2.1. Field research

The research presented here is the result of joint USA/Japan/Russia glaciological expeditions to the Siberian Altai in 2001, 2002 and 2003 (Fujita and others, Reference Fujita, Takeuchi, Aizen and Nikitin2004; Aizen and others, Reference Aizen2005, Reference Aizen2006; Nakazawa and others, Reference Nakazawa2005; Okamoto and others, Reference Okamoto2011). The Western Belukha Plateau at the northern edge of the central Asian mountain system was selected as the most suitable site for ice-core drilling. The plateau is ~1 km² and maintains an accumulation area of cold, recrystallized snow/firn (Aizen and others, Reference Aizen2005). The surface velocity at the drilling site is <0.45 m a⁻¹. Maximum ice thickness, determined by radio-echo sounding measurements, is 180 m. Two ice cores were drilled in 2003 on the plateau (Bl2003; 49°48′N, 86°33′E, 4115 m a.s.l.) (Fig. 1), westward from West Belukha Peak (4435 m a.s.l.): one core was drilled to a depth of 171.3 m (surface to bedrock), and the second was drilled to a depth of 47.8 m from the surface.

An electro-mechanical drill with an inner diameter of 9.5 cm and a 135 cm long barrel (Geo-Tech Co., Japan), was used for drilling. With the 171.3 m borehole, the drill cutters touched bedrock. Our radar measurements of the ice thickness and bedrock topography showed that West Belukha Plateau lies on a relatively smooth flat bedrock, composed of plagiogranite and granodiorites (Berzin and Kungurtsev, Reference Berzin and Kungurtsev1996).

Ice-core densities and preliminary stratigraphic descriptions of ice layers and grain sizes were documented in the field via photographic and written records (Takeuchi and others, Reference Takeuchi2004). The core from the surface to ~40 m depth consisted of a mixture of compacted firn and bubbly ice with thin transparent ice layers related to summers (Fig. 2a). The transparent layers of ice in the ice-core sections are gradually merged into a single mass of ice below 60 m of depth based on visual inspection.

Fig. 2.

Profiles of (a) *ex-SO₄ ²⁻, ex- SO₄ ²⁻ (μEq L⁻¹), and oxygen stable isotope ratios δ ¹⁸O (‰) seasonal-annual signals from two parts of ice-core sections: from 1987 to 1997, e.g. from 5 to 2 m w.e. (1) and from 1809 to1826, e.g. from 48 to 43 m w.e. (2) of Bl2003 ice-core, and corresponding visual stratigraphy composed of a mosaic of digital pictures of ice-core sections: C.B signifies a break between the core sections; R.F. is regelated coarse-grained firn with few 1–2 mm ice crusts; F.F. is fine-grained firn with multiply 2–3 mm radiative ice crusts; C.F. is compact medium-grained snow/firn; C.I. is compact ice; CR is transparent ice interlayers identified compacted summer ice crusts. (b) The borehole temperature and (c) ice-core density (surface to the bedrock ice-core) (Takeuchi and others, Reference Takeuchi2004).

Temperature was measured every 10 m in the 171 m deep borehole (Takeuchi and others, Reference Takeuchi2004; Aizen and others, Reference Aizen2006) (Fig. 2b). From 0 °C at the snow surface, temperature dropped to −10 °C at 2 m, to −15.8 °C at 50–70 m depth and to −14.4 °C at the bottom, i.e. lower than the annual mean air temperature (−12.9 °C for the period 1973–2003; Aizen and others, Reference Aizen2005) at this elevation. The ice temperature suggests that West Belukha Plateau lies in the cold recrystallization zone, where any meltwater subsequently refreezes below the surface. Since the −14.4 °C ice temperature at the bedrock is below the eutectic temperature, there should be no ion diffusion in the Bl2003 ice core (Iizuka and others, Reference Iizuka2012).

Bulk density of the cores increased with depth, and reached 930 kg m⁻³ at ~60 m w.e. (Fig. 2c). A density/depth profile was constructed allowing the w.e. thickness to be determined. All depths from this point in the paper are presented as w.e. depths. The ice-core length is 145.87 m w.e. Using insulated boxes, the ice cores were transported frozen to the ice-core laboratory at the Research Institute for Humanity and Nature (RIHN) in Japan. There, core sections were halved lengthwise and shipped frozen to the Ice Core Laboratory at the University of Idaho (UI).

2.2. Ice-core processing and geochemical analysis

Ice-core physical stratigraphy was conducted in the UI Ice Core Laboratory, the National Ice Core Laboratory, USA and the RIHN. After detailed stratigraphic documentation, the inner part of ice from each section (4 cm × 4 cm) was cut and shipped frozen to the Climate Change Institute (CCI) at the University of Maine (UM). At the CCI dedicated ice-core laboratory, ice-core sections were melted in a modified ‘Wagenbach-style’ continuous melter system connected with multiple fraction collectors to melt the core sections into discrete, co-registered samples at 0.01–0.08 m w.e. resolution (Fig. 3a, 4252 samples). The samples were immediately refrozen to await geochemical analysis. Osterberg and others (Reference Osterberg, Handley, Sneed, Mayewski and Kreutz2006) provide full details of the melter system accuracy, precision and detection limits. Major ion analysis was performed via suppressed ion chromatography using a Dionex DX500 system at the ppb level with minimum detectable concentrations of 1 ppb.

Fig. 3.

The profiles of (a) sample length in the Bl2003 ice core and (b) oxygen stable isotope ratios, δ ¹⁸O (‰). The results received in UofI and validated with corresponding isotope data at Nagoya University.

Stable isotope ratios (δ ¹⁸O, δD) were determined via headspace equilibration at the UI Stable Isotope Laboratory using a Finnigan Delta Plus isotope ratio mass spectrometer coupled with Finnigan's GasBench II. Oxygen isotope ratios were measured using a standard CO₂ equilibration technique (Craig, Reference Craig1957) with a Micromass multi-prep device coupled to a SIRA mass spectrometer. Hydrogen isotope ratios were measured using Cr reduction with a Eurovector elemental analyzer coupled to a Micromass Isoprime mass spectrometer (Morrison and others, Reference Morrison, Brockwell, Merren, Fourel and Phillips2001). Data are reported in standard delta (δ) notation vs Standard Mean Ocean Water. The analytical precision for measurements of oxygen and deuterium isotope ratios was ±0.05 and ±0.5‰, respectively. Analytic uncertainty in d-ex was 0.5‰, calculated from the quadratic average of the uncertainty for δD and 8 × δ ¹⁸O (Froehlich and others, Reference Froehlich, Gibson and Aggarwal2002). Stable isotope ratios (δ ¹⁸O, δD) determined at UI were validated with corresponding isotope data from Nagoya University (NU), Japan (Fig. 3b). UI stable isotope samples were analyzed at 0.01–0.08 m w.e. resolution (Fig. 3a) for the 145.87 m w.e. surface to the bedrock core, while NU stable isotope samples were analyzed at 0.10 m resolution to a depth of 68.7 m w.e. (87.4 m) for the same surface to bedrock core. The NU stable isotope samples (1594 samples) were interpolated for validating the UI data.

2.3. Tritium measurements

Tritium concentrations (³H) were measured via liquid scintillation counting at National Institute for Polar Research (NIPR, Japan) by analyzing 178 samples at a resolution of 0.06–0.59 m and verified in the Idaho State University, Environmental Monitoring Laboratory USA (ISU) by analyzing seven non co-registered samples within 1 m above and below the depth of maximum concentration determined at NIPR. Average difference between the four ISU samples and the NIPR results was <13TU, i.e. <2% of the maximum concentration.

2.4. ¹⁴C radiocarbon measurements

Radiocarbon analysis of the particulate organic carbon (POC) fraction was conducted at the Laboratory of Radio and Environmental Chemistry, Paul Scherrer Institute according to the method described by Jenk and others (Reference Jenk2006) and Sigl and others (Reference Sigl2009). Prior to analysis ice-core segments were cut in the cold room to obtain sections of clear ice. Ice layers with visible high dust loading or coarse lithoidal particles were not used for dating to avoid potential age interferences of old mineral carbon with the organic carbon fraction. Ice samples were thoroughly decontaminated by removing outer layers in a three-step process (cutting with a band saw, scraping with a scalpel, rinsing with 18 MΩ cm ultrapure water) to eliminate potential contamination from sampling and handling operations. Melted samples were then filtered through quartz fiber filters (Pallflex Tissuquartz, 2500QAO-UP; prebaked) and carbonates were removed by acidification of the filter residue with 0.2 M HCl. Dried filters were combusted in a two-step process where the fractions of POC and elemental carbon are separated (10 min at 340 °C, 12 min at 650 °C) followed by cryogenic trapping and manometric quantification of the evolving CO₂ (Szidat and others, Reference Szidat2004). The CO₂ samples were sealed in glass ampoules, which were fixed to the gas handling system of the 200 kV accelerator mass spectrometer system MICADAS for ¹⁴C determination at the ETH Laboratory of Ion Beam Physics (Ruff and others, Reference Ruff2007; Synal and others, Reference Synal, Stocker and Suter2007). Results were corrected for a blank input of 1.5 ± 0.7 µgC with a fraction of modern f _m = 0.64 ± 0.11. For calibration OxCal 4.1 (Bronk, Reference Bronk2001) and the IntCal09 data of Reimer and others (Reference Reimer2009) were used.

2.5. Meteorological data

Data from meteorological stations (daily, event, monthly and annual) for the period 1950–2002 were used for climatic analysis. The Akkem station (49°54′N, 86°32′E; 2045 m) has over 50 years of instrumental record, is in close proximity to the drill site (within 10 km), sits at a relatively high elevation compared with other nearby stations, and is positioned to record the main air masses moving from the west toward the drill site (Fig. 1a) (Aizen and others, Reference Aizen2005). Barnaul station (53°17′N, 83°39 E; 185 m) data were also used because that station has the longest (1838 to present) instrumental record in the region. It is located 450 km northwest of the drill site. An AWS installed near the drill site recorded the main meteorological parameters every 3 h during 2002/03 and resulting data are highly correlated with the Akkem station data. Akkem station and West Belukha Plateau temperature data for the period, July 2002 to April 2003 are also correlated, with R ² = 0.87 (Okamoto and others, Reference Okamoto2011).

Precipitation amount and simultaneous event mean air temperature were recorded hourly at the Akkem station from 21 July 2002 to 23 July 2003. Water samples from each precipitation event were collected for determination of stable isotope ratios (δ ¹⁸O, δD).

3.1. Tritium concentrations (Fig. 4; Table 1)

Ice-core chronology was refined using radioactivity measurements (Naftz and others, Reference Naftz1996; Schwikowski and others, Reference Schwikowski, Brutsch, Gaggeler and Schotter1999; Pinglot and others, Reference Pinglot2003). The analyzed tritium concentrations with depth exhibit several notable peaks consistent with past nuclear testing. The earliest tritium peak (68.5 TU at 15.49 m w.e.) was attributed to the first historical nuclear testing maximum in 1958, while the subsequent and largest peak (reaching 772 TU at 14.11 m w.e.) was attributed to the time of maximum recorded nuclear detonations from 1962 to 1963 (Carter and Moghissi, Reference Carter and Moghissi1977; Beck and Bennett, Reference Beck and Bennett2002). Five sampled radioactive horizons related to 1963 have at least three times higher values than any others with one maximum of 772 TU. The largest peak as well as minor subsequent tritium peaks (119.6 TU at 12.82 m w.e. and 127.4 TU at 11.04 m w.e.) are consistent with relative tritium concentration peaks preserved in the East Belukha (Olivier and others, Reference Olivier2004) during the late 1960s and early 1970s, respectively.

Fig. 4.

(a) Oxygen stable isotope ratios and 1/0.5 m w.e. averages of δ ¹⁸O (‰) and (b) d-ex (‰) from the BI2003 ice core with (c) radiogenic isotope records of ³H (TU) at the top of the ice core, and (d) four ¹⁴C records at the bottom of ice core. 1 - ³H records related to 1963; 2 - ³H record related to 1958; 3 - ¹⁴C records; 4- mean of δ ¹⁸O and d-ex for ReWP.

Table 1.

Historical events recorded in Bl2003 ice-core from the Belukha Plateau, Siberian Altai

er., eruption; VEI, volcanic explosivity index; ff, forest fire.

1. Johnsen and others (Reference Johnsen1997); Kobashi and others (Reference Kobashi, Severinghaus and Barnola2008); 2. Zoller (Reference Zoller1960); 3. Alley and others (Reference Alley1997); Alley and Ágústsdóttir (Reference Alley and Ágústsdóttir2005); 4. Winkler and Wang (Reference Winkler, Wang and Wright1993); 5. Koshkarova and Koshkarov (Reference Koshkarova and Koshkarov2004); 6. Claussen and others (Reference Claussen1999); Kalugin and others (Reference Kalugin, Selegei, Goldberg and Seret2005); 7. Briffa and others (Reference Briffa1990); 8. Mann and others (Reference Mann2009); 9. Palais and others (Reference Palais, Germani and Zielinski1992); 10. Mayewski and others (Reference Mayewski1993); Meese and others (Reference Meese1997); Bradley (Reference Bradley2000); Bradley and others (Reference Bradley, Briffa, Cole, Hughes, Osborn, Alverson, Bradley and Pedersen2003); 11. Andreev and others (Reference Andreev2007); Butvilovskii (Reference Butvilovskii1993); Jacoby and others (Reference Jacoby, D'Arrigo and Davaajatms1996); Ovchinnikov and others (Reference Ovchinnikov, Adamenko and Panushkina2000); 12. Li and Ku (Reference Li and Ku2002); 13. Stothers (Reference Stothers1984); 14. Olivier and others (Reference Olivier2006); 15. Vorob'ev and others (Reference Vorob'ev, Akimov and Sokolov2004); 16. Carter and Moghissi (Reference Carter and Moghissi1977); Beck and Bennett (Reference Beck and Bennett2002); 17. Valendik (Reference Valendik, Goldammer and Furyaev1996); Eruptions dates were taken from the Global Volcanism Program (http://www.volcano.si.edu/world/largeeruptions.cfm) and (Zielinski, Reference Zielinski1995).

3.2. ¹⁴C measurements of POC (Figs 4 and 5a; Table 1)

Four depths were chosen for ¹⁴C measurements. The deepest measured horizon at 145.2 ± 0.1 m w.e. depth (0.665 m w.e. from the bedrock) corresponds to 9075 ± 1221 cal a BC, suggesting that Altai glaciers were formed during the YD. The next horizon at 142.8 ± 0.4 m w.e. (3.065 m w.e. from the bedrock) corresponds to 6197 ± 473 cal a BC, coincident with the sudden significant 8.2 ka cooling episode. Two other samples were obtained from the upper ice-core layers with sufficient organic carbon for radiocarbon dating. The corresponding ages were 135 ± 221 cal a BC at 134.6 m w.e. depth (11.2 m w.e. above the bedrock) and 790 ± 93 AD at 121.1 m w.e. depth (26.88 m w.e. above the bedrock) (Figs 4 and 5a). The dated age of a ¹⁴C measured layer was determined within the possible range of yearly deviation (i.e. ± uncertainty) according to ice flow modeled dating or other corresponding historical events such as significant volcanic eruptions (Table 1).

Fig. 5.

Ice-core isotope-chemistry records and associated historical events (Table 1) (a) at the low part of the Bl2003 ice core: (1) is from 145.8 to 134.2 m w.e., (2) is from 134.5 to 117.3 m w.e., (3) is from 117.3 to 46.2 m w.e., and (b) at the upper part of the Bl2003 ice core. Stable isotope records of δ¹⁸O (‰) are red, non-dust sulfate absolute, ex-SO₄ ²⁻ (μEq L⁻¹) and normalized, **ex-SO₄ ²⁻ (Eqn (4)) and *ex – SO₄ ²⁻ (Eqn (5)) fraction records are violet, major ions of Ca²⁺, NO₃ ⁻, K⁺ (μEq L⁻¹) are black and radiogenic isotope of ³H (TU); 1 is ¹⁴C records; 2_l, 2_h are extreme low/high temperatures; 3₅ and 3_≥6 are referred volcanic eruptions with corresponding VEI = 5 and VEI = 6 or 7; 4 is Tunguska explosion; 5 is forest fires; 6 is ³H records; 7 is strong dust storm.

3.3. Stratigraphy (Fig. 2a)

Dating of the upper ice-core sections was preliminarily assigned by counting annual (summer) layers based on detailed visible inspection of core stratigraphy. This technique was used successfully for the Greenland GISP2 ice core (e.g. Alley and others, Reference Alley1993; Meese and others, Reference Meese1997), for dating ice cores recovered from the Dunde and Guliya ice caps (Thompson and others, Reference Thompson1989), and also for shallow Tien Shan and Altai ice cores (Aizen and others, Reference Aizen2005, Reference Aizen2006). Due to the absence of regular/annual visible dust layers in Belukha ice cores, stratigraphic layer counting was achieved by identifying thin transparent ice interlayers related to summers radiation crusts. Melt percentage was found to be ~7% in the upper 30 m w.e. of the core (Aizen and others, Reference Aizen2005; Joswiak, Reference Joswiak2008), indicating an absence of percolation (Koerner and Fisher, Reference Koerner and Fisher1990). Okamoto and others (Reference Okamoto2011) also reported that percolation was absent based on detailed stratigraphic analysis of ice-core layers (the upper 33 m w.e.) coincident with maximum air temperatures.

3.4. Variability in stable isotopes (Figs 2a, 4, 5 and 6)

Ice-core chronology was also refined by counting annual layers (Figs 2a and 5b) based on stable isotope variability/seasonality (e.g. Taylor and others, Reference Taylor1992). The δ ¹⁸O and δD ratios were analyzed to determine the overall behavior of the stable isotope ratios with depth/time (Fig. 4). Stable isotope values in glacial cores are determined by air temperature during snowfall, seasonal distribution of precipitation, transport, mass exchange and distillation history of an air mass.

Fig. 6.

Dated (a) stable isotope, δ ¹⁸O (‰), (b) d-ex (‰) and major ions of (c) Na⁺, (d) K⁺, (e) Ca²⁺, (f) NO₃ ⁻ and (g) SO₄ ²⁻ records with 10-record and 30-record (bold) moving averages and averages for the ReWP (direct solid black) and for the MoWP from (dashed black) from the Bl2003 ice core.

Because the Altai Mountains are located in the center of the Eurasian continent, precipitation amount during a snowfall event is not significant. Therefore, a precipitation amount effect (Dansgaard, Reference Dansgaard1964) is assumed to be absent, and distribution of stable isotope values in the ice core mainly reflects seasonal air temperature distribution (correlation up to 0.7; Aizen and others, Reference Aizen2006), which is notably pronounced in intercontinental regions. Identification of annual accumulation layers in the ice core was based on the extreme values of δ ¹⁸O, as minimum winter and maximum summer air temperatures, which are distinctive characteristics of the Altai meteorological regime (Aizen and others, Reference Aizen2005). The stable isotope records from the surface to 51 m w.e. (Fig. 2a) yield well preserved seasonal signals of δ ¹⁸O.

The δ ¹⁸O–δD relationship in the Bl2003 ice core reveals a similar slope to the co-variance (i.e. 8) of the Global Meteoric Water Line indicating a similar initial relationship in fractionation factor pointing to the absence of percolation in the Bl2003 ice core. For different time periods, the slope varied from 8.4 to 6.1. Slopes do not approach typical sublimation/evaporation line slopes ~‘5’ (Clark and Fritz, Reference Clark and Fritz1997) (Table 2). It is unlikely that evaporative/sublimation changes that could occur at site would significantly affect the preserved ice-core records.

Table 2.

Mean characteristics of the stable isotope distribution for the different periods of the Altai glacier existence

3.5. A steady-state glacier flow model for layer thinning (Figs 7a–c)

A steady-state glacier flow model was used to determine the ice age, t (a) in the Altai ice core as a function of depth. We applied the numeric modeling of annual ice thickness, L(z) with depth initially presented by Raymond (Reference Raymond1983) and implemented by Thompson and others (Reference Thompson2000), Yao and Yang (Reference Yao and Yang2004), Davis and others (Reference Davis, Thompson, Yao and Wang2005) and Kaspari and others (Reference Kaspari2008), where

(1) $$L({z}) = {\rm A}{\rm c}{\left( {\displaystyle{{1 - z} / {H}}} \right)^{k}}$$

and

(2) $${t} = \displaystyle{{{{H}^{k}}} \over {\left[ {({k} - 1){\rm Ac}} \right]\left[ {1/{{({H} - {z})}^{{k} - 1}} - 1/{{H}^{{k} - 1}}} \right]}}$$

H (145.867 m w.e.) and z are ice equivalent thickness and depth. Ac (0.344 m w.e.) is the original layer thickness as determined from the present thickness of annual layers, e.g. from Eqn (1) the snow pit stratigraphy seasonal layers for 2002, or from Eqn (2) the thickness of snow/firn/ice between two annual timelines, i.e. for the period, 1963 (³H marked event; Section 2.1) to the present. k (1.53) is the constant determined by least squares, to minimize the discrepancy in dating.

Fig. 7.

(a) Modeled and mark-dated age/depth profiles of the Bl2003 ice core with (b) extended bottom part from 120 to 140 m w.e. and (c) from 141 to 145.87 m w.e. (d) The standard error profile, StEr (a) and (d and e) discrepancy, D2 (a and %) between modeled and mark-dated Bl2003 ice-core records. Dating validation through annual accumulation estimated for (f) each meter of w.e. and (g) marked events.

3.6. Peaks in sulfate concentrations/volcanic eruptions

Volcanic eruptions are also used as reference horizons to validate the dating (Zielinski and others, Reference Zielinski1994; Zielinski, Reference Zielinski1995; Siebert and others, Reference Siebert, Simkin and Kimberly2010; Moore and others, Reference Moore2012). For inferring volcanic source analysis, we use the Smithsonian Global Volcanism Program database of Holocene volcanism (Siebert and Simkin, Reference Siebert and Simkin2002). We considered significant volcanic eruptions with a volcanic explosivity index (VEI) ≥ 5 and focused on eruptions that are most likely recorded in Siberian Altai ice-core records, e.g. from Kamchatka, Japan (Table 1). Significant anomalies (≥2σ) of sulfate concentrations associated with volcanic eruptions were considered as markers for validation of the depth/age scale. However, significant anomalies of sulfate concentrations, SO₄ ²⁻, may also be associated with Ca²⁺ (e.g. gypsum and/or anhydrite), which originates from evaporite deposits. If gypsum and/or anhydrite were the primary soluble compound delivering SO₄ ²⁻ to the site, then a Ca⁺²/SO₄ ²⁻ equivalence ratio >1 would be expected. This was not the case for the markers of volcanic eruptions. We considered significant anomalies in sulfate (SO₄ ²⁻) with Ca²⁺/SO₄ ²⁻ equivalence ratios <1 above 46.25 m w.e. (Mt. Tambora eruption in 1815).

Below 46.25 m, e.g. during the LIA and earlier, the Ca²⁺ background and Ca²⁺ extremes were more significantly increased than SO₄ ²⁻. Therefore, to reveal the maxima related to volcanic eruptions we used only the non-dust sulfate fraction (Eqn (3); ex-SO₄ ²⁻) (Figs 5a and b; Table 1) as utilized for the Bl2001 ice-core dating (Olivier and others, Reference Olivier2006).

(3) $${\rm ex - SO}_4^{2 - } = {\rm SO}_4^{2 - }\!-\!n\;{\rm Ca}^{2 + },$$

(4) $$^{\ast\ast}{\rm ex - SO}_4^{2 - } = {\rm SO}_4^{2 - } /20\!-\!n\;{\rm Ca}^{2 - }/45\;({\rm below}\;142.8\;{\rm mw.e.}),$$

(5) $$^{\ast}{\rm ex - SO}_4^{2 - } = {\rm SO}_4^{2 - } / {2.1-n} {\rm Ca}^{2 -}({\rm above}\;17.8\;{\rm m w.e}.),$$

where n is the average ratio between SO₄ ²⁻ and Ca²⁺ concentrations for the period, 1815–99 with well-calibrated records of non-volcanic events. The value of n was reported to be 0.21 in the BL2001 ice core (Olivier and others, Reference Olivier2006) and the same value was applied for calculation of the non-dust sulfate fraction (ex-SO₄ ²⁻) (Eqn (3)) for volcanic eruption indicators in the present study.

For bottom ice-core sections (below 142.8 m w.e.), SO₄ ²⁻ and Ca²⁺ background and extreme concentrations were significantly elevated. Therefore, to compare bottom records with the other part of the ice core, the SO₄ ²⁻ and Ca²⁺ bottom records were normalized by an average basic noise factor of ‘20’ and ‘45’ (Eqn (4)), respectively (Fig. 5a), then the peaks in the non-dust sulfate fraction (**ex-SO₄ ²⁻) were the same order as those in the other periods, e.g. pre-industrial. Average basic noise was estimated as a ratio between background means during periods of elevated the SO₄ ²⁻ and Ca²⁺ concentration (i.e. YD) and background means during the pre-industrial period (PI).

For the upper part of the core (above 17.8 m w.e.), the SO₄ ²⁻ background and SO₄ ²⁻ extreme concentrations were also increased (on average 2.1 times) compared with the lower part of the core (e.g. PI). A similar procedure of normalization with an average basic noise factor of 2.1 (Eqn (5)) was applied. After normalization peaks in sulfate (*ex-SO₄ ²⁻) were the same order as those for the pre-IP (Fig. 5b).

Intensive growth in sulfate from the background with a simultaneous decline in the Ca²⁺/SO₄ ²⁻ equivalence ratio relative to adjacent records, as well as the non-dust sulfate fraction maxima (Eqns (3–5)), were also considered when assigning volcanic eruptions. The appearance of significantly depleted isotopes follows in many cases after the sulfate anomalies associated with volcanic eruptions (Fig. 5). This illustrates the impact of strong volcanic eruptions on the temporal decrease of air temperatures.

3.7. Peaks in biomass burning

The large forested areas of western Siberia and northeastern Kazakhstan are located directly upwind from the Belukha Plateau, and aerosols injected to the atmosphere by large forest fires are preserved in Altai glacier ice. Ice-core records have been used as a proxy for large fire activity by examining the variability of soluble major ions associated with smoke from fire plumes (e.g. Whitlow and others, Reference Whitlow, Mayewski, Dibb, Holdsworth and Twickler1994; Yalcin and others, Reference Yalcin, Wake, Kreutz and Whitlow2006; Olivier and others, Reference Olivier2006). Eichler and others (Reference Eichler2011) demonstrated that K⁺ and NO₃ ⁻ are suitable proxies for biomass burning and the temporal and spatial distribution of forest fires over Russia, including Siberia, is well known. The largest forest fires in the Altai Mountains and Southwestern Siberia were recorded in 1921, 1974, 1991 and 2003 (Valendik, Reference Valendik, Goldammer and Furyaev1996; Vorob'ev and others, Reference Vorob'ev, Akimov and Sokolov2004). Peaks in K⁺ potentially associated with forest fires (Fig. 5b; Table 1) were also used to validate dating at the upper part of Bl2003 ice core.

3.8. Identification of distinct layers: Tunguska meteorite event and a notable dust storm

The Tunguska explosion event (1908) corresponds to a significant nitrate peak (Henderson and others, Reference Henderson2006) in the B12003 core (at 28.5 m w.e. depth; Fig. 5b). The most pronounced visible horizon through stratigraphy analysis in the upper part of the Bl2003 ice cores is a thick dust layer dated to 1842 (Henderson and others, Reference Henderson2006; Malygina, Reference Malygina2009) at 41 m w.e. signaled by a peak in calcium (Fig. 5b). These two events were also used to calibrate dating in the upper part of the Bl2003 ice core.

3.9. Discrepancy, uncertainty and standard error

Discrepancy-1 (D1) over the upper part of the core (until 62 m w.e.) is the difference in years of an horizon dated by different techniques, i.e. tritium picks, stratigraphy/isotope analysis, and validated through volcanic eruption marks (Table 3). Discrepancy-2 (D2), considered along the Bl2003 ice core (Figs 7d and e), is estimated based on comparison between dated age/depth profile (radioactive measurements, counting annual ice layer through stratigraphy, stable isotopes, etc.) and the calculated profile using a steady-state glacier flow model for layer thinning (Section 3.5) with validation through volcanic eruption events. The absolute discrepancy (Fig. 7d) is estimated as the absolute difference in years of a horizon. Relative discrepancy is the ratio between the difference in dated years (D2) and the number of years from the surface (Table 3).

Table 3.

Measured and modeled age, and discrepancy (D1, D2), uncertainty (U1, U2) and standard errors (StEr) in dating of the Bl2003 ice core

D1 is discrepancy between dating through tritium marks (³H), sulfate (exSO₄ ²⁻) or nitrate (NO₃ ⁻) concentration marks and dating though stratigraphy or stable isotope annual signals (Stratigr/δ ¹⁸O). D2 is discrepancy between modeled and estimated age in the Bl2003 ice core; U1 is uncertainty in determining the date of marked volcanic eruption; U2 (bold font) is uncertainty in dating through four marks of ¹⁴C. U2 (Italic font) is related to interpolated uncertainty between U2 marks. StEr, (a) is standard error between dated Bl2003 ice-core records and modeled results.

Uncertainty-1 (U1), below 121.1 m w.e. is based on the uncertainty of validation referenced by volcanic eruption dating (Siebert and Simkin, Reference Siebert and Simkin2002). Uncertainty-2 (U2) is the uncertainty in ¹⁴C measurements of the four POC horizons and values of uncertainty interpolated between the four ¹⁴C measured horizons. Absolute and relative values of uncertainty are estimated in years and percent relative to mean year of a horizon (Table 3).

The standard error, StEr (a) of dated Bl2003 ice-core records relative to modeled results is estimated beginning in 1963 (for the period 1963–2003) and earlier (deeper) (Table 3; Fig. 7d). Determination of the 1963 tritium peak through the seasonal signal in isotope/stratigraphy analysis yields a discrepancy of 1 year. Comparison of modeled depth/age with 1963 radioactive markers yields a discrepancy (D2) within 1.5 years, i.e. ~3.7% of the 40 years period from 1963 to 2003. StEr of dated Bl2003 ice-core records relative to modeled (Eqn (2)) is estimated as 0.5 year from 1963 to 2003 (Table 3).

Discrepancy (D1) is 4 years at the depth of the local sulfate peak (27.56 m w.e.) as attributed to the 1912 Novarupta eruption (Table 3). Validation of modeled dating through dating by ex-SO₄ ²⁻, yields a discrepancy within 4 years, i.e. ~4%, at the 1912 horizon. Depth 117.3 m w.e., modeled to 1000 AD is validated through the Changbaishan eruption, yielding a discrepancy of 9% between modeled dating and validation through ex-SO₄ ²⁻.

The discrepancy between dated ice-core and modeled profiles is <10% above 135 m w.e. (till ~330 a BC) in the Bl2003 ice core (Table 3; Fig. 7e). Standard error between dated and modeled ice-core records at 135 m w.e. is 26 years.

Below 135 m w.e. the discrepancy increased, reaching a maximum at the bottom. Until 145.4 m w.e. (~10 900 BC) the discrepancy (D2) in dated ice-core records is within the values of uncertainty (U2) of ¹⁴C measurement (Table 3). The discrepancy does not exceed 6% at three radiocarbon marked horizons. The discrepancy in dating through radiocarbon marks and modeled dating could be explained by a deviation in accumulation rate (Fig. 7f and g) from modeled accumulation (0.344 m w.e.) during periods of variable Altai accumulation rate history.