trigonal system of jarosite33. The morphology of TALDICE deep particles exhibits differences with the ones from the upper core, consisting in micrometric mono-mineral particles and volcanic glasses characterized by flat surfaces and sharp corners, indicative of poor chemical weathering (Supplementary Fig. 3). Elemental maps of individual grains show that precipitates are composed of Fe, S and K, corresponding to jarosite constituents, while grain cores mostly consist in Si or Si and Al, with minor traces of Ca, Mg and Na (Fig. 3). A definitive confirmation that precipitates in deep TALDICE consist of jarosite comes from STEM-EDX applied on two mineral grains from TALDICE samples 1559 m deep. Results confirm the presence of jarosite as bladed crystals with diffraction spacings and chemical composition consistent with jarosite (Fig. 4). The examined crystals are nearly pure KFe3+3(SO4)2(OH)6, as supported by EDX quantitative results (see the Supplementary Information).
Englacial chemical weathering of mineral dust in deep ice
Physico-chemical signals are preserved for hundreds of thousands of years within ice34. Climatic proxies, such as δ18O and dust concentration, are correlated in ice cores and show coherent oscillations during glacial/interglacial cycles35. This is confirmed by TALDICE data, where their linear R-squared is 0.75 when considering the depth interval 0–1400 m (Supplementary Fig. 6). In contrast, Fe oxidation and jarosite abundance are not coupled with δ18O (R-squared <0.02) and lack of climate-related fluctuations. They are correlated with the increasing size of ice crystals along the core (R-squared = 0.55 and 0.49, respectively), which is primarily driven by ice metamorphism and not by climate36. The possibility that jarosite observed in the deep part of TALDICE comes from the bedrock is discarded, since there are no other evidences about the presence of bedrock inclusions. Only an extreme ice-folding could explain the presence of bedrock inclusions hundreds of meters above the ice-bedrock interface, but this is incompatible with the preservation of ice stratigraphy up to 1560 m deep21.
Based on our understanding of the environmental conditions of deep ice, we interpret jarosite as the product of englacial weathering. Its formation requires acidic conditions, a limited activity of liquid water and the presence of Fe-bearing materials7. The deep part (>1000 m) of TALDICE can meet such requirements. Deep ice is affected by the progressive re-crystallization of ice grains36,37,38. A consequence of re-crystallization is that impurities incompatible with the ice lattice accumulate at ice grain junctions39,40 or within intra-grain µ-inclusions37,41. Atmospheric sulfates and sulfuric acid are strongly affected by remobilization in ice39,42. They are easily concentrated in isolated environments forming solutions whose eutectic temperature is below the pressure melting point of deep ice, allowing for the presence of acidic liquid layers at grain boundaries in the form of localized brines37,38,39,42,43. In deep ice, as a result of the increased temperature and ice metamorphism, the concentration and mobilization of impurities allows for the mixing of soluble and insoluble species, and for their interaction through englacial acid–base reactions37,41,44,45. Such small-scale environments promote the local increase of acidity and the chemical weathering of aeolian dust41. Dust particles deposited at Talos Dome have a basaltic/doleritic signature and are rich in Fe26,27, making deep TALDICE an environment suitable for jarosite precipitation. An additional source of acidity to the deep englacial environment could come from the oxidation of the pyrite present in TALDICE dust. Pyrite is a relatively common secondary mineral in the Victoria Land region46,47 and has been recognized in shallow TALDICE dust samples as an accessory mineral (see the Supplementary Information). The degradation of pyrite through the oxidation of Fe2+ to Fe3+ and the production of sulfuric acid is a common weathering reaction in glacial systems48 and could contribute to the local increase of acidity in the englacial environment. The positive shift of the Fe K-edge absorption recognized along the core (Fig. 1c), supports this scenario, since it is indicative of the progressive oxidation of Fe with depth.
The identification of secondary ferric precipitates in deep ice is not completely new, evidences were reported from the two EPICA ice cores: De Angelis et al.37 observed micrometric Fe-oxides precipitates within the Dome C ice core while Eichler et al.41 interpreted a few micro-inclusions in the Dronning Maud Land ice core as jarosite.
The acidic weathering of basalt in a closed system produces jarosite and amorphous silica6,13. This matches the observed composition of the grains observed in deep TALDICE. Jarosite is attached to grains composed almost entirely of Si with detectable Al (Fig. 3), a signature compatible with amorphous silica with substituted Al. The distribution of other elements further supports chemical weathering in deep TALDICE: Mg, Ca and Na are almost absent from jarosite precipitates and scarce within Si-rich grains. This is revealed by SEM results (Fig. 3) and by the previous elemental characterization of TALDICE mineral dust30. The scarcity of these elements, common constituents of minerals, suggests that reaction with acidic species leads to the formation of soluble compounds which were removed during the preparation of samples through filtration. This is supported by the identification in deep ice cores of soluble Mg, Ca and Na sulfates41,43,45 and by their direct observation in TALDICE when ice is sublimated rather than being filtrated49. Weathering of minerals also impacts the grain size of insoluble dust in deep TALDICE. This is shown by the dust grain size index, developed to distinguish upper and deeper TALDICE dust through granulometric features (Fig. 1d). Dust from deep TALDICE presents an excess of large particles and a lack of fine ones with respect to typical dust from Antarctic ice cores (Supplementary Fig. 7), as highlighted by the index which presents positive values only in the bottom part of TALDICE (see the Supplementary Information for details). Such anomalies can relate to the chemical aggregation of mineral particles resulting from jarosite englacial precipitation. This mineral is in fact known for acting as a cement during weathering, favoring the aggregation of particles33. We observe that below 1400 m, the linear R-squared between δ18O and dust decreases from 0.75 to 0.44 (Supplementary Fig. 6), pointing to a degradation of the climatic significance of the TALDICE dust record.
Antarctic implications
Jarosite formation in TALDICE constrains the physico-chemical environment of deep Antarctic ice. The bare titration of Antarctic meltwater reveals a mild acidity because of the presence of acid atmospheric species (pH between 5.5 and 650), but jarosite formation and preservation requires a pH lower than 46,51. The only process which can explain how in deep ice such acid conditions are found, at least locally, is the concentration of acids mediated by ice re-crystallization and possibly by the oxidation of the pyrite fraction originally present in the dust deposited at Talos Dome48. Another important point concerns the occurrence of liquid water in the form of brines. Only a few direct lines of evidence for its presence in ice cores are available42 although questioned41, and theoretical supports exist43. The discrepancy could arise because while acidic brines are stable at pressure and temperature conditions found in deep ice sheets, measurements on ice cores are carried under different conditions, in particular for pressure. Yet, the occurrence of jarosite, whose formation requires liquid water, is a strong evidence for the actual, but localized, occurrence of acidic brines in deep ice, likely in correspondence of ice grain junctions or at intra-grain micro-inclusions. Our data show that once jarosite has formed, it is relatively stable in the englacial environment – at least considering the depth interval covered by TALDICE – since its contribution increases from 1000 to 1400 m deep (corresponding to a time interval of ~100,000 years) and then remains almost stable (Fig. 1b). This is a further confirmation that the occurrence of liquid water in deep ice sheets is only local and takes place in the form of highly saline and acid fluids. If the presence of water was larger and its solute content lower, jarosite would not be stable and would convert into goethite8,9,10,13. Further studies involving deeper ice cores, where calcium carbonate has been detected and suggests less acidic conditions37,38, will be useful to assess if the englacial stability field of jarosite is limited to a particular ice depth interval.
Jarosite is present in TALDICE deeper than 1000 m, suggesting that its formation is associated with a threshold (Fig. 1b). Since jarosite forms also at the Earth surface, high pressure is likely not the limiting factor7. Ice temperature at 1000 m depth at Talos Dome is ca. −25.5 ± 0.1 °C, while at the core bottom it is −8.9 ± 0.5 °C (Rix & Martin, personal communication). Increasing temperatures can accelerate both jarosite formation and dissolution51; however, over the full range of temperatures observed within the ice sheet, jarosite is considered stable1,7,51. Instead, the factor which enables the formation of jarosite below the depth of 1000 m, is likely the presence of liquid acidic brines and the concentration of impurities in the same isolated environment, where the pressure melting point is locally lowered37,38,39,40,41,42,43,44. This process is linked to ice metamorphism that is known to drive the migration and the concentration of impurities39,40,42. Once mineral particles and highly concentrated acidic fluids interact, chemical weathering of minerals is enhanced, allowing for the partial dissolution of original dust particles and the precipitation of new mineral phases37,38,41,44,45, such as jarosite. Reactions involving dust in deep ice should be investigated further in relation to the preservation of climatic signals in deep ice cores, in particular considering the “quest for the oldest ice”. Ice core records concerning the analysis of Fe concentration and speciation52 could be significantly affected by the processes described here.
Other implications of this study concern meteorites found at Antarctic blue ice fields. On the surface of such meteorites, a weathering rind 10–100 µm thick rich in jarosite and amorphous silica is commonly found, pointing to acidic alteration18. The rinds have been explained assuming that weathering occurred once meteorites were exposed at the ice surface, because of the interaction with acidic atmospheric species and tiny amounts of liquid water during summer18. Meteorites from blue ice can have remained into the ice for periods up to tens of thousands of years, reaching deep portions of the Antarctic ice sheet before surfacing19,53,54. The interface between deep ice and meteorites could promote the occurrence of acidic aqueous brines because of the crystallographic misfits between ice and mineral structures. Given the compositional similarity between the rinds and weathered dust in deep TALDICE, we suggest that englacial weathering should also be considered in relation to the chemical weathering of Antarctic meteorites, not only the surficial one. A support to this hypothesis comes from the Dome Fuji ice core, where jarosite has been found in correspondence of two extraterrestrial dust horizons, one interpreted as the result of a meteorite impact over East Antarctica, the other of the atmospheric entry of a fragment of an asteroid or a comet55. In TALDICE jarosite only forms below 1000 m deep; its presence in Antarctic meteorite rinds could be thus interpreted as a proxy of the englacial depth reached by meteorites themselves and of their residence time into the ice, as originally proposed by Terada et al.19.
Martian implications
The occurrence of jarosite in TALDICE supports the ice-weathering model for the formation of Martian jarosite within large ice-dust deposits14. The environment inside the Talos Dome ice is isolated from the Earth atmosphere and its conditions, including pressure, temperature, pH and chemistry, provides a suitable analogue for similar Martian settings. Dust deposited at Talos Dome is also similar to Martian atmospheric dust, being both mostly basaltic11,12. Within thick ice deposits it is likely that the environment would be similar at Talos Dome and under Mars-like conditions since both settings would contain at cryogenic temperatures basaltic dust and volcanogenic and biogenic (for Antarctic only) sulfur-rich aerosols. What set them apart is the oxidative agent responsible for Fe oxidation. In deep TALDICE, Fe is likely oxidized through the interaction between air bubbles and clathrates and mineral dust. On Mars oxygen is likely derived from aerosols such as oxy-chlorine species formed through UV photo-oxidation56. Considering this context, it is reasonable that the formation of jarosite on Mars involves the interaction between brines and mineral dust in deep ice, as observed in TALDICE. This mechanism for Martian jarosite precipitation is paradigm changing and strongly challenges assumptions that the mineral formed in playa settings3,5,11.
Mars experienced dramatic climate swings and glaciations throughout its history57,58, and it has been argued that much of the physical layering observed on Mars surface could have been mediated by paleo ice-related processes59. The same could be for its mineralogical and geochemical features. In accordance with the ice-weathering model, Martian polar regions are rich in sulfate deposits which are created through the aeolian reworking of sublimation residues60,61. Despite these evidences and the Burns’ prophetic vision of Mars low-temperature, acid, water-limited alteration1, ice-mediated weathering has never been widely embraced or tested. Based on ongoing detections across the planet, jarosite is probably globally distributed across Mars in association with finely layered sediments3,4,5. Such sediments could result from the accumulation of weathered sublimation residue of past ice-rich deposits, since most of the settings where they occur are compatible with alteration pathways enabled by deep ice metamorphism and cryo-concentration of acidic fluids14,15. In contrast, recent studies have shown that the playa model does not adequately explain the chemical characteristics of jarosite rich deposits, their enormous size and the location of the putative playas12,14,62.
Methods
Dust concentration and grain size
Dust concentration and grain size in TALDICE have been determined through Coulter counter technique in the ISO6 clean room available at the EUROCOLD facility of the University Milano-Bicocca. Twenty-five cm-long ice sections were decontaminated with three successive baths in MilliQ water (© Millipore) and mixed with a clean electrolyte solution (NaCl solution, passed through 0.22 µm pore size membranes) until a final Na+ concentration of 1% m/m was reached. The passage is required so as to make samples electrically conductive. Each sample, consisting in 10 mL of decontaminated meltwater, was measured three times with a Beckman Multisizer 4 equipped with a quartz tube with a 30 µm orifice. Such an instrumental apparatus allows for the quantification of the insoluble particles with a spherical equivalent diameter between 0.6 and 18 µm, divided into 400 channels. Volume of insoluble particles was then converted into mass using a constant density of 2.5 g cm−3, following the convention suggested by Hänel63 for mineral aerosols and classically adopted by the ice core community64,65. Blanks were constantly evaluated during the analysis, their signal, on average, corresponded to 2.5% of the mean sample one. Standard deviation of the replicates ranged between 5 and 10% with respect to the total dust mass of samples. Data concerning the highest part of TALDICE (0–900 m depth interval) have already been published26,66, data from the lowest part (from 900 m to 1616 m) are published here for the first time.
Dust grain size index
To highlight the granulometric differences between dust samples from the upper and lower sections of TALDICE, a dedicated index was developed. For each dust sample analyzed with Coulter counter, sixteen granulometric variables were defined, consisting in dust concentrations and ratios referred to specific grain size intervals (Supplementary Information). Surficial samples are typically fitted by a log-normal distribution, with modal values ranging between 1.8 and 2.2 µm, and present a limited tail of coarser particles (5–10 µm) related to the influence of local Antarctic dust sources26,66. Deeper samples show a coarser modal value (between 2 and 4 µm) but are poorly described by log-normal distributions because of the presence of tails of coarse particles and the scarcity of finer ones (<2 µm). Examples are reported in the Supplementary Fig. 7. A Partial Least Square – Discriminant Analysis algorithm67 was applied to highlight such differences. Samples were firstly classified into upper (0–1450 m depth interval) and lower (1450–1620 depth interval), the algorithm was therefore instructed to reproduce the classification using the descriptive granulometric variables calculated from Coulter counter data, without considering the depth of samples. The dust grain size index shown in Fig. 1d corresponds to the linear combination of the granulometric variables defined by the first latent component calculated by the model to classify the samples. Further details are found in the Supplementary Information.
X-ray absorption spectroscopy
Fe K-edge absorption energy was determined through XAS, performed at B18 beamline of the Diamond Light Source68. Analyses were carried out on samples prepared extracting mineral particles from decontaminated meltwater obtained from TALDICE ice sections in an ISO6 clean room. The extraction took place with clean polycarbonate membranes (rinsed with high purity nitric acid, pore-size 0.4 µm) where meltwater was passed through with micro-pipettes, so as to concentrate the particles in the smallest possible area and maximize the performances69. For each sample a variable volume of meltwater was filtered depending on dust concentration (evaluated with Coulter counter), so as to have on each filter not less than 2–3 µg of dust. Membranes were then placed in clean PTFE filter-holder and mounted on the beamline. Fifty-four samples were prepared, covering the entire length of the ice core; details, including spectral data, are reported in the Supplementary Information. To avoid contamination and interference issues, the following procedures were adopted: 1- the experimental chamber was provided with a clean glove-box filled with pure nitrogen in order to handle and mount the samples in clean conditions; 2- the inner walls of the chamber were coated with clean plastic sheets to reduce the inelastic scattering produced by the interaction of the beam with the metallic chamber; 3- measurements were carried out under high vacuum conditions to remove atmospheric interferences. XAS spectra were acquired at the Fe K-edge absorption line in fluorescence mode, considering the energy interval between 7000 and 7500 eV and energy steps of 0.3 eV. The incident beam was defocused as much as possible to maximize the irradiation area, its size was 0.4 × 0.4 mm. A Vortex 4-elements silicon detector was used (spectral resolution 140 eV full width height maximum at the 5.9 keV Mn K-line). The energetic calibration was monitored through the simultaneous acquisition of the absorption edge spectrum of a metallic Fe foil. For each sample–foil couple, the first derivative peak of the Fe K-edge of the foil was centered at 7112.0 eV, corrections of up to 0.2 eV were necessary. At least three spectra were acquired for each sample during different sessions and average spectra were calculated. Blank filters were measured but no Fe signal was detected. Standards (SRM 2709a, NIST) were prepared following the same procedures adopted for the samples to evaluate the precision of the method, which is 0.2 eV. Spectra were analyzed with the software Athena70. To make them comparable, fluorescence signals were processed to obtain absorption coefficients, which were normalized considering the post-edge baseline71. The pre-edge region was normalized subtracting the pre-edge baseline. The energy position of the Fe K-edge absorption was defined as the energy of the main absorption edge at the height of 0.8 (normalized value) with respect to the post-edge baseline. Errors shown in Fig. 1c correspond to the standard deviation calculated considering the replicates, further details are found in Cibin et al.72.
Jarosite quantification
Jarosite Contribution was estimated comparing the Fe-K edge spectral signature of the samples with one of the mineralogical standards73. Specimens of the following minerals were retrieved from the collection of the University Milano-Bicocca: biotite, chlorite, glaucophane, goethite, hematite, hornblende, jarosite, limonite, magnetite, muscovite, fayalite, pargasite, pyrite, schoerlite, siderite. Fragments of the minerals were powdered using a mortar and mixed with cellulose in pellets which were measured at B18 in transmission mode. Fe K-edge absorption spectra were processed following the steps adopted for samples. To determine the amount of jarosite within the Fe minerals present in TALDICE dust, a linear combination fitting approach was followed73: spectra of the mineral standards were used to reproduce the spectra of the samples through the calculation of linear combinations with the combinatoric package of the Athena software70, based on ordinary least square regression (OLS). For each sample spectrum, all the possible combinations of 4 standards were calculated, forcing the presence of goethite, being the most common Fe-oxide within aerosols31, in particular in cold environments32,74. The contribution of jarosite with respect to total Fe minerals in TALDICE (Fig. 1b), corresponds to the coefficients (expressed as %) associated with jarosite within each linear combination. The % coefficient varies between 0 and 100 and is interpreted as the relative amount of information present in sample spectra that is explained by jarosite signature. The associated error is only statistical and corresponds to the OLS standard error of jarosite regression coefficient. Further details are found in the Supplementary Information.
Microscopy
SEM-EDX observations were carried out on samples of dust extracted from TALDICE decontaminated meltwater, using a Zeiss Gemini 500 Field-Emission SEM equipped with EDX (Quantax EDX 4000, Bruker). Insoluble mineral dust was extracted from meltwater by filtration in an ISO6 clean room with polycarbonate membranes (diameter 25 mm, pore size 0.44 µm). After filtration some membranes were coated with gold for morphological observations (SEM) and others with graphite, for elemental mapping of mineral particles (SEM-EDX).
Two samples were prepared for STEM-EDX analyses following the same procedure adopted for SEM-EDX. Dust particles from two deep sections of TALDICE (below 1500 m) were deposited on polycarbonate membranes through filtration and successively picked, embedded in low viscosity epoxy, and thin sections were placed on amorphous carbon support films and were analyzed using a JEOL 2500SE 200 kV field-emission scanning and transmission electron microscope equipped with a JEOL silicon drift detector for EDX. Diffraction data from multiple orientations were obtained from selected areas of the grains to confirm their identity. Quantitative EDX data were obtained from the same grains as the diffraction data and were quantified using standard thin-film analysis techniques with k-factors from mineral standards (Table S1).
Data availability
The datasets generated and analyzed to the aims of the current study are available in the PANGAEA open repository: 10.1594/PANGAEA.924109, 10.1594/PANGAEA.924113, 10.1594/PANGAEA.924114.
References
Burns, R. G. Ferric sulfates on Mars. J. Geophys. Res. 92, E570–E574 (1987).
Klingelhöfer, G. et al. Jarosite and hematite at Meridiani Planum from opportunity′s mössbauer spectrometer. Science 306, 1740–1745 (2004).
Farrand, W. H., Glotch, T. D., Rice, J. W. Jr, Hurowitz, J. A. & Swayze, G. A. Discovery of jarosite within the Mawrth Vallis region of Mars: implications for the geologic history of the region. Icarus 204, 478–488 (2009).
Weitz, C. M., Noe Dobrera, E. & Wray, J. J. Mixtures of clays and sulfates within deposits in western Melas Chasma, Mars. Icarus 251, 291–314 (2015).
Rampe, E. B. et al. Mineralogy of an ancient lacustrine mudstone succession from the Murray formation, Gale crater, Mars. Earth Planet. Sci. Lett. 471, 172–185 (2017).
Elwood Madden, M. E., Bodnar, R. J. & Rimstidt, J. D. Jarosite as an indicator of water-limited chemical weathering on Mars. Nature 431, 821–823 (2004).
Papike, J. J., Karner, J. M. & Shearer, C. K. Comparative planetary mineralogy: Implications of martian and terrestrial jarosite. A crystal chemical perspective. Geochim. Cosmochim. Acta 70, 1309–1321 (2006).
Tosca, N. J., McLennan, S. M., Dyar, M. D., Sklute, E. C. & Michel, F. M. Fe oxidation processes at Meridiani Planum and implications for secondary Fe mineralogy on Mars. J. Geophys. Res. Planets 113, E05005 (2008).
Zolotov, M. Y. & Shock, E. L. Formation of jarosite-bearing deposits through aqueous oxidation of pyrite at Merdiani Planum. Geophys. Res. Lett. 32, L21203 (2005).
Elwood Madden, M. E., Madden, A. S. & Rimstidt, J. D. How long was Meridiani Planum wet? Applying a jarosite stopwatch to determine the duration of aqueous diagenesis. Geology 37, 635–638 (2009).
McLennan, S. M. et al. Provenance and diagenesis of the evaporite-bearing Burns formation, Meridiani Planum, Mars. Earth Planet. Sci. Lett. 240, 95–121 (2005).
McCollom, T. M. & Hynek, B. M. A volcanic environment for bedrock diagenesis at Meridiani Planum on Mars. Nature 438, 1129–1131 (2005).
Zolotov, M. Y. & Mironenko, M. V. Timing of acid weathering on Mars: a kinetic‐thermodynamic assessment. J. Geophy. Res. Planets 112, E07006 (2007).
Niles, P. B. & Michalski, J. M. Meridiani Planum sediments on Mars formed through weathering in massive ice deposits. Nat. Geosci. 2, 215–220 (2009).
Michalski, J. M. & Niles, P. B. Atmospheric origin of Martian interior layered deposits: links to climate change and the global sulfur cycle. Geology 40, 419–422 (2012).
Niles, P. B., Michalski, J., Ming, D. W. & Golden, D. C. Elevated olivine weathering rates and sulfate formation at cryogenic temperatures on Mars. Nat. Comm. 8, 998 (2017).
Giorgetti, G. & Baroni, C. High-resolution analysis of silica and sulphate-rich rock varnishes from Victoria Land (Antarctica). Eur. J. Mineral. 19, 381–389 (2007).
Hallis, L. J. Alteration assemblages in the Miller Range and Elephant Moraine regions of Antarctica: comparisons between terrestrial igneous rocks and Martian meteorites. Meteorit. Planet. Sci. 48, 165–179 (2013).
Terada, K. et al. General characterization of Antarctic micrometeorites collected by the 39th Japan Antarctic research. Exped. Antarct. Meteor. Res. 14, 89–107 (2001).
Simas, F. N. B. et al. Clay-sized minerals in permafrost-affected soils (cryosols) from King George Island, Antarctica. Clay. Clay Miner. 54, 721–736 (2006).
Stenni, B. et al. Expression of the bipolar see-saw in Antarctic climate record during the last deglaciation. Nat. Geosci. 4, 46–49 (2011).
Veres, D. et al. The Antarctic ice core chornology (AICC2012): an optimized multi-parameter and multi-site dating approach for the last 120 thousands years. Climate 9, 1733–1748 (2013).
Bazin, L. et al. An optimized multi-proxy, multi-site Antarctic ice and gas orbital chronology (AICC2012): 120-800 ka. Climate 9, 1715–1721 (2013).
Montagnat, M. et al. Measurements and numerical simulation of fabric evolution along the Talos Dome ice core, Antarctica. Earth Planet. Sci. Lett. 357–358, 168–178 (2012).
Delmonte, B. et al. Aeolian dust in the Talos Dome ice core (East Antarctica, Pacific/Ross Sea sector): Victoria Land versus remote sources over the last two climatic cycle. J. Quat. Sci. 25, 1327–1337 (2010).
Baccolo, G. et al. Regionalization of the atmospheric dust cycle on the periphery of the East Antarctic ice sheet since the last glacial maximum. Geochem. Geophy. Geosy. 19, 3540–3554 (2018).
Delmonte, B. et al. Modern and Holocene aeolian dust variability from Talos Dome (Northern Victoria Land) to the interior of the Antarctic ice sheet. Quat. Sci. Rev. 64, 76–89 (2013).
Narcisi, B., Petit, J. R., Delmonte, B., Scarchilli, C. & Stenni, B. A 16,000 yr tephra framework for the Antarctic ice sheet: a contribution from the new Talos Dome core. Quat. Sci. Rev. 49, 52–63 (2012).
Berry, A. J. et al. XANES calibrations for the oxidation state of iron in a silicate glass. Am. Mineral. 88, 967–977 (2003).
Baccolo, G. et al. The contribution of synchrotron light for the characterization of atmospheric mineral dust in deep ice cores: preliminary results from the Talos Dome Ice Core (East Antarctica). Condens. Matter 3, 25 (2018).
Formenti, P. et al. Dominance of goethite over hematite in iron oxides of mineral dust from Western Africa: quantitative partitioning by X‐ray absorption spectroscopy. J. Geophys. Res. Atmos. 119, 12740–12754 (2014).
Zhang, X. L., Wu, J., Zhang, C. L., Xu, T. L. & Zhou, Q. Q. What is the role of iron oxides in the optical properties of dust aerosols? Atmos. Chem. Phys. 15, 12159–12177 (2015).
Long, D. T. et al. Formation of alunite, jarosite and hydrous iron oxides in a hypersaline system: Lake Tyrell, Victoria, Australia. Chem. Geol. 96, 183–202 (1992).
EPICA Community Members. Eight glacial cycles from an Antarctic ice core. Nature 429, 623–628 (2004).
Markle, B. R., Steig, E. J., Roe, G. H., Winckler, G. & McConnell, J. R. Concomitant variability in high-latitude aerosols, water isotopes and the hydrologic cycle. Nat. Geosci. 11, 853–859 (2018).
De La Chapelle, S., Castelnau, O., Lipenkov, V. & Duval, P. Dynamic recrystallization and texture development in ice as revealed by the study of deep ice cores in Antarctica and Greenland. J. Geophys. Res. 103, 5091–5105 (1998).
De Angelis, M., Tison, J. L., Morel-Fourcade, M. C. & Susini, J. Micro-investigation of EPICA Dome C bottom ice: evidence of long term in situ processes involving acid–salt interactions, mineral dust, and organic matter. Quat. Sci. Rev. 78, 248–265 (2013).
Tison, J. L. et al. Retrieving the paleoclimatic signal from the deeper part of the EPICA Dome C ice core. Cryosphere 9, 1633–1648 (2015).
Mulvaney, R., Wolff, E. W. & Oates, K. Sulphuric acid at grain boundaries in Antarctic ice. Nature 331, 247–249 (1988).
Bohleber, P., Roman, M., Sala, M., Barbante, C. Imaging the impurity distribution in glacier ice cores with LA-ICP-MS. J. Anal. Atom. Spectrom.https://doi.org/10.1039/D0JA00170H (2020).
Eichler, J. et al. Impurity analysis and microstructure along the climatic transition from MIS 6 into 5e in the EDML ice core using cryo-Raman microscopy. Front. Earth Sci. 7, 20 (2019).
Fukazawa, H., Sugiyama, K., Mae, S., Narita, H. & Hondoh, T. Acid ions at triple junction of Antarctic ice observed by Raman scattering. Geophy. Res. Lett. 25, 2845–2848 (1998).
Dash, J. G., Rempel, A. W. & Wettlaufer, J. S. The physics of premelted ice and its geophysical consequences. Rev. Mod. Phys. 78, 695–741 (2006).
Ohno, H. et al. Physicochemical properties of bottom ice from Dome Fuji, inland East Antarctica. J. Geophys. Res. Earth Surf. 121, 1230–1250 (2016).
Traversi, R. et al. Sulfate spikes in the deep layers of EPICA-Dome C ice core: evidence of glaciological artifacts. Environ. Sci. Technol. 43, 8737–8743 (2009).
Sturm, A. & Carryer, S. J. Geology of the region between the Matusevich and Tucker glaciers, North Victoria Land, Antarctica. N. Zeal. J. Geol. Geop. 13, 408–435 (1970).
Dow, J. A. S. & Neall, V. E. Geology of the lower Rennick glacier, Northern Victoria Land, Antarctica. New Zeal. J. Geol. Geop. 17, 659–714 (1974).
Raiswell, R. et al. Iron in Glacial Systems: Speciation, Reactivity, Freezing Behavior, and Alteration During Transport. Front Earth Sci. 6, 222 (2018).
Iizuka, Y. et al. Sulphate and chloride aerosols during Holocene and last glacial periods preserved in the Talos Dome Ice Core, a peripheral region of Antarctica. Tellus B 65, 20197 (2013).
Legrand, M. J., Aristarain, A. J. & Delmas, J. R. Acid titration of polar snow. Anal. Chem. 54, 1336–1339 (1982).
Elwood Madden, M. E. et al. Jarosite dissolution rates and nanoscale mineralogy. Geochim. Cosmochim. Acta 91, 306–321 (2012).
Burgay, F. et al. Fe2+ in ice cores as a new potential proxy to detect past volcanic eruptions. Sci. Total Environ. 654, 1110–1117 (2019).
Folco, L., Welten, K. C., Jull, A. J. T., Nishiizumi, K. & Zeoli, A. Meteorites constrain the age of Antarctic ice at the Frontier Mountain blue ice field (northern Victoria Land). Earth Planet. Sci. Lett. 248, 209–216 (2006).
Zekollari, H. et al. Unravelling the high-altitude Nansen blue ice field meteorite trap (East Antarctica) and implications for regional palaeo-conditions. Geochim. Cosmochim. Acta 248, 289–310 (2019).
Misawa, K. et al. Two extraterrestrial dust horizons found in the Dome Fuji ice core, East Antarctica. Earth Planet. Sci. Lett. 289, 287–297 (2010).
Catling, D. C. et al. Atmospheric origins of perchlorate on Mars and in the Atacama. J. Gephys. Res. Planet 115, E00E11 (2010).
Head, J. W., Marchant, D. R., Agnew, M. C., Fassett, C. I. & Kreslawski, M. A. Extensive valley glacier deposits in the northern mid-latitudes of Mars: evidence for late Amazonian obliquity-driven climate change. Earth Planet. Sci. Lett. 241, 663–671 (2006).
Kite, E. S., Matsuyama, I., Manga, M., Perron, J. T. & Mitrovica, J. X. True Polar Wander driven by late-stage volcanism and the distribution of paleopolar deposits on Mars. Earth Planet. Sci. Lett. 280, 254–267 (2009).
Tanaka, K. L. Dust and ice deposition in the Martian Geologic Record. Icarus 144, 254–266 (2000).
Langevin, Y., Poulet, F., Bibring, J. P. & Gondet, B. Sulfates in the north polar region of Mars detected by OMEGA/Mars express. Science 307, 1584–1586 (2005).
Smith, I. B., Spiga, A. & Holt, J. W. Aeolian processes as drivers of landform evolution at the south pole of Mars. Geomorphology 240, 54–69 (2015).
Hynek, B. M., McCollom, T. M. & Szynkiewicz, A. Sulfur cycling and mass balance at Meridiani, Mars. Geophys. Res. Lett. 46, 11728–11737 (2019).
Hänel, G. The real part of the mean complex refractive index and the mean density of samples of atmospheric aerosol particles. Tellus 20, 371–379 (1968).
Delmonte, B., Petit, J. R. & Maggi, V. Glacial to Holocene implications of the new 27000-year dust record from the EPICA Dome C (East Atarctica) ice core. Clim. Dynam. 18, 647–660 (2002).
Ruth, U. et al. Proxies and measurement techinques for mineral dust in Antarctic ice cores. Environ. Sci. Technol. 42, 5675–5681 (2008).
Albani, S. et al. Interpreting last glacial to Holocene dust changes at Talos Dome (East Antarctica): implications for atmospheric variations from regional to hemispheric scales. Climate 8, 741–750 (2012).
Ballabio, D. & Consonni, V. Classification tools in chemistry. Part 1: linear models. PLS-DA. Anal. Methods 5, 3790–3798 (2013).
Dent, A. J. et al. B18: a core XAS spectroscopy beamline for Diamond. J. Phys. Conf. Ser. 190, 012039 (2009).
Macis, S. et al. Microdrop deposition technique: preparation and characterization of diluted suspended particulate samples. Condens. Matter 3, 21 (2018).
Ravel, B. & Newville, M. ATHENA, ARTEMIS, HEPHAESTUS: data analysis for X-ray absorption spectroscopy using IFEFFIT. J. Synchrotron Radiat. 12, 537–541 (2005).
Calvin, S. XAFS for Everyone. (CRC Press, Taylor & Francis Group, 2013).
Cibin, G. et al. First combined total reflection X-ray fluorescence and grazing incidence X-ray absorption spectroscopy characterization of aeolian dust archived in Antarctica and Alpine deep ice cores. Spectrochim. Acta B 63, 1503–1510 (2008).
Shoenfelt, E. M., Winckler, G., Lamy, F., Anderson, R. F. & Bostick, B. C. Highly bioavailable dust-borne iron delivered to the Southern Ocean during glacial periods. PNAS 115, 11180–11185 (2018).
Cong, Z. et al. Iron oxides in the cryoconite of glaciers on the Tibetan Plateau: abundance, speciation and implications. Cryosphere 12, 3177–3186 (2018).
Acknowledgements
This work is part of the TALDEEP project funded by MIUR (PNRA18_00098). The Talos Dome Ice core Project (TALDICE), a joint European programme, is funded by national contributions from Italy, France, Germany, Switzerland and the United Kingdom. Primary logistical support was provided by PNRA at Talos Dome. This is TALDICE publication no 57. This publication was generated in the frame of Beyond EPICA. The project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 815384 (Oldest Ice Core). It is supported by national partners and funding agencies in Belgium, Denmark, France, Germany, Italy, Norway, Sweden, Switzerland, The Netherlands and the United Kingdom. Logistic support is mainly provided by PNRA and IPEV through the Concordia Station system. The opinions expressed and arguments employed herein do not necessarily reflect the official views of the European Union funding agency or other national funding bodies. This is Beyond EPICA publication number 11. The authors acknowledge Diamond Light Source for provision of beamtime within proposals sp7314, sp8372 and sp9050. We thank Paolo Gentile and Tiziano Catelani for their assistance with SEM and for providing mineral specimens. Support from NASA ISFM grants to Johnson Space Center are also acknowledged.
Author information
Authors and Affiliations
Contributions
G.B. and B.D. conceived the idea of the work; G.B. interpreted the data and wrote the paper with contributions from all the coauthors; G.B., B.D., E.D.S. prepared the samples and carried out Coulter counter measurements and SEM-microscopy; G.B., G.C., D.H. and A.M. acquired and analyzed XAS data; L.K. and C.S. performed STEM analyses; P.B.N., J.M., M.F. and V.M. helped in the interpretation and discussion of data.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Peer review information Nature Communications thanks Megan Elwood Madden, Elizabeth Shoenfelt and Jean-Louis Tison for their contribution to the peer review of this work.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Baccolo, G., Delmonte, B., Niles, P.B. et al. Jarosite formation in deep Antarctic ice provides a window into acidic, water-limited weathering on Mars. Nat Commun 12, 436 (2021). https://doi.org/10.1038/s41467-020-20705-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-020-20705-z