Introduction

Recent intensification and southward migration of the Southern Hemisphere westerly winds (SHW) have been implicated in a number of important physical changes in the southern high latitudes. These include: (1) changes to the Southern Ocean CO2 sink through alterations in ocean mixing1,2,3; (2) the loss of ice shelves fringing the West Antarctic Ice Sheet and Antarctic Peninsula ice sheets through enhanced basal melting4,5,6,7,8; (3) changes to Antarctic sea ice extent9; (4) enhanced Agulhas leakage10, and (5) warming along the Antarctic Peninsula11,12,13. Many of these changes have far-reaching implications for global climate, ocean circulation, and sea level rise.

Regionally, changes in the position and intensity of the core belt of the SHW (also identified by the Southern Annular Mode, SAM index14), have influenced precipitation patterns in southern continental landmasses15,16. Notably, the recent (post-1950 CE) southward (poleward) intensification of the SHW has shifted the main moisture-carrying storm tracks away from continental regions17. This has resulted in reduced precipitation in New Zealand18,19 and droughts and wildfires in southwestern Australia20, western South Africa21, and southern South America22,23, with their associated ecological and economic impacts24.

Despite the importance of the SHW, our current understanding of how they influence Southern Hemisphere climate on longer timescales is limited by the spatial and temporal patchiness of reconstructions in their core latitudes, coupled with few modelled simulations of their observed behaviour25,26,27. This is important because we are experiencing a continued net poleward migration and intensification of the SHW primarily as a result of loss of stratospheric ozone since the 1960s28. While ozone recovery in the coming decades is expected to reverse these long term trends, especially in the austral spring-summer months, the increase in greenhouse gas-based climate warming may counteract this process, driving renewed poleward year-round intensification of the SHW29,30,31. However, the baseline natural variability of the SHW, without the added influence of ozone depletion, is not well-understood over longer timescales28. Paleoclimatic records of westerly wind behaviour can therefore help establish a framework for past SHW modalities, bridge the model-data gap, and better constrain the range of future climate change projections.

Although their distribution is increasing, past reconstructions of the SHW have been largely concentrated within Patagonia32,33,34 and to a lesser extent from the north of the core belt of the westerly winds on the continental landmasses35,36,37. Historically, reconstructions have typically relied on indirect proxies for assessing changing wind strength (e.g., changes in precipitation inferred from sub-fossil pollen assemblages, and sediment geochemistry, etc.). While several recent studies have sought to address these limitations38, there still remain few records of SHW variability from directly within their core belt. Here, we present a 700-year record of SHW from the sediments of a small lake on the west coast of sub-Antarctic Marion Island (46°S, Fig. 1, Supplementary Fig. 1), that lies on the northern margin of the SHW belt (Supplementary Fig. 2). Our reconstruction is based on tracking sea salt and minerogenic inputs using a combination of a diatom-based conductivity proxy and micro-X-ray fluorescence (XRF) measurements (see “Methods” section). We document coherent shifts in SHW intensity, which when compared with other regional records, we attribute to latitudinal shifts in the SHW linked to globally colder and warmer periods over the last 700 years.

Fig. 1: Map showing location of Marion Island and study site.
figure 1

a Map showing location of Marion Island and the core belt of the Southern Hemisphere westerly winds. Arrows mark the direction of surface winds (see also Supplementary Fig. 3). Shaded annual sea surface-level (10 m) mean wind speeds are based on NOAA blended high resolution (0.25 degree grid) vector data downloaded from (https://www.ncdc.noaa.gov/data-access/marineocean-data/blended-global/blended-sea-winds), b the location of the lake coring site at La Grange Kop on Marion Island (satellite imagery courtesy of NASA Visible Earth, https://visibleearth.nasa.gov/). Numbered sites indicate places referred to in the text: (I) Verlorenvlei, in the winter rainfall zone (WRZ) of South Africa50, (II) Îles Kerguelen, (III) West Antarctic Ice Sheet (WAIS68).

Results

The sediment record recovered from Marion Island dates to ~1300 CE based on a model incorporating 210Pb, 137Cs and 14C analyses (see “Methods” section and Supplementary Methods, Supplementary Figs. 8, 9).

Changes in sea salt aerosol deposition were tracked by shifts in sub-fossil diatom species assemblages in the sediments. These respond to changes in lake water conductivity resulting from past sea salt aerosol delivery39. A weighted averaging statistical model to reconstruct past conductivity was based on measuring the present relationship between modern diatom species assemblages and lake water conductivity in 64 lakes on the island40 (see Supplementary Methods). These changes are also tracked by a Principle Components Analysis (PCA) of the downcore samples. The second axis, which explains 14% of the variance, closely follows that of the diatom-inferred conductivity (Fig. 2).

Fig. 2: Stratigraphic diagram of diatoms from Marion Island.
figure 2

Stratigraphic diagram of the relative frequency (%) of the 6 most abundant diatom taxa, the principal components analysis first and second axes (PC1 and PC2), and the diatom-inferred conductivity (log mS cm−1) and μ-XRF-scanning PC1 results from Marion Island. Biostratigraphic zone III (1300–1450 CE) is marked by the presence of soil- and moss-associated diatoms with a high salinity tolerance, a high PC2, DI-conductivity, and more minerogenic material. Zone II (1450–1920 CE) is defined by a shift to diatoms indicative of higher water levels and lower conductivity as well as lower PC2 and minerogenic material. Zone I (1920 CE-present) shows a shift towards species with higher salinity tolerances, higher PC2 and diatom-inferred conductivity. (Note that scanning-based geochemical data is only available below 10 cm).

Diatom species in the core shift from moss- and soil-associated taxa with higher salinity tolerance (e.g., Diadesmis spp.) at the beginning of the record, to taxa indicative of fresher water lakes and pools (e.g., Aulacoseira principissa and Psammothidium confusum) circa 1450 CE. Around 1920 CE, these taxa then give way to lake/pool diatoms that are associated with higher salinity conditions (e.g., Planothidium quadripunctatum and Karayevia oblongellum) (for discussion of diatom changes see Supplementary Note 2, Supplementary Fig. 10).

Three significant sea salt aerosol zones (I, II, III) are seen in the diatom-inferred conductivity: (III) a period of high DI conductivity between 1300 and 1450 CE, followed by (II) a low-conductivity interval from 1450–1920 CE and (I) after 1920 CE, a higher DI-conductivity period, reaching a maximum in the last century (c. 1950 CE) (Fig. 2).

To test this reconstruction, we also measured changes in minerogenic deposition using µ-XRF. This method measures a combination of typically “sea-salt” derived aerosols (e.g., Cl, Br41), wind-blown (dust) as well as “crustal” minerogenic elements (e.g. Ti, Al, K, Sr, Fe, Mn41) together. We also measured Fe and other magnetic minerals using magnetic susceptibility. This “minerogenic signal” is captured by the PCA axis 1 (PC1; Fig. 2) which is dominated on the positive side by elements Fe, Ca, Ti, Sr, K, Mn. The negative side of the axis captures the more organic fraction, which is also tracked by the C, N, and δ13C measurements (for more information on geochemical changes see Supplementary Note 3, Supplementary Figs. 12, 13).

The minerogenic measurements (µ-XRF PC1) follow broadly similar trends to diatom-inferred conductivity (Fig. 2), with the highest values in the earliest part of the record and lower values between 1500 and 1800 CE. Two large amplitude changes between 1500 and 1650 CE in the µ-XRF PC1 plot (37% of the variance) relate to two large visible basic tephra deposits, whose timing is stratigraphically consistent with other tephras on the island (unpublished data).

Our reconstruction of the SHW is also validated through comparison with the instrumental records of climate changes, such as local temperature, pressure, precipitation, the SHW jet latitude and the SAM index in recent decades (Fig. 3).

Fig. 3: Comparison of instrumental, satellite, and core data from Marion Is.
figure 3

Comparison of instrumental and satellite and modelling data since the 1950s, documenting the effects of a southward intensifying SHW on the island. This is shown by a rise in the Marion Island atmospheric pressure (SLP) and temperature91 along with the Marshall SAM index14, while the mean latitude of the summer (DJF) SH Jet declines64 along with the annual precipitation91 and the inferred wind strength record (as DI-conductivity) from Marion Island. Plotted lines are linear regressions.

Combined, these sedimentary records of sea salt and minerogenic inputs document major changes in the strength of the SHW at Marion Island over the last 700 years. Of these large scale variations, three major features are apparent: (1) higher aerosol deposition and hence intensified SHW prior to 1450 CE and from 1920 CE to the present day, (2) lower aerosol deposition and hence reduced SHW between 1450 and 1920 CE, and (3) the highest inferred SHW (of the last 700-years) occurring within the last century (until 1950 CE).

Discussion

Differentiating a SHW signal from local factors

In order to confidently reconstruct SHW from lake sediments using both biological and geochemical techniques, it is necessary to disentangle the climate signal from local ecological and edaphic factors. In many lake systems, the relationship between precipitation and evaporation is the main driver of lakewater conductivity. However, on Marion Island, SHW are responsible for the delivery of saltspray to its western flanks and also the low-pressure systems which bring precipitation to the island. We can use the species assemblages to differentiate between lake level (habitat) and conductivity42 (see Supplementary Note 2; Supplementary Fig. 11), and can reliably differentiate between deep water, freshwater periods (e.g., 1450–1920 CE) and deep water, more saline periods (1920 CE to the present), thereby mitigating any conflation of water balance-driven changes in conductivity and those that are SHW wind-derived. Since the 1950s, we can also see a clear decrease in precipitation and conductivity on Marion Island, suggesting that P–E does not play a key role in conductivity at this site (Fig. 3). Additionally, the lake has a small catchment and is located on the windward side of the island, to reduce edaphic minerogenic factors that could overwhelm the climate signal.

Links between SHW and temperature

The Marion Island SHW reconstruction shows a long-term correspondence between SHW and temperature within the limitations of the record’s temporal resolution. The period of lowest inferred-wind strength on Marion Island between 1450 and 1920 CE is similar to the timing of regional declines in temperature associated with the Little Ice Age (LIA; c. 1400–1870 CE; Fig. 4). Globally, reconstructions place LIA temperatures ~0.5 °C cooler than the 1940–1990s43,44, but regionally, these temperature changes were more pronounced with 0.75 °C change in Southern Hemisphere reconstructions45 and up to 2 °C in the AUS2K reconstruction for Australasia over that same time period46. While the expression of a Southern Hemisphere Little Ice Age is spatially variable47, the majority of Southern Hemisphere extreme cold events occur between c. 1500 and 1700 CE45. Conversely, at Marion Island, periods of higher inferred wind strength before 1450 CE and from 1920 CE onwards coincide with records of both global and regional warming (Fig. 4).

Fig. 4: Comparison of results from Marion Island with regional paleoclimate records.
figure 4

Comparison of Marion Island DI-conductivity results with the Australasian 2K temperature reconstruction46, lake water level (salinity: % brackish diatoms) from Verlorenvlei in the WRZ, South Africa50, the WAIS ice core coarse particle size68 (with a 20 pt running mean in red) and the SAM reconstruction92. Orange and pink bars represent warmer periods with stronger, more poleward-shifted SHW delineated by the Marion Island biostratigraphic zones I and III.

Links between SHW, temperature, and rainfall

Links between SHW, temperature and rainfall are well established in recent regional meterological23,48,49 and paleoclimate records32,33,50,51,52. While not universal (e.g. in NZ fjords36,37) or sustained (e.g., Patagonian glacier fluctuations53), cool periods, such as the LIA, have been associated with increased rainfall. For example, in Patagonia, many records show cooler and wetter conditions beginning around c. 1450–1500 CE, associated with increased effective precipitation recorded in lakes33,54,55,56 and glacier advances53,57. Colder and wetter conditions are also seen in New Zealand and Australia during the LIA58,59,60. Nearer to Marion Island, southwestern South African records also document an increase in rainfall during this time (c. 1350–1900 CE35,50). Conversely, during warmer periods rainfall has generally decreased, especially in the period after 1950 CE.

Meridional migration of the SHW

The relationship between the most recent part of the SHW reconstruction and the increasingly positive phase of SAM (Fig. 3) is consistent with a poleward displacement of the core belt of the westerlies49 (Fig. 3); where the core belt of the SHW has moved south of Marion Island, resulting in demonstrably weaker SHW at the latitudinal belt of Marion Island since the 1950s48. This has resulted in a large increase (~1.5 °C) in temperature at Marion Island48 (Fig. 3), consistent with other sub-Antarctic islands (see also Supplementary Fig. 4)61 and the Antarctic Peninsula11 and with changes in the spatial pattern of SAM in the mid-latitudes49. With the warming climate there has been a concomitant reduction in precipitation (Fig. 3), soil and peat moisture, ice cap size, and snowfield permanence62 as well as marine nearshore productivity63. The diatom-based conductivity record reflects this change showing declining SHW strength beginning in the 1950s, as the SHW moves poleward (shown here as mean austral summer (DJF) jet latitude), and the core SHW belt and its associated storm tracks passes to the south of Marion Island49,64 (Fig. 3).

On longer centennial timescales, the spatial pattern of these changes (in SHW, temperature and rainfall) are consistent with a northward shift of the main belt of the SHW away from Antarctica during cool periods such as the LIA, and vice versa during the antecedent and more recent warm periods65. Mechanistic models of modern-day SHW behaviour show that warmer temperatures in the temperate latitudes cause the SHW to intensify and move poleward, as they do in austral summer months (DJF)66. Conversely, flattened equatorial-pole temperature gradients result in weaker, northward deflected SHW, as seen in winter months (JJA). It has been hypothesised from paleoclimate records and models that over century- to millennial- timescales, the same principles should apply, with cooler extratropical temperatures resulting in weaker, more spatially diffuse and/or northward shifted winds, and warmer temperatures driving stronger winds closer around the Antarctic margin31,32,65,67,68.

Few paleoclimate records from the high southern latitudes explicitly reconstruct SHW migration on centennial timescales. However, compilations of SHW and temperature records from the southern hemisphere continents and Antarctica reveal the likely impact of latitudinal shifts in the SHW and SAM modes (Fig. 4). For example, paleoclimate proxies from South African lake, cave, and marine records in the Winter Rainfall Zone (WRZ) suggest a link between SHW and shifting precipitation patterns over the last few millennia69. During the warm Medieval Climate Anomaly (MCA; 1000-1200 CE70), the SHW were well south of their present position, no longer impinging on the continent during winter69,71,72,73. However, with the onset of the LIA, WRZ precipitation increased with the northward migration of SHW-driven storm tracks50 (Fig. 4), resulting in the wettest climate of the late Holocene74. These patterns hold true in Australia and Southern South America as well, where record droughts were experienced during the MCA and cooler moister conditions prevailed during the LIA. However, concomitant changes to El Niño-Southern Oscillation (ENSO) and the Interdecadal Pacific Oscillation (IPO) make a clear attribution to the SHW in these regions difficult56,75.

In Antarctica, a wind strength record based on coarse aerosol particle deposition on the West Antarctic Ice Sheet also provides compelling evidence of a northward displacement of the SHW during the LIA and its reinvigoration at high latitudes in the last century (Fig. 4)68. Other Antarctic aerosol sea salt records similarly suggest a northward migration of the SHW (and shifts toward a negative SAM sign) between the MCA and the LIA, with an increasingly positive index beginning c. 1600 CE resulting from the migration of the Subtropical Ridge65,76.

In this context, the Marion Island wind reconstruction provides an important bridge connecting inferred changes in the SHW events in the Antarctic with those from South America, South Africa, and Australia. Specifically, the combined evidence suggests that the centre of the core belt of the SHW passed through Marion Island on its migration north of the island at the beginning of the LIA, and south of the island beginning c 1950 CE, the latter being confirmed by instrumental data.

Future scenarios

The apparent sensitivity of the SHW to relatively small (1–2 °C) shifts in temperature presented here provides a basis for determining future wind and storm track migration and its implications for water security and drought severity on centennial timescales. This is especially relevant in the face of ongoing drought and wildfires currently affecting southern continental regions. Under future global and regional warming scenarios, the data suggest that the SHW will continue to intensify and shift poleward, thereby enhancing the severity of droughts that have already severely affected South Africa, SW Australia, and W Patagonia, and some sub-Antarctic islands20,23,49,77 as moisture-laden storm tracks shift further south with the core belt of the SHW. On Marion Island and other sub-Antarctic islands at similar latitudes, continued climate warming in the 21st century will also likely enhance current warming and drying on the islands, as the core belt of the SHW bypasses the islands to the south, exacerbating ecological and glaciological changes already underway21,77.

Our data also confirm modelling results, which identify latitudinal shifts in the SHW over time with increased future warming78,79 and suggest that these relationships have persisted over centennial to millennial timescales31,67. The SHW-temperature relationship has important feedbacks on the climate system, not only on continental drought but also on atmospheric CO2 concentrations, and Antarctic Ice Sheet stability. Changes in the strength and location of the SHW have been linked to weakening of the Southern Ocean carbon sink both on multi-millennial38 and recent instrumental timescales1,2. Hence, further strengthening of the winds from increasing temperatures will likely exert a positive feedback through the accumulation of more CO2 in the atmosphere. The SHW also influence ocean circulation, driving warmer water masses towards Antarctica leading to increased basal melting of ice shelves and ice sheet mass loss80,81,82. Future poleward-shifted and strengthened SHW will exacerbate this process, making already unstable ice shelves and the ice sheets they buttress increasingly susceptible to melting31.

Methods

Coring and dating

Marion Island is one of a small number of sub-Antarctic islands within the northern margin of the current core belt of the SHW. Sediment cores were collected from La Grange Kop (46°56′S, 37°35′E), a small ~1 ha lake occupying a scoria cone on the western coast of Marion Island (Fig. 1). The lake is ideally positioned to accumulate sea salt and minerogenic inputs from the prevailing westerly winds (lake water conductivity = 170 μS cm 1; see Supplementary Table 1), whilst receiving minimal inputs from elsewhere on the island (for a full site description see Supplementary Note 1).

Multiple cores were extracted from the deepest point of the basin (4 m depth) using a Livingston piston corer from paired inflatable boats. The flocculant uppermost sediments were retrieved using a UWITEC corer, which was extruded and subsampled at 0.5 cm intervals in the field. Cores were shipped and stored frozen.

Age determinations were made using 14C radiometric methods on bulk organic sediments (Supplementary Table 3). Surface sediments yielded modern ages, suggesting the current absence of a radiocarbon reservoir effect. Surface sediments were dated using 210Pb and 137Cs, and the CIC method of age interpretation (see Supplementary Information). Age-depth models were generated using the software package BACON in R83.

Diatom-inferred conductivity

To reconstruct past sea salt aerosol inputs we developed a bespoke method to track past changes in lake water conductivity (which is a function of sea spray inputs) using diatom-based inference models. This utilises the strong statistical relationship between modern diatom species assemblages and lake water conductivity in 64 lakes on Marion Island40 and is applied as a transfer function (weighted averaging; r2 = 0.85, RMSE = 0.06 log mS cm−1) to reconstruct past changes in conductivity from subfossil species assemblages preserved in the lake sediments (for more information on diatom species-environment transfer functions and model development see Supplementary Methods, Supplementary Table 2, Supplementary Figs. 57).

Diatoms were isolated from the sediments using standard oxidative techniques84 and mounted on plain glass coverslips using NAPHRAX mounting medium. Taxonomic assignments were made using reference literature42 and using the reference photographs to ensure consistency with the diatom-conductivity model and amongst sub-Antarctic island analysts. At least 400 valves were identified from each slide on an Olympus BX60 microscope at 1000× magnification and phase contrast under oil immersion.

Diatoms with <1% in any one sample were excluded from further statistical analyses. PCA was performed on centred relative percentage diatom data from the lake using the software package rioja in R85. Diatom zones were delineated using constrained cluster analysis (CONISS86) and significance was assessed with the broken-stick model87.

Minerogenic inputs

An ITRAX micro x-ray fluorescence (μ-XRF) core scanner was used to track inputs of aerosols into the lake, focusing on sea salt and crustal elements in the cores. Fine-scale measurements of changes in bulk as-deposited (i.e., wet) sediment geochemistry was undertaken on flat half-core wet sediment surfaces using an ITRAX core scanner fitted with a Molybdenum (Mo) X-ray tube. X-radiography settings were 50 kV, 50 mA, 200 ms; μ-XRF; Mo settings: 30 kV, 50 mA, count time 10 s, 200 μm or 2 mm interval with 50- or 5-point moving average for 1 cm subsample interval equivalence. Machine and sample calibration was undertaken using a synthetic glass standard and XRF fused glass discs from the core at the start and end of each core-site run. Raw count per second (cps) data were analysed using the Q-spec spectra matching software (Cox Analytical). As we were interested in primarily patterns of downcore variability, data are presented as total scatter-normalisation ratios and percentages of the total scatter-normalised sum, following established total-scatter normalisation procedures88,89 rather than equivalent whole-rock percentages. This avoids creating spurious values for elements that cannot be measured (e.g., Na, Mg) or have low count values (e.g., Al, Si) when using an ITRAX Mo-tube89. The uppermost sediments were flocculent and could not be preserved intact for scanning.

Proxies controlling for within lake influences

To understand changes in sedimentology whole core magnetic susceptibility (MS) (Bartington Instruments MS2G 1 cm loop sensor, 10 s) was measured with a GEOTEK core logger using standard calibration procedures90. Biological changes were tracked using C, N, and δ13C analysis. Sediments were placed in 5% HCl to remove any CaCO3 (assumed negligible), then washed over Whatman 41 filter papers with deionised water and dried at 40 °C in a drying cabinet. When dry, samples were ground to a fine powder and stored in glass vials. Carbon isotope ratios (δ13C), percentage total organic carbon (%TOC) and percentage total nitrogen (%TN) were analysed during combustion in a Carlo Erba 1500 on<line to a VG Triple Trap and dual inlet mass spectrometer. δ13C values were converted to the VPDB scale using a within-run laboratory standard calibrated against NBS-19 and NBS-22, with C/N ratios calibrated against an Acetanilide standard. Replicate analysis of sample material indicated a precision of ±0.1‰ for δ13C and ±0.1 for C/N.