Carbon and oxygen isotopes in mummified wood reveal warmer and wetter winters in the Siberian Arctic 3000 years ago

Abstract

Paleoclimate reconstructions from the Holocene are important for defining baseline conditions in order to interpret and contextualize the effects of modern climate change. Such records are particularly lacking for Siberia, a region that represents ~ 50% of the Arctic. In addition, the majority of proxy-based paleoclimate reconstructions for the Holocene represent mean annual conditions, and few quantify winter temperature, which is particularly important for predicting the effects of global warming in Arctic environments. Here we provide the first quantitative proxy reconstruction of precipitation and temperature for both summer and winter for 3000 years ago via novel high-resolution intra-annual carbon and oxygen isotope measurements across annual growth rings of fossil wood mummified within the permafrost of far northeastern Siberia. We found that the site experienced greater precipitation year-round (~ 10% increase in summer and ~ 30% increase in winter), cooler summer temperatures, and warmer winter temperatures, compared with today. Our findings indicate that warmer winter temperatures (+ 3.0 °C above early twentieth century values) in the Arctic 3000 years ago drove higher mean annual temperature by up to 1 °C, despite the existence of cooler summers, a similar phenomenon to what is observed within today’s Arctic environments, and past intervals of extreme global warmth.

Introduction

Mean annual temperature (MAT) in the Arctic is increasing at nearly four times the rate of the global average¹, leading to a lengthened snow-free season^2,3, which affects polar species, diversity, and ecosystem function^4,5,6,7,8; hydrology⁹; global carbon cycling^10,11; and sediment transport¹². However, Arctic warming in response to rising levels of CO₂ is temporally asymmetric, i.e., winters have warmed significantly more than summers¹³.

Paleoclimate reconstructions of past Arctic climate from ice cores have mainly focused on determining mean annual conditions, and MAT in particular. However, mean annual conditions do not provide a unique or complete window into climate. For example, San Francisco, USA and Beijing, China share the same MAT and mean annual precipitation (MAP), but have very different seasonal (summer versus winter) climates. Furthermore, sites with similar summer temperatures can exhibit very different winter temperatures (e.g., Chicago, USA and Rome, Italy). As for the Arctic, one of the effects of the highly seasonal insolation (continuously dark winters, followed by summers with continuous light) is a large difference between winter versus summer temperatures. For example, during the year 2020, mean July temperature in Verhkjoyansk (Eastern Siberia) was 16 °C, while mean January temperature was − 43 °C [Ref.¹⁴].

Reconstructions of Arctic seasonality are lacking compared to other Holocene climate records, and Holocene records of winter conditions are completely absent for Arctic Siberia [e.g.,¹⁵]. The Siberian Arctic houses a significant store of permafrost carbon; therefore, defining baseline conditions for this region is crucial to interpreting and contextualizing the effects of modern climate change. For example, the PAGES Arctic 2k database of Holocene climate reconstructions¹⁶ consists of fifty-six records, only five of which come from sites located between Scandinavia (30 °E) and Alaska (162 °W) (and all are summer temperature reconstructions)^17,18,19,20, a region that represents ~ 50% of the Arctic. In order to augment this gap in our knowledge, we performed high-resolution stable carbon (δ¹³C) and oxygen (δ¹⁸O) isotope analysis on the annual growth rings of 3000 year-old fossil wood to provide the first proxy reconstruction of whole-year seasonal precipitation and temperature within Arctic Siberia.

Field site

We collected mummified fossil wood from an outcrop located along the Kolyma River in eastern Siberia (68.63°N, 159.15°E; Duvanny Yar, Sakha Republic, Russia; Fig. 1A). This outcrop is considered a model stratigraphic deposit for interpreting pre-industrial Arctic environmental change²¹. Mummified wood samples (cf. petrified) were excavated at this site from incised channel deposits above the organic-rich Pleistocene yedoma silt (Fig. 1B,C), a vast loess deposit containing ~ 500 Gt of carbon²². In order to obtain reliable ages for the exceptionally well-preserved mummified wood, we extracted α-cellulose from bulk wood using the modified Brendel method (see “Methods”). The clean, chemically pure α-cellulose was then radiocarbon dated to 2840 (sample DY2) to 2890 (sample DY4) ¹⁴C BP (± 20 years) at the National Ocean Sciences Accelerator Mass Spectrometry Facility at the Woods Hole Oceanographic Institution (calibrated ages with 95% probability: DY2 = 1077 to 920 cal BCE, DY4 = 1192 to 1005 cal BCE; OxCal online, Version 4.4), indicating that the plants were growing after loess deposition of the yedoma silt. The fragmentary specimens and limited number of rings in each sample precludes cross-correlation between samples.

Figure 1

(A) Location of Duvanny Yar (yellow square) and Cherskiy, Russia (green circle). Base map was generated using "pscoast," part of the freely available Generic Mapping Tools package, version 4, previously at http://woodshole.er.usgs.gov/mapit/. (B) Outcrop view of Duvanny Yar showing the yedoma sediments slumping down towards the Kolyma River. (C) Photograph of cut cross-section of mummified wood (DY2) showing distinct earlywood (light brown) and latewood (dark brown) anatomy. (D) Average monthly precipitation (teal bars, 1980–2020) and temperature (red curve, 1900–2020). See Supplementary Information for climate data.

Modern environmental conditions

Today, the site experiences a continental, Arctic climate with open Larix (Larch) forest and shrub vegetation (e.g., Pinus pumila; dwarf Siberian pine). Mean annual temperature (MAT, 1900–2021) determined using CRU TS v.4.06 reanalysis data is -12.7 ± 1.1 °C [Ref.¹⁴] (Supplementary Information) (Fig. 1D). A short (2006–2022), unpublished instrumental temperature record is also available for the nearby village of Kolymskoye, located 17 km to the northwest of the field site at Duvanny Yar. Comparison of the CRU TS v.4.06 reanalysis data for the period of overlap (16 years) reveals nearly identical mean monthly temperatures (mean difference = 0.1 °C, Pearson’s r = 0.99, n = 192 months), demonstrating reliability in the reanalysis data. Mean annual precipitation (MAP) from a weather station in Cherskiy, Sakha Republic, Russia (68.74°N, 161.40°E) is 236 ± 54 mm (1980–2020), and correlates well (Pearson’s r = 0.74, n = 8) with an overlapping, but short precipitation record from Kolymskoye (2013–2022). The majority of precipitation falls during summer months (P_s, defined as May through October = 156 ± 45 mm) with lesser precipitation during winter (P_w, November through April = 80 ± 27 mm). Snowfall generally occurs through May, and reaches maximum depth in late April²¹. The warm month mean (T_max) and cold month mean (T_min) temperatures are 9.5 ± 1.2 °C and − 35.3 ± 2.4 °C, respectively (median ± 1σ). The growing season is short; only 3 months (June to August) experience average temperatures > 5 °C.

Methods

Consecutive growth rings from four wood pieces (DY1, DY2, DY3, and DY4) were subdivided by hand using a razor blade, parallel to the growth rings, as per our previous studies on modern and fossil wood^{23,24,25,26,27,28,29,30}. Fossil specimens showed distinctive rings in hand sample with discernable earlywood and latewood anatomy (Fig. 1C); therefore, the direction of growth was known. Each of the fossil rings was divided into 8–30 subsamples (average slice thickness: 55 to 187 µm) for δ¹³C analysis (n = 16 rings and 247 δ¹³C measurements) and 8–24 subsamples (average thickness of the subsamples ranged from 73 to 182 µm) for δ¹⁸O analysis (n = 17 rings and 216 δ¹⁸O measurements). Ring numbers and subsamples do not correspond across δ¹³C and δ¹⁸O analyses and cannot be matched within each fossil wood sample (δ¹³C and δ¹⁸O measurements were determined on different sections of the same fossils). All δ¹³C measurements were made on whole wood and δ¹⁸O measurements were made on α-cellulose^31,32.

Cellulose was isolated from each subsample for δ¹⁸O analysis using a method modified from [Refs.^33,34]. The subsamples were placed into 1500 µl polypropylene micro centrifuge tubes and a 10:1 ratio of 80% acetic acid to 70% nitric acid was added to the samples. The subsamples were then agitated using a standard vortex mixer (Fisher Scientific), centrifuged for a minimum of 5 min at 12,000 rpm, and heated in an aluminum block at 120 °C for 30 min before being allowed to cool to room temperature. The liquid was decanted and the subsamples were rinsed twice with 1000 µl of 99% ethanol and once with 1000 µl of deionized water. Next, 300 µl of a 17% sodium hydroxide (NaOH) solution was added, and after 10 min, the subsamples were rinsed with 1000 µl of deionized water. A solution containing 36 µl acetic acid and 260 µl deionized water was then added, followed by a final rinse with 300 µl of 99% ethanol and 300 µl of acetone in successive steps. The subsamples were then dried overnight at 50 °C in a drying oven (Thermo Scientific Precision). Percent cellulose, measured in two samples, averaged 20% (DY2) and 16% (DY4), approximately half the amount of modern wood³¹.

Each subsample was weighed singly into tin capsules for δ¹³C analysis of whole wood and into silver capsules for δ¹⁸O analysis of α-cellulose (DY1 and DY3 in singlicate; DY2 and DY4 in duplicate). Stable isotope values were determined using a Delta V Advantage Isotope Ratio Mass Spectrometer (IMRS) joined with a Thermo Finnigan Elemental Analyzer (Flash EA1112 Series, Bremen, Germany) (δ¹³C analysis) or a high temperature conversion elemental analyzer (TC/EA) (Thermo Fisher, Bremen, Germany) configured with a zero-blank autosampler (Costech Analytical, Valencia, CA, USA) (δ¹⁸O analysis). Quality control samples (δ¹³C: JGLUC; δ¹⁸O: JCELL2) were analyzed as unknowns within each batch run. Over the course of the analyses, the JGLUC and JCELL2 quality control sample averaged (± 1σ) − 10.64 ± 0.22 ‰ (n = 15) and 20.54 ± 0.10‰ (n = 27), respectively [calibrated reference values are − 10.52‰ (JGLUC) and 20.44‰ (JCELL2)]. All isotope values were expressed in delta notation in units per mille (‰).

Data analysis was preformed in R Studio version 4.3.0 [Ref.³⁵] (Supplementary Information). Uncertainty in all equations was propagated using a Monte Carlo resampling approach, which is detailed in the Supplementary Information.

Results

All samples showed a seasonal change in δ¹³C_wood and δ¹⁸O_cell value through each growth year (Figs. 2, 3, Tables S1, S2), similar in shape to the intra-ring patterns observed in modern wood from other high-latitude and Arctic sites^24,25.

Figure 2

High-resolution carbon isotope measurements on fossil wood. Vertical dashed lines mark ring boundaries; growth is from left to right. Analytical precision (± 1σ) for each δ¹³C value was ± 0.2‰. For illustration, δ¹³C_max and δ¹³C_min values for DY1 are indicated; all data are reported in Tables S1 and S3.

Figure 3

High-resolution oxygen isotope measurements on fossil cellulose. Vertical dashed lines mark ring boundaries; growth is from left to right. Error bars in (B) and (D) indicate the ± 1σ uncertainty based on duplicate analyses; analytical precision (± 1σ) was ± 0.1‰ for individual measurements. For illustration, δ¹⁸O_cell(max) and δ¹⁸O_cell(min) values for DY1 are indicated; all data are reported in Tables S2 and S4.

Determination of paleoseasonality

We used δ¹³C_wood data collected across annual growth rings to quantify summer and winter precipitation (P_s: May through October, and P_w: November through April) using a published relationship between intra-ring carbon isotope analyses and precipitation^24,25. This relationship was calibrated via an analysis of 33 high-resolution δ¹³C profiles and 286 annual growth rings from evergreen trees growing across a wide range of environments (including high latitude sites in Sweden and Siberia)²⁴, and has been used to reconstruct precipitation seasonality from living trees²⁸ and using significantly older fossils (Miocene to Eocene in age) collected from Arctic^26,27, Antarctic³⁶, and monsoon environments³⁰.

The δ¹³C values measured within annual growth rings are related to seasonal precipitation via the following (R² = 0.96) [Ref.²⁴]:

$$\Delta \left( {\updelta^{{{13}}} {\text{C}}_{{{\text{wood}}}} } \right) = 0.0{1}L - 0.{82}\left[ {{\text{ln}}\left( {{\text{P}}_{{\text{s}}} /{\text{P}}_{{\text{w}}} } \right)} \right] + 0.{86}$$

(1)

Within the above, P_s/P_w is the ratio of summer to winter precipitation as a measure of seasonality; L (latitude, in degrees) = 68.63 and Δ(δ¹³C_wood) is the difference between the maximum δ¹³C value of a given ring (δ¹³C_max) and the preceding minimum δ¹³C value of the annual cycle (δ¹³C_min) [Δ(δ¹³C) = δ¹³C_max – δ¹³C_min]. Using Eq. (1) and the δ¹³C_wood data gained from 16 fossil tree-rings analyzed at high resolution (Fig. 2) we calculate median P_s/P_w = 1.6, suggesting a summer-dominated precipitation regime 3000 years ago, but with a larger fraction of wintertime precipitation compared to the modern meteorological records (P_s/P_w = 2.1; 1981–2019) (One-sided Wilcoxon rank sum test, p < 0.001).

Although Eq. (1) relates Δ(δ¹³C_wood) to P_s/P_w, Ref.²⁴ noted that reconstructed P_s/P_w ratios can be used to quantify P_s and P_w directly, provided independent constraints on mean annual precipitation (MAP), given that:

$${\text{MAP }} = {\text{ P}}_{{\text{s}}} + {\text{ P}}_{{\text{w}}}$$

(2)

Modeling work by [Ref.³⁷] suggest the site experienced 0.125 mm/day more precipitation 3000 years ago than present (0.125 mm/day = 46 mm/year), yielding a reconstructed Holocene MAP (MAP3ka) for the site 3000 years ago = 282 ± 55 mm. The MAP3ka resamples range from 63 to 516 mm, encompassing all published hydroclimate estimates for this region during this time window^15,38. An estimate for maximum MAP3ka using the upper limit of the [Ref.³⁷] estimate (0.25 mm/day wetter than modern) would equate to 307 mm, or approximately the 68th percentile of the MAP3ka resamples, providing a conservative range of values with high uncertainty to account for relatively few independent paleo-MAP constraints for the region.

By solving Eqs. (1, 2) simultaneously, we determined consensus median (± 1σ) P_s = 170 ± 56 mm and P_w = 103 ± 50 mm for the site based on 10,000 solutions that incorporate uncertainty in MAP, P_s and P_w (Fig. 4) (see Supplementary Information). The estimations suggest that the site experienced an absolute increase in precipitation year-round 3000 years ago relative to present (P_s = + 14 mm, P_w = + 23 mm), which equates to ~ 10% greater precipitation in the summer months and ~ 30% increase in winter precipitation (Fig. 4). Because the P_s/P_w ratios directly quantified from the Δ(δ¹³C_wood) proxy are lower than modern conditions, and independent modeling efforts suggest a slight increase in MAP values 3000 years ago, the estimated P_s and P_w values each are clearly higher than late twentieth century meteorological observations (One-sided Wilcoxon rank sum tests, p < 0.001 for each).

Figure 4

Results of annually resolved estimates of summer (P_s, A) and winter (P_w, B) precipitation using 3000-year-old wood fossils. Kernel density plots (right) show the distribution of consensus proxy estimates compared to modern values. Proxy estimates, determined from δ¹³C_wood and Eqs. (1, 2), are shown as median values (colored symbols) and 95% confidence interval (error bar) calculated from Monte Carlo resampling. Symbols and annual bars along the top of each plot are colored according to precipitation anomaly, calculated as the difference between the proxy value and Cherskiy weather station (1981–2000 C.E.) (positive values = more precipitation 3000 years ago).

We used δ¹⁸O_cell data collected across annual growth rings to quantify warm-month mean temperature (T_max) using a published empirical relationship between intra-ring oxygen isotope analyses and temperature. This relationship was calibrated from a dataset of intra-ring oxygen isotope measurements on modern wood cellulose from 33 globally distributed sites, including 10 sites with below-freezing cold-month mean temperatures²⁵. The δ¹⁸O_cell values measured within annual growth rings are related to changes in seasonal temperature via the following equation (R² = 0.82) (see Supplementary Information) [Ref.²⁵]:

$$\Delta \left( {\updelta^{{{18}}} {\text{O}}_{{{\text{cell}}}} } \right) = \left[ {\left( {{17}.{\text{57T}}_{{{\text{max}}}} } \right)/\left( {{39}.{89 } + 0.{\text{44T}}_{{{\text{max}}}} } \right) - \left( {{17}.{\text{57T}}_{{{\text{grow}}}} } \right)/\left( {{39}.{89 } + 0.{\text{44T}}_{{{\text{grow}}}} } \right) + 0.00{82}\left( {{\text{P}}_{{\text{w}}} - {\text{ P}}_{{\text{s}}} } \right)} \right] /{ 1}.{13}$$

(3)

Within the above, T_max and T_grow are the average warm month temperature and the average minimum growing season temperature (°C); ∆(δ¹⁸O_cell) is the difference between the maximum and minimum δ¹⁸O_cell value within each ring [∆(δ¹⁸O_cell) = δ¹⁸O_cell(max) – δ¹⁸O_cell(min)]; P_w and P_s were calculated using Eq. (2), as reported above. For the analysis above, T_grow was set to be a uniform distribution between 1 and 5 °C [after Refs.^8,39,40] in order to account for uncertainty in growth strategy and timing of the start of the growing season. Using Eqs. (1–3), we reconstructed a consensus median T_max estimate across all 17 rings = 8.5 ± 4.4 °C (Eq. 4) (Fig. 5A) (Supplementary Information), which is significantly cooler than median T_max of reanalysis temperatures from 1900–2021 (9.5 ± 1.2 °C) (One-sided Wilcoxon rank sum test, p < 0.001).

Figure 5

Results of annually resolved estimates of warm month (T_max, A) and cold month (T_min, B) average temperature using 3000-year-old wood fossils. Kernel density plots (right) show the distribution of proxy estimates across all samples compared to modern values. Proxy estimates, determined using δ¹³C_wood, δ¹⁸O_cell, and Eqs. (1–4), are shown as median values (colored symbols) and 95% confidence interval (error bar) calculated from Monte Carlo resampling. Symbols and annual bars along the top of each plot are colored according to temperature anomaly, calculated as the difference between proxy value and the CRU TS v.4.06 reanalysis data (1971–2000 C.E.) (positive values = warmer temperatures 3000 years ago).

We can use calculated T_max values to quantify T_min, provided an independent estimate of MAT because MAT can be approximated as an average of T_max and T_min, as confirmed across a global dataset at 10' spatial resolution²⁵. Equation 4, below, was verified for all land areas, including the CRU TS v.4.06 reanalysis data used here (1900–2021, mean difference = 0.2 °C), by comparison with MAT calculated using all 12 months of the year (R² > 0.99, n = 566,262) [Ref.²⁵], where:

$${\text{MAT }} = \left( {{\text{T}}_{{{\text{max}}}} + {\text{ T}}_{{{\text{min}}}} } \right) /{ 2}$$

(4)

We determined pre-industrial MAT using reanalysis temperatures from 1900–1925 C.E. (− 13.6 ± 0.5 °C) and then adjusted the temperatures upward for MAT 3000 years ago assuming warming of 0.5 ± 0.5 °C, based on Holocene long-term warming trends proposed by [Ref.⁴¹], and consistent with latitudinal temperature gradients^42,43. The 10,000 resamples for MAT 3000 years ago (MAT_3ka) have a median ± 1σ = − 13.1 ± 0.7 °C and a wide range (− 16.7 to − 8.4 °C) to account for the lack of independent constraints for the region [e.g.,^15,44,45]. Using our estimates of T_max determined above, we quantified median T_min = − 34.7 ± 4.6 °C (Eq. 4) (Fig. 5B) (Supplementary Information), which is 3 °C warmer than T_min values from the early twentieth century temperatures (1900–1925 C.E.; T_min = − 37.7 ± 2.5 °C) and 0.6 °C warmer than median T_min across the full temperature record (1900–2021 C.E.; − 35.3 ± 2.4 °C), consistent with a significant shift in central tendency towards higher T_min values 3000 years ago (One-sided Wilcoxon rank sum test, p < 0.001).

Discussion

Our determination of increased winter and summer precipitation 3000 years ago, relative to pre-industrial values for the region (Fig. 4), is similar to modern changes observed between 1981 and 2020 (Fig. 6). Across the instrumental record, P_s and P_w have both increased (P_s = 1.4 mm/year, P_w = 1.2 mm/year; F-test, p < 0.05 for each), resulting in an increase in precipitation of 31% (P_s) and 58% (P_w) when comparing the 2010s to the 1980s. Across the years 2011–2020, values for P_s (180 ± 54 mm) and P_w (105 ± 39 mm) are now similar to those determined here for 3000 years ago (P_s = 170 ± 57 mm; P_w = 103 ± 50 mm).

Figure 6

Historical precipitation (A–C) and temperature (D–F) data for 1981–2020 C.E. Stripes represent anomalies, calculated as the difference between each annual value and the 1971–2000 C.E. mean value from CRU TS v.4.06 reanalysis data (temperature) and the 1981–2000 C.E. mean value from the Cherskiy weather station records (precipitation). These data reveal a significant increase in precipitation across all seasons and clear bias in seasonal warming towards winter.

As for temperature, our results show that the relatively slight increase in mean annual temperature in the Siberian Arctic 3000 years ago relative to pre-industrial values^15,41,42,43 was due to notably increased winter temperatures, despite cooler summers (Fig. 5). Within modern records, winter temperatures (November through January) have increased at triple the rate (0.95 °C/decade versus 0.35 °C/decade, 1981–2020) compared to summer temperatures (June through August), with MAT increasing at an intermediate rate of 0.65 °C/decade (Fig. 6). This work demonstrates greater sensitivity of winter versus summer temperatures in the Siberian Arctic region to climate change and the importance of winter temperatures in driving changes in MAT, both 3000 years ago and at present.

Models of future warming project amplification of this asymmetric seasonal warming through CO₂ forcing⁴⁶, with winter temperatures in the Arctic increasing a further 7 to 13 °C, while summer temperatures warm a more modest 2 to 5 °C by the end of this century⁴⁷. Although the current rate of temperature increase in the Arctic is unprecedented within the historical record⁴⁸, our novel high-resolution data provide key insight on the full effects of industrialization on Arctic seasonality, including warmer and wetter winters.

Expressions of winter temperature and precipitation within the earth system are myriad, and include increased primary production⁴⁹, reduced surface albedo due to earlier leaf-out^50,51, and enhanced ecosystem respiration resulting in lower net carbon uptake⁵². All of these have the potential to alter permafrost and the associated carbon stores within. The IPCC estimates that Arctic and boreal permafrost soils contain 1460 to 1600 Gt of organic carbon⁵³ with approximately one-third (~ 500 Gt) contained within yedoma sediments²². There is much uncertainty in how warming will affect soil carbon loss⁵⁴, but recent model predictions indicate winter warming will increase CO₂ loss by 17–41% within permafrost regions⁵⁵. This will more than offset any potential increases in plant productivity driven by moderate summer warming⁵⁶, particularly if permafrost thaw is abrupt⁵⁷.

Much of our baseline climate data for the Arctic are limited spatially (e.g., Arctic Canada and Greenland) or to only the most recent decades^16,58,59. Ice-core data from the Greenland Ice Sheet provide millennial-scale records of mean annual climate⁶⁰, while other longer-term records (e.g., marine foraminifera), may contain seasonal biases that hamper interpretations of long-term warming versus cooling trends^44,61,62. Moreover, such analyses focus on measurements of sea surface temperature within low latitude regions due to the scarcity of applicable data from high-latitudes⁴⁵. Limited, high-latitude terrestrial proxies, such as stable isotope analyses of relict pore ice in permafrost (summer temperature proxy) and ice wedges (winter temperature proxy) indicate millennial-scale trends in seasonal warming in the western Arctic (e.g., western Canada)^63,64, while tree-ring width data from western Siberia show a long-term summer cooling trend prior to industrialization⁶⁵. As we work to further resolve the history of carbon-cycling throughout the Holocene, knowledge of seasonality will be critical to evaluating the dynamic nature of this large carbon pool.

Conclusions

Globally, more than 75% of proxy temperature data for the Holocene represent mean annual conditions, and less than 2% represent winter temperatures⁶²; thus we have very little insight into the seasonality of the past. Within the Arctic, especially, existing data are disproportionately focused across northern parts of Europe and North America, and, like records from lower-latitudes, limited to estimates of long-term, mean annual conditions, or only partial-year seasonality¹⁶. Here we used a high-resolution method to demonstrate warmer winter temperatures and higher winter precipitation 3000 years ago, within a severely understudied region of the Arctic: eastern Siberia. Our findings support trends observed today of amplified winter warming under elevated MAT: the fossil plants we analyzed experienced warmer cold-month temperatures 3000 years ago relative to twentieth century temperatures. However, in contrast to expectations, warm-month temperatures were cooler than present, despite a warmer MAT. Today, the climate of eastern Siberia is changing in a similar fashion: increases of + 2.9 °C and + 60% in winter temperature and precipitation, respectively, over the last 30 years. From this we suggest that high MAT values in the Arctic accompanied by increased precipitation and decreased temperature seasonality (i.e., winter temperatures are closer to summer temperatures) are fundamental features of high-latitude environments.

In past intervals of extreme global warmth, the Arctic experienced similar, proportional increases in precipitation across all seasons²⁷ and asymmetric seasonal warming [e.g.,⁶⁶], but these results are for periods with very high CO₂, stable hot greenhouse climates, and ice-free conditions. The record of whole-year seasonality produced here highlights the importance of seasonal climate (temperature and precipitation) on mean annual trends and represents a critical advance in our understanding of changes in climate seasonality in the Arctic under a warmer climate comparable to present and near-future climate predictions.

Warming of Arctic regions is a periodic feature of the geologic record, at times leading to profound changes in the distribution of life on our planet (e.g., the lush Arctic forests of the middle Eocene⁶⁷). The twentieth century onset of today’s Arctic warming was not the result of uniform changes throughout the year¹³; our results show that temporal heterogeneity during climate change, with pronounced warming during winter, was also in place 3000 years ago.