1 Introduction

Millennial-scale climate variations during the last glacial period (Dansgaard–Oeschger (DO) cycles and Heinrich events) are well documented in ice core and marine proxy records (Rasmussen et al., 2014; Davtian and Bard, 2023; Martrat et al., 2007; Dansgaard et al., 1993). Abrupt warming is recorded within decades in ice cores at the onset of Greenland interstadials (GIs), followed by gradual cooling, forming a repeated saw-shaped pattern (Rasmussen et al., 2014; North Greenland Ice Core Project members, 2004). Coarse-grained layers of ice-rafted debris in the North Atlantic are markers of Heinrich events (Heinrich, 1988), which are associated with pronounced declines in sea surface temperatures and major changes in oceanographic conditions, including weakened Atlantic Meridional Overturning Circulation (AMOC) (Martrat et al., 2007; Davtian and Bard, 2023; Bohm et al., 2015) and expanded sea ice in the North Atlantic (De Vernal et al., 2006). Millennial-scale climate events can be detected in terrestrial records from Europe during the last glacial period including lake sediments and paleoecological records (Duprat-Oualid et al., 2017; Guiot et al., 1993; Wohlfarth et al., 2008; Ampel et al., 2010; Fletcher et al., 2010; Stockhecke et al., 2021), loess (Prud'homme et al., 2022; Újvári et al., 2017), and speleothems (Genty et al., 2003; Spötl and Mangini, 2002; Genty et al., 2010). Pollen deposited in marine sediment cores off the coast of the Iberian Peninsula and France confirms that these millennial-scale events occurred in Europe synchronously with oceanographic changes (Sánchez Goñi et al., 2000, 2008). Yet, there is a lack of continuous quantitative estimates of temperature fluctuations across these events from the European continent, limiting our understanding of the magnitude of potential millennial-scale climate variability in terrestrial environments. The sparse proxy data lead to divergent interpretations of the magnitude of temperature change associated with these millennial-scale events and, in particular, the role of changing seasonal conditions in driving observed changes in proxy records.

Glycerol dialkyl glycerol tetraethers (GDGTs) provide a unique opportunity to quantitatively estimate past temperatures over continental regions. Branched GDGTs (brGDGTs) are bacterial membrane lipids and are found in a wide range of environments including lakes, soils, loess, and marine environments (Hopmans et al., 2004; Schouten et al., 2013; De Jonge et al., 2014; Xiao et al., 2016; Raberg et al., 2022). The source organisms for these lipids are not well constrained; however, recent research has shown that certain strains of Acidobacteria produce brGDGTs in culture (Halamka et al., 2023; Chen et al., 2022; Sinninghe Damsté et al., 2011). Temperature has repeatedly been shown to drive brGDGT distributions, particularly the degree of methylation, and this relationship can be demonstrated in laboratory experiments (Martínez-Sosa et al., 2020; Martínez-Sosa and Tierney, 2019; Halamka et al., 2023), global datasets (Raberg et al., 2022, 2021; Martínez-Sosa et al., 2021; Naafs et al., 2017; Dearing Crampton-Flood et al., 2020; Weijers et al., 2007; De Jonge et al., 2014; Russell et al., 2018), and in situ monitoring (Zhao et al., 2021). brGDGTs preserved in lake sediments can provide continuous, high-resolution records of past temperatures, and research in recent years has focused on expanding global calibration datasets for the lacustrine brGDGT paleothermometer. Initial studies interpreted brGDGTs in lacustrine sediments as derived from soil (Hopmans et al., 2004); however, it is now established that the majority of lacustrine brGDGTs are produced within the aquatic environment (Bechtel et al., 2010; Tierney and Russell, 2009; Tierney et al., 2010; Van Bree et al., 2020; Weber et al., 2018, 2015; Zhao et al., 2021; Wang et al., 2023). Recent global calibrations have shown that brGDGTs are sensitive to the temperature of months above freezing (TMAF), likely because bacterial growth is substantially lower below freezing temperatures, and ice cover on lakes disconnects lacustrine brGDGT producers from atmospheric conditions (Dearing Crampton-Flood et al., 2020; Martínez-Sosa et al., 2021; Raberg et al., 2021; Cao et al., 2020). The two most recent lacustrine brGDGT-temperature calibrations have errors of 2.1–2.9 °C across a diverse set of lakes spanning the globe (Raberg et al., 2021; Martínez-Sosa et al., 2021), proving this proxy can effectively be utilized for quantitative past temperature reconstructions.

Despite the ubiquitous relationship between temperature and brGDGT distributions, challenges remain for interpreting paleoclimate records from brGDGTs. Factors other than temperature are known to affect brGDGT distributions, which may lead to biases in temperature reconstructions. These non-climatic factors include oxygen and/or water depth (Weber et al., 2018, 2015; Van Bree et al., 2020; Halamka et al., 2023; Stefanescu et al., 2021), salinity (Wang et al., 2021), pH (De Jonge et al., 2014; Parish et al., 2023; Martínez-Sosa and Tierney, 2019), and conductivity (Raberg et al., 2021). Furthermore, changes in the sources of brGDGTs can dramatically impact temperature reconstructions; brGDGTs produced in soils will produce a warm bias when input to a lacustrine calibration equation (Ramos-Román et al., 2022; Martin et al., 2020). Within-lake variations in bacterial communities could also produce different temperature signals, with a cold bias from GDGTs produced at depths below the thermocline (Van Bree et al., 2020; Weber et al., 2018; Stefanescu et al., 2021; Sinninghe Damsté et al., 2022).

In this study, we measured brGDGTs in a composite lake sediment record from Eifel maar lakes (Sirocko et al., 2021) to reconstruct TMAF at multi-centennial resolution. Modern samples were utilized to test brGDGT temperature calibrations, and we use an isomer that is only produced in anoxic settings to correct for biases that occur when a large portion of brGDGTs are produced in the hypolimnion of stratified lakes. The temperature record provides a unique insight into millennial-scale climate variability and changing seasonal temperature gradients in central Europe during the past 60 000 years.

Figure 1

Location map. (a) Spatial correlation of annual temperature at the ELSA site compared with regional surface temperatures over the period 1900–2015. Data are from NOAA-CIRES-DOE 20th Century Reanalysis V3 (Compo et al., 2011; Slivinski et al., 2019). Map made using KNMI Climate Explorer (Trouet and Oldenborgh, 2013). (b) Topographic map of the sample sites for this study. AU is for Auel Maar, GM is for Gemündener Maar, WM is for Weinfelder Maar, HM is for Holzmaar, and SM is for Schalkenmehrener Maar. Topographic data are from https://www.naturalearthdata.com/ (last access: 12 June 2023).

[Figure omitted. See PDF]

2.1 Study area and sample collection

The Eifel Volcanic Field of western Germany features more than 250 Quaternary-age scoria cones (Schmincke, 2007) and is well known for its maar basins, 7 of which are currently lakes, while another $\mathit{>}\mathrm{60}$ have been filled with sediments (Sirocko, 2016). The modern climate of the region is a temperate oceanic climate (Cfb), with cool winters (mean January temperature $=$ 0 °C), warm summers (mean July temperature $=$ 16 °C), and precipitation distributed throughout the year (mean annual precipitation $=$ 817 mm) (Deutscher Wetterdienst, Climate Data Center). The modern landscape is a mosaic of agricultural areas, urban land use, and patches of deciduous broad-leaved forests or mixed coniferous broadleaved forests.

The Eifel Laminated Sediment Archive (ELSA) project has systematically drilled maar features in the Eifel (Sirocko, 2016). Five maar sites (Table 1; Fig. 1) are relevant for the current study: Auel (dry) Maar (AU), Gemündener Maar (GM), Weinfelder Maar (WM), Holzmaar (HM), and Schalkenmehrener Maar (SM). Sediment cores obtained from Auel Maar (AU3, AU4), Holzmaar (HM3, HM4), and Schalkenmehrener Maar (SMF1, SMF2) were used to build a continuous 60 000-year record (ELSA-20 stack), which has previously been investigated for changes in vegetation (Sirocko et al., 2016, 2022), lake productivity (Sirocko et al., 2021), floods (Brunck et al., 2016), and dust (Fuhrmann et al., 2021). The chronology for the ELSA-20 stack is based on a combination of varve counts, marker layers, pollen stratigraphy, radiocarbon ages, and tuning of high-resolution C${}_{\mathrm{org}}$ data with the NGRIP ${\mathit{\delta }}^{\mathrm{18}}$O record (Sirocko et al., 2021, 2022). For our downcore analysis of GDGTs, 317 samples were analyzed, with each sample typically spanning 10 cm. On average (median), each sample represents $\sim \mathrm{43}$ years, and the interval between each sample midpoint is 116 years (range 14–1380 years); the temporal resolution is lower for the period 24 000 yr b2k (years before 2000 CE) to present. Samples from Auel Maar represent the period 58 340–14 300 yr b2k, Holzmaar represents 14 200–690 yr b2k, and Schalkenmehrener Maar represents 630–0 yr b2k.

Table 1

Summary of study sites and their properties. MAAT is for mean annual air temperature, and TMAF is for temperature of months above freezing. Temperature data refer to the 1901–2016 period from the CRU TS v4.01 dataset (Osborn and Jones, 2014).

Modern samples of soils ($n=\mathrm{13}$) were taken from the vicinity of the Gemündener Maar, Weinfelder Maar, Holzmaar, and Schalkenmehrener Maar. Lake surface sediments were also taken from Holzmaar and Schalkenmehrener Maar; each surface sediment sample represents approximately the upper 4 cm of sediment. Four samples were taken from 19 m water depth in Holzmaar, while a depth transect from 0.5–21.7 m water depth was obtained at Schalkenmehrener Maar ($n=\mathrm{18}$). Additionally, 13 samples from the upper 50 cm (representing sediments younger than 1900 CE) of sediment cores retrieved from Gemündener Maar, Holzmaar, and Schalkenmehrener Maar were included in the modern set of samples (total of 48 samples) that were used to test GDGT calibrations against modern climate data.

Sediment cores from Holzmaar (HM4) and Auel Maar (AU4) were scanned with an Avaatech X-ray fluorescence (XRF) core scanner at the Max Planck Institute for Chemistry in Mainz to obtain semi-quantitative elemental data. The core face was smoothed and flattened using a blade and then covered with 4 $\mathrm{\mu }$m thick SPEX CertiPrep Ultralene film to avoid contamination and drying during measurements. XRF scans were performed using a rhodium anode tube with a voltage of 10 kV, a current of 550 $\mathrm{\mu }$A, and counting time of 10 s. The measurement resolution was 0.5 mm. We utilize the counts of Ti as an indicator of terrigenous clastic sediment input, and the ratio of S $/$ Ti as an indicator of hypolimnetic anoxia or sediment anoxia.

2.3 GDGT extraction and measurement

Samples were freeze-dried, homogenized, and then extracted using an accelerated solvent extractor (ASE), following the two-fraction method for lake sediments and soil in Auderset et al. (2020). Between 0.2 and 3.51 g of dried sediment was weighed into an ASE cell, with approximately 16 g of silica gel, which had previously been baked at 500 °C for 5 h, then deactivated with 5 % Milli-Q water, and stored in $n$-hexane. A two-step extraction was performed with $n$-hexane and a $\mathrm{1}:\mathrm{1}$ dichloromethane / methanol mix, which were flushed through the cells at 100 °C and 100 bar. The dichloromethane / methanol fraction contains the GDGT molecules. After extraction, a known amount ($\sim \mathrm{700}$ ng) of internal C${}_{\mathrm{46}}$ GDGT standard (Patwardhan and Thompson, 1999) was added to the extracts. Solvents were then evaporated with a low-pressure centrifuge (Rocket by Genevac). Samples were re-dissolved in $\sim \mathrm{1}$ mL of a $\mathrm{98.5}:\mathrm{1.5}$ mix of $n$-hexane $/$ 2-propanol and filtered with 0.4 $\mathrm{\mu }$m PTFE filters. Subsequently, solvents were evaporated using a FlexiVap and samples re-dissolved in 300 $\mathrm{\mu }$L of $\mathrm{9}:\mathrm{1}$ $n$-hexane $/$ 2-propanol or a greater volume for particularly concentrated samples.

GDGTs were measured with an Agilent 1260 Infinity HPLC-MS (high-performance liquid chromatography mass spectrometer). The HPLC method was based on (Hopmans et al., 2016) and used a flow of 0.2 mL min${}^{-\mathrm{1}}$ of 9:1 $n$-hexane $/$ 2-propanol through two silica columns (UPLC BEH HILIC, 1.7 $\mathrm{\mu }$m) at 200 bar. In total, 5 $\mathrm{\mu }$L was injected from each sample. An intra-laboratory standard based on North Atlantic sediments (see Auderset et al., 2020) was run with each sample batch for quality control and to identify individual GDGT compounds. Data evaluation and peak integration were performed using Agilent MassHunter. The standard set of isoprenoid and brGDGT compounds were identified based on Hopmans et al. (2016) and an additional isomer, IIIa${}^{\prime \prime }$, which is specifically produced under low oxygen conditions, was also identified (Weber et al., 2018, 2015). The limit of detection of each measured compound was determined using the method defined by Currie (1999) (Eq. 14) based on the repeated ($n=\mathrm{17}$) analysis of method blanks. The reproducibility of the method was assessed by repeated ($n=\mathrm{17}$) extraction and measurement of a single sediment sample (Table S1).

2.4 Temperature calibration and data analysis

Several calibration models exist for transforming brGDGT fractional abundances into temperature estimates, and the different calibrations can yield substantially different results. We tested several calibration models on our set of modern samples to assess their ability to produce temperatures that agree with instrumental temperatures. We used the CRU TS v4.01 dataset for modern temperature (representing the period 1901–2016; Osborn and Jones, 2014). We corrected for elevation differences at the five sample sites using a lapse rate of 6.6°C km${}^{-\mathrm{1}}$ calculated from nearby meteorological stations (German Weather Service). The altitude correction was also applied to reconstructed temperatures to ensure a homogenous reconstruction that represents the temperature at Auel Maar (465 m above sea level; a.s.l.).

The following calibration models were assessed.

• Mean annual air temperature (MAAT) using the soil-based calibrations of De Jonge et al. (2014) and using the MBT'${}_{\mathrm{5}\mathrm{Me}}$ (methylation of branched tetraethers 5-methyl index) index and Index 1, respectively: $$\begin{array}{}\text{1}& {\displaystyle }{{\mathrm{MBT}}^{\prime }}_{\mathrm{5}\mathrm{Me}}={\displaystyle \frac{\mathrm{Ia}+\mathrm{Ib}+\mathrm{Ic}}{\mathrm{Ia}+\mathrm{Ib}+\mathrm{Ic}+\mathrm{IIa}+\mathrm{IIb}+\mathrm{IIc}+\mathrm{IIIa}}},\text{2}& {\displaystyle }{{\mathrm{MBT}}^{\prime }}_{\mathrm{5}\mathrm{Me}}\mathrm{soil}\mathrm{MAAT}=-\mathrm{8.57}+\mathrm{31.45}\cdot {{\mathrm{MBT}}^{\prime }}_{\mathrm{5}\mathrm{ME}},\text{3}& {\displaystyle }\mathrm{Index}\mathrm{1}={\log }_{\mathrm{10}}{\displaystyle \frac{\mathrm{Ia}+\mathrm{Ib}+\mathrm{Ic}+\mathrm{IIa}{}^{\prime }+\mathrm{IIIa}{}^{\prime }}{(\mathrm{Ic}+\mathrm{IIa}+\mathrm{IIc}+\mathrm{IIIa}+\mathrm{IIIa}{}^{\prime })}},\text{4}& {\displaystyle }\mathrm{Index}\mathrm{1}\mathrm{soil}\mathrm{MAAT}=\mathrm{5.05}+\mathrm{14.86}\cdot \mathrm{Index}\mathrm{1}.\end{array}$$

• Bayesian calibration models, BayMBT, for soils (Dearing Crampton-Flood et al., 2020) and lakes (Martínez-Sosa et al., 2021), which are based on the MBT'${}_{\mathrm{5}\mathrm{Me}}$ index and calibrated for TMAF (temperature of months above freezing).

• FROG${}_{\mathrm{0}}$ (random Forest Regression for PaleOMAAT using brGDGTs) calibration model for soils (Véquaud et al., 2022).

• African lake calibration models from Russell et al. (2018), using Index 1 and stepwise forward selection multivariate regression: $$\begin{array}{}\text{5}& {\displaystyle }\mathrm{Index}\mathrm{1}\mathrm{lake}\mathrm{MAAT}=\mathrm{12.22}+\mathrm{18.79}\cdot \mathrm{Index}\mathrm{1},\text{6}& {\displaystyle }\begin{array}{rl}& \mathrm{SFS}\mathrm{lake}\mathrm{MAAT}=\mathrm{23.81}-\mathrm{31.02}\cdot \mathrm{IIIa}-\mathrm{41.91}\\ & \cdot \mathrm{IIb}-\mathrm{51.59}\cdot {\mathrm{IIb}}^{\prime }-\mathrm{24.70}\cdot \mathrm{IIa}+\mathrm{68.80}\cdot \mathrm{Ib}.\end{array}\end{array}$$

• The multivariate calibration model of Raberg et al. (2021), hereafter referred to as Raberg21:

  7$$\begin{array}{rl}& \mathrm{Raberg}\mathrm{21}\mathrm{lake}\mathrm{TMAF}=\\ & \mathrm{92.9}\left(\pm \mathrm{15.98}\right)+\mathrm{63.84}\left(\pm \mathrm{15.58}\right)\\ & \cdot {\mathrm{fIb}}_{\mathrm{meth}}^{\mathrm{2}}-\mathrm{130.51}\left(\pm \mathrm{30.73}\right)\cdot {\mathrm{fIb}}_{\mathrm{meth}}-\mathrm{28.77}\left(\pm \mathrm{5.44}\right)\\ & \cdot {\mathrm{fIIa}}_{\mathrm{meth}}^{\mathrm{2}}-\mathrm{72.28}(\pm \mathrm{17.38})\cdot {\mathrm{fIIb}}_{\mathrm{meth}}^{\mathrm{2}}-\mathrm{5.88}(\pm \mathrm{1.36})\\ & \cdot {\mathrm{fIIc}}_{\mathrm{meth}}^{\mathrm{2}}+\mathrm{20.89}(\pm \mathrm{7.69})\cdot {\mathrm{fIIIa}}_{\mathrm{meth}}^{\mathrm{2}}-\mathrm{40.54}(\pm \mathrm{5.89})\\ & \cdot {\mathrm{fIIIa}}_{\mathrm{meth}}-\mathrm{80.47}(\pm \mathrm{19.19})\cdot {\mathrm{fIIIb}}_{\mathrm{meth}},\end{array}$$ where the compound fractions are calculated according to their methylation set; see Raberg et al. (2021) for details.

To assess how brGDGT distributions varied in different types of samples and different sites, a principal component analysis (PCA) was calculated on the fractional abundances (FAs) of brGDGTs; the FAs were calculated as centered-log ratios and scaled prior to the PCA calculation. To assess changing sources of GDGTs, we calculated several indices. The $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa ratio was modified from Xiao et al. (2016) and Martin et al. (2019) and has been used as an indicator of aquatic production of brGDGTs: 8$${\displaystyle \frac{\sum \mathrm{IIIa}}{\sum \mathrm{IIa}}}={\displaystyle \frac{\mathrm{IIIa}+\mathrm{IIIa}{}^{\prime }+\mathrm{IIIa}{}^{\prime \prime }}{\mathrm{IIa}+\mathrm{IIa}{}^{\prime }}}.$$ The branched and isoprenoid tetraether index (BIT) compares the proportion of branched GDGTs to the crenarchaeol and has been used as an indicator of soil input (Hopmans et al., 2004, 2016): 9$$\mathrm{BIT}={\displaystyle \frac{\mathrm{Ia}+\mathrm{IIa}+\mathrm{IIa}{}^{\prime }+\mathrm{IIIa}+\mathrm{IIIa}{}^{\prime }}{\mathrm{Ia}+\mathrm{IIa}+\mathrm{IIa}{}^{\prime }+\mathrm{IIIa}+\mathrm{IIIa}{}^{\prime }+\mathrm{crenarchaeol}}}.$$ The %GDGT-0 index was calculated using the formula of Peaple et al. (2022) and used as an indicator of anaerobic methane-oxidizing archaea or methanogenic Euryarchaeota (Sinninghe Damsté et al., 2012): 10$$\mathrm{\%}\mathrm{GDGT}-\mathrm{0}={\displaystyle \frac{\mathrm{GDGT}-\mathrm{0}}{\mathrm{GDGT}-\mathrm{0}+\mathrm{crenarchaeol}}}\cdot \mathrm{100}.$$ Statistical analyses were performed in R v4.3.1 (R Core Team, 2022). Pearson's $r$ was used to assess the strength of correlations between time series and was calculated using the package geoChronR (Mckay et al., 2021). Time series data were mapped to a normal distribution; $p$ values were adjusted to account for autocorrelation using the effective $n$ method (Dawdy and Matalas, 1964) and were adjusted for multiple hypothesis testing using the false discovery rate method of Benjamini and Hochberg (1995).

3.1 GDGT distribution in modern samples and implications for temperature calibrations

The compositions of brGDGTs in modern samples (Zander et al., 2024a) show clear differences between samples taken from soils and lake sediments (Figs. 2, 3). Soils have a greater proportion of tetra-methylated (Ia–c) GDGTs, as well as IIa and IIa${}^{\prime }$. The hexamethylated compounds IIIa, IIIa${}^{\prime }$, IIIa${}^{\prime \prime }$, IIIb, and IIIb${}^{\prime }$ are less abundant in soils. The samples taken from the shallow lake shore (depths $\mathit{<}\mathrm{1}$ m) have a composition that falls between soil and lake sediment. The IIIa${}^{\prime \prime }$ isomer is not found above the limit of detection in any of the soil samples but is found in all of the modern and ancient lake sediments, with the exception of two samples from Auel Maar dating to the last deglaciation. The modern lake sediments tend to have generally similar distributions compared to each other; however, some small differences can be observed. SM has fewer tetra-methylated GDGTs and more IIIa${}^{\prime \prime }$, indicating a dominance of aquatic production and particularly high production within the anoxic hypolimnion. A strong relationship can be observed between fIIIa${}^{\prime \prime }$ and depth in the transect from Schalkenmehrener Maar (Fig. 4), consistent with previous studies that have concluded this isomer is produced under low oxygen conditions (Weber et al., 2018, 2015).

Figure 2

Distribution of brGDGT compounds at different sites (for abbreviations, see Fig. 1) and among different sample types. Boxes represent the interquartile range (IQR) of the data, with the median depicted by a horizontal line. Whiskers represent the minimum and maximum of the data, excluding outliers that are greater than 1.5 times the IQR beyond the IQR.

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The test of calibration models reveals significant differences in GDGT-estimated temperatures (Fig. 5a). The soil models underestimate modern temperatures, which is to be expected when applied to lake sediments; however, three of the four soil calibrations also underestimate modern temperatures for the soil samples. The FROG${}_{\mathrm{0}}$ model produces temperature estimates with low errors but also low variability. The two calibrations derived from African lakes (Russell et al., 2018) overestimate modern temperatures for all sample types, likely due to the fact that these models are calibrated for MAAT (mean annual air temperature) and are not well suited for temperate lakes that are seasonally ice covered. The two recent global lake calibrations (Raberg et al., 2021; Martínez-Sosa et al., 2021) tend to underestimate modern temperatures for most of the lake sediment samples. Across all calibration models, a consistent relationship can be observed between fIIIa${}^{\prime \prime }$ and the offset between the GDGT-based temperature estimate and the modern instrumental temperature, with high values of fIIIa${}^{\prime \prime }$ corresponding to a cold bias (Fig. 5a). High fIIIa${}^{\prime \prime }$ is indicative of greater production of brGDGTs within the anoxic hypolimnetic waters of a stratified lake, which are substantially cooler than mixed surface layers, particularly in summer (Fig. 4). We note that oxygen is likely not the sole factor controlling IIIa${}^{\prime \prime }$ production – nutrient levels and other biogeochemical parameters could influence fIIIa${}^{\prime \prime }$ (Weber et al., 2018), but nonetheless, it is a useful proxy for production of brGDGTs in the hypolimnion at these sites.

Figure 3

Principal component analysis biplots. Panels (a) and (c) show principal components 1 and 2. Panels (b) and (d) show principal components 2 and 3. Filled symbols in panels (a) and (b) represent the centroids of the groups (site or sample type). The fill in panels (c) and (d) is Raberg21_adj temperatures.

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Figure 4

Depth transect at Schalkenmehrener Maar. (a) Water temperature and oxygen concentration measured in water column in May 2007 (Sirocko, 2012). (b–f) GDGT data from surface sediment samples taken along a depth transect. (b) %GDGT-0 index showing relative abundance of methanogens and methanotrophs (Peaple et al., 2022; Sinninghe Damsté et al., 2012). (c) Crenarchaeol fractional abundance of isoprenoid GDGTs indicating relative abundance of Nitrososphaerota. (d) Fractional abundance of IIIa${}^{\prime \prime }$ relative to brGDGTs, indicating brGDGT production under anoxic conditions. (e) $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa ratio, a proxy for soil vs. aquatic origin of brGDGTs. (f) brGDGT-inferred air temperatures (TMAF) from BayMBT (Martínez-Sosa et al., 2021) and Raberg21 (Raberg et al., 2021) calibrations. Lines in panels (b)–(f) represent smoothing defined by generalized additive models.

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Based on the observed inverse relationship between fIIIa${}^{\prime \prime }$ and the temperature offsets, we calculated regression models to estimate the temperature bias associated with hypolimnetic production of brGDGTs for each calibration model. Figure 5b shows the linear regression models obtained by comparing the offsets of the BayMBT lake model and the Raberg21 model with fIIIa${}^{\prime \prime }$. These regressions were found to be significant ($p\mathit{<}\mathrm{0.001}$), confirming our hypothesis that water column stratification leads to a cold temperature bias in brGDGT temperature estimates. We utilize the regression models fit only to lake sediment samples because the soil samples have temperature offsets that do not fit the linear trend and have distinct distributions from the lake samples. We then applied this correction to the temperature estimates from each calibration, which reduced the temperature offsets by accounting for the cold bias due to aquatic production of brGDGTs in bottom waters of the stratified lakes (Fig. S1). Our data add to results from modern studies of brGDGTs at diverse lakes that have shown variable brGDGT composition along depth transects, suggesting that redox gradients could strongly influence brGDGT composition (Van Bree et al., 2020; Weber et al., 2018, 2015; Stefanescu et al., 2021). We propose that the fIIIa${}^{\prime \prime }$ correction should be tested at other sites and is likely useful to improve the accuracy of brGDGT temperature calibrations, particularly at lakes that experience prolonged stratification with extensive low-oxygen zones.

Figure 5

(a) Offsets between brGDGT-inferred temperatures and 1901–2016 temperature data for eight different calibration models. The symbol shape corresponds to sample type, and the symbol fill corresponds to the fractional abundance of the IIIa${}^{\prime \prime }$ isomer. (b) Cross-plots of temperature offsets and fIIIa${}^{\prime \prime }$ for the two most recent lacustrine brGDGT temperature calibrations (Martínez-Sosa et al., 2021; Raberg et al., 2021). The regression model fit to lake samples (blue line) was used to correct the temperature reconstructions. The symbol shapes match those in panel (a); the symbol color is defined by the site.

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Downcore measurements of brGDGTs (Zander et al., 2024b) were used to reconstruct TMAF using both the BayMBT and Raberg21 model, with and without the adjustment for cold bias associated with lake stratification and IIIa${}^{\prime \prime }$ (Fig. 6). In this section, we interrogate the different reconstructions to understand if changing sources of brGDGTs may have biased the reconstructions; in particular, we assess evidence for variable contributions of brGDGTs from soils, epilimnetic production (warmer surface waters), and hypolimnetic production (cooler bottom waters). All four reconstructions show broadly similar multimillennial-scale patterns, with mild temperatures near or slightly cooler than present during early MIS (marine isotope stage) 3, a colder period from 35–25 kyr b2k, with temperatures around 2–3 °C cooler than present and very warm temperatures during the mid-Holocene (2–5 °C warmer than present). The magnitude of the Last Glacial Maximum (LGM) to Holocene warming is comparable across calibration models. However, significant differences occur during millennial-scale climate perturbations. The BayMBT model shows several periods of pronounced cooling that are, counterintuitively, synchronous with interstadials recorded in Greenland ice cores (GIs 3, 4, 5, 6, 9, 10, and 11 in particular). These interstadial periods are associated with proxy evidence for greater oxygen depletion in the hypolimnion (increased C${}_{\mathrm{org}}$, S $/$ Ti, and fIIIa${}^{\prime \prime }$; Fig. 7); The adjusted BayMBT model shows a reduced magnitude of these cooling events, but nonetheless, the contradictory cold interstadials remain. The Raberg21 model shows little change (cooling or warming) across these interstadial periods. This suggests that the BayMBT model is particularly sensitive to changes in brGDGT source, in particular the cold bias associated with increased production of brGDGTs in anoxic conditions. We interpret proxy evidence for increased primary productivity in the lake during interstadials to reflect a longer growing season. Furthermore, lake mixing likely also decreased either due to thermal stratification or a reduction in winds, leading to an expanded anoxic zone and leading to a cold bias in the MBT'${}_{\mathrm{5}\mathrm{Me}}$ proxy.

Figure 6

Comparison of brGDGT temperature reconstructions with and without correction for anoxic production of brGDGTs. Close-up panels show the comparison with the NGRIP ice core (gray; Rasmussen et al., 2014) during (b) the deglaciation and during (c) Dansgaard–Oeschger events. Colored bars indicate Younger Dryas (YD), Greenland interstadials (GIs), and Heinrich stadials (H1–5).

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We tested the correlation of each of the four reconstructions with prominent temperature records from the last glacial period, including ${\mathit{\delta }}^{\mathrm{15}}$N-based temperature estimates from Greenland ice cores (Kindler et al., 2014; Kobashi et al., 2017), alkenone-based sea surface temperatures (SSTs) from the Iberian margin (Martrat et al., 2007), and $\mathit{\delta }$D-based temperature estimates from the European Project for Ice Coring in Antarctica (EPICA) ice core in Antarctica (Jouzel et al., 2007). Correlations were calculated with each time series averaged into bins of three different widths, namely 250, 500, and 1000 years (Table 2). The Raberg21 models correlate more strongly with each of the tested paleoclimate records compared to the BayMBT models. Focusing on the Greenland temperature record and highest-resolution binning, the Raberg21_adj has a Pearson correlation coefficient $r=\mathrm{0.71}$, while for BayMBT_adj $r=\mathrm{0.54}$. The BayMBT model shows particularly weak correlations if the period is restricted to 15–59 kyr b2k ($r\mathit{<}\mathrm{0.12}$ for all comparisons). The Raberg21 training data include 43 sites from high-latitude environments that are not included in the BayMBT, and this may help improve the calibration for cold environments such as central Europe during the last glacial. The Raberg21_adj reconstruction shows higher correlations in all tests, and the correlations are significant ($r\mathit{>}\mathrm{0.70}$, p_adj $\mathit{<}\mathrm{0.05}$) for all comparisons for the full period (0–59 kyr b2k). If the correlation test is restricted to the period prior to the deglaciation (15–59 kyr b2k), correlations decrease, but the Raberg21_adj model remains significantly correlated with the Greenland temperature data. The significant correlations indicate that the Raberg21_adj model is a valid temperature reconstruction that captures the major climatic fluctuations over the past 60 000 years and that the fIIIa${}^{\prime \prime }$ correction method improves the accuracy of the reconstruction.

Correlation (Pearson's $r$) between brGDGT temperature reconstructions and paleoclimate time series. Bold values indicate $p\mathit{<}\mathrm{0.05}$. $P$ values were adjusted for autocorrelation of the time series, using the effective $n$ method (Dawdy and Matalas, 1964), and for multiple hypothesis testing, using the false discovery rate method (Benjamini and Hochberg, 1995). Greenland temperatures are from Kindler et al. (2014) and Kobashi et al. (2017). North Atlantic SSTs are from alkenone $U_{\mathrm{37}}^{K^{\prime }}$ on core MD01-2444 (Martrat et al., 2007). Antarctica temperatures are from $\mathit{\delta }$D measured on EPICA core (Jouzel et al., 2007).

Figure 7

Proxy data from ELSA sediments. (a) brGDGT temperature reconstruction (Raberg21_adj), where gray shading indicates the calibration uncertainty from Raberg et al. (2021). (b) Fractional abundance of IIIa${}^{\prime \prime }$ isomer indicating the anoxic production of brGDGTs. (c) $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa ratio, which is a proxy for soil vs. aquatic origin of brGDGTs. (d) %GDGT-0 index showing the relative abundance of methanogens and methanotrophs. (e) BIT index showing the relative proportion of brGDGTs to crenarchaeol. (f) Concentrations of brGDGTs, isoprenoid GDGTs, and crenarchaeol (including crenarchaeol isomer). (g) C${}_{\mathrm{org}}$ inferred from sediment reflectance (Sirocko et al., 2021). (h) S $/$ Ti ratio from XRF core scanning used as a proxy for sediment and/or bottom-water anoxia. (i) Ti counts used as an indicator of lithogenic input. (j) Tree pollen data with thermophilous species Quercus and Corylus highlighted (Sirocko et al., 2022). Non-filled circles in the pollen plot represent $\mathrm{10}\times$ exaggerated pollen percentages.

[Figure omitted. See PDF]

To further investigate what factors might influence mismatches between the GDGT temperature reconstructions and the Greenland temperature record, we calculated the offset between our four reconstructions and the Greenland temperatures after scaling the Greenland temperatures to match the mean and variance of the GDGT temperature estimates. These offsets were then correlated with paleoclimate and local proxy data (Fig. 8). This analysis shows that the offsets with Greenland temperatures tend to be negatively correlated with the paleoclimate records, indicating that our reconstructions tend to have a cold bias during warm periods (and/or vice versa). However, this relationship is substantially weaker for the Raberg21 models compared to the BayMBT model. The BayMBT models show strong negative correlations with C${}_{\mathrm{org}}$ and fIIIa${}^{\prime \prime }$, both of which are associated with greater aquatic production and hypolimnetic anoxia weber (Weber et al., 2018). The Raberg21 models also show negative correlations with these proxies, but the correlations are weaker, indicating that the model is less sensitive to these non-climatic factors. The Raberg21_adj model is the only reconstruction that does not show a significant negative correlation between the offsets and fIIIa${}^{\prime \prime }$, indicating that the cold bias associated with stratification has been mitigated due to the correction applied.

Figure 8

Assessing which factors contribute to offsets between GDGT temperature reconstructions and the Greenland ${\mathit{\delta }}^{\mathrm{15}}$ N temperature record after scaling mean and variance to match the GDGT temperatures (Kobashi et al., 2017; Kindler et al., 2014). Pearson's $r$ is plotted for these offsets and the proxy time series on the $x$ axis. Time series were placed in 250-year bins before the correlation was calculated. Filled circles indicate significant correlations ($p\mathit{<}\mathrm{0.05}$ after adjusting for autocorrelation and multiple-hypothesis testing).

[Figure omitted. See PDF]

Variations in aquatic vs. soil sources of brGDGTs might influence the temperature reconstruction, as has been reported at other European lakes (Martin et al., 2019, 2020; Ramos-Román et al., 2022). No lake samples in this study are classified as soil samples by a machine learning algorithm that uses GDGT distributions to predict depositional environments (Martínez-Sosa et al., 2023), suggesting lacustrine sources dominate our lake sediment samples. Correlations between the Greenland temperature offsets and $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa and BIT could suggest that more soil input is related to temperature overestimation. However, the correlations are not statistically significant, indicating that changing contribution of terrestrial- vs. aquatic-sourced GDGTs is not a significant influence on the mismatch between the GDGT record and the Greenland record. Furthermore, although these two indices have been used in previous studies as indicators of soil-derived GDGTs, global compilations provide mixed evidence of their utility. High BIT has been used as an indicator of terrestrial GDGT sources (Hopmans et al., 2004), but in a global compilation of GDGT data (Martínez-Sosa et al., 2023), lake sediments actually have a higher average BIT than soils ($p\mathit{<}\mathrm{0.05}$). BIT is more likely to be controlled by the niche for crenarchaeol-producing Nitrososphaerota, i.e., oxic conditions (often low oxygen concentrations) below the photic zone with a supply of ammonium (Sinninghe Damsté et al., 2022). Under this interpretation, high BIT values indicate either a shallow lake or shallow oxycline. The interpretation of low $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa, as indicative of soil-derived brGDGTs, was originally proposed for marine settings (Xiao et al., 2016) but has also been applied to lacustrine GDGTs (Martin et al., 2020). However, 65 % of lake sediment samples in a global compilation (Raberg et al., 2022) have $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa $\mathit{<}\mathrm{1}$, suggesting that calibration models for lacustrine sediments already account for some degree of soil input or that $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa $\mathit{<}\mathrm{1}$ is commonly produced in lacustrine environments. Additionally, the $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa ratio is strongly negatively correlated with temperature in global compilations of lacustrine brGDGTs (Raberg et al., 2022), in particular for values $\mathit{<}\mathrm{1}$. Thus, fluctuations in $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa may be driven by temperature change rather than variable portions of aquatic vs. terrestrial brGDGTs. Alternatively, because $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa changes with depth in our SM transect (Fig. 4), this index may be influenced by variable biogeochemical conditions that control the niches of IIa vs. IIIa producers, similar to IIIa${}^{\prime \prime }$.

In our 60 000-year reconstruction, low $\mathrm{\Sigma }$IIIa/$\mathrm{\Sigma }$IIa and high BIT mainly occur during the interval represented by Holzmaar sediments. The composition of GDGTs in HM is unique in that it has low concentrations of crenarchaeol, specifically produced by ammonium oxidizing Nitrososphaerota, and high GDGT-0, produced by methanogens. These characteristics indicate that isoprenoid GDGTs have an aquatic (anoxic) source in HM. C $/$ N ratios in organic matter in HM sediments are typically 9–11, also indicating a dominantly aquatic source for organics in HM (Anhäuser et al., 2014; Lücke et al., 2003). HM sediments plot between lake and soil samples from the Eifel in a reduced-dimensional space (Fig. 3); however, the similarity with soil is mainly driven by the first principle component (PC), which is highly correlated to temperature, and therefore it is unclear if the similar composition of Holocene HM samples and modern soil samples could be due to HM representing the warmest period in the record (Holocene thermal maximum; Kaufman and Broadman, 2023). PCs 2 and 3 show distinct differences between HM and soil samples. When compared to a global compilation of GDGTs (Martínez-Sosa et al., 2023), HM plots outside the range of soil samples in a PCA (Fig. S2). Overall, there is evidence that HM GDGTs differ from the other sites with some evidence for a greater portion of soil-derived brGDGTs; however, there is also evidence that the GDGTs are still predominantly aquatic. The distinct composition of HM GDGTs could be related to a steep redox gradient and extensive euxinic conditions in HM, as indicated by the presence of pigments attributed to anoxygenic phototrophic bacteria in Holocene sediments of HM (García et al., 2024). The same pigments were not detected in sediments from Auel Maar (Albert et al., 2024). The euxinic conditions in HM restrict the abundance of Nitrososphaerota (Callieri et al., 2016; Sinninghe Damsté et al., 2022), driving high BITvalues. brGDGT production in the anoxic zone was apparently relatively low (low fIIIa${}^{\prime \prime }$) in Holocene HM, and this points toward a greater proportion of brGDGTs produced in the warm epilimnion of HM or in catchment soils, which could be a justification for anomalously warm temperatures in the HM segment. Similarity of the HM Holocene samples and SM lake shore samples ($\mathit{<}\mathrm{1}$ m water depth) strengthens this interpretation (Figs. 3, 4). The reasonable agreement (considering significant age uncertainty in the Auel Maar data) of reconstructed temperature from samples taken from both Auel Maar and Holzmaar during the Bølling–Allerød warm period (GI-1) is evidence that compatible results can be obtained from both sites, despite substantially different sediment properties in this interval (Fig. 6).

Modeled TMAF from a high-resolution global circulation model (HadCM3; (Leonardi et al., 2023; Beyer et al., 2020) agrees with brGDGT-inferred temperatures (Fig. 9), though the model is not capable of capturing millennial-scale variations. The root mean square deviation between the proxy and model is 2.19 °C, nearly identical to the calibration error of 2.14 °C. The Holocene segment from Holzmaar is the only prolonged period of deviation between the model and proxy data, which might be attributed to changing brGDGT sources as described above. However, it is likely that the model output also underestimates TMAF to some extent during the Holocene thermal maximum (HTM; 5–11 kyr BP), due to an underestimation of vegetation expansion and subsequent albedo feedbacks during the HTM (Thompson et al., 2022). Proxy data from Europe consistently show warmer-than-present summer temperatures during the HTM (Kaufman and Broadman, 2023; Martin et al., 2020; Renssen et al., 2009; Kaufman et al., 2020), which is not observed in the model output.

Figure 9

Comparison of HadCM3 model simulations (Beyer et al., 2020; Leonardi et al., 2023) of seasonality, MAAT, and TMAF with brGDGT temperature reconstruction.

[Figure omitted. See PDF]

The TMAF reconstruction shows multi-millennial patterns and magnitudes of change that are congruent with existing temperature reconstructions from Europe (Fig. 10). An early MIS 3 warm period occurs from 54–51 kyr b2k (GI-14) in which TMAF is approximately the same as modern conditions (9 °C). This warm period corresponds with the presence of thermophilous tree species Quercus and Corylus in the study area (Fig. 7), as well as an interval of speleothem growth in central European caves, a qualitative indicator of warm conditions (Riechelmann et al., 2023). Evidence of summer temperatures near modern levels during early MIS 3 can also be found from insect remains in northern Finland, the British Isles, and France (Helmens, 2014) and peak temperatures recorded in an Austrian speleothem (Spötl and Mangini, 2002). During Heinrich stadial 5 (H5), brGDGTs record relatively warm temperatures in contrast to severely depressed SST in the North Atlantic at this time (Fig. 10; Martrat et al., 2007). Low $\mathrm{\Sigma }$IIIa $/$ $\mathrm{\Sigma }$IIa, low C${}_{\mathrm{org}}$, and high Ti could indicate a shift towards more soil-derived brGDGTs during H5 (Fig. 7), which would lead to a warm bias in the TMAF reconstruction. Alternatively, enhanced seasonality may have led to higher TMAF despite cold long winters (Denton et al., 2022). Following H5, temperatures enter a cool phase from 44–38 kyr b2k, corresponding with a minimum of summer insolation and including Heinrich stadial 4 (H4). GI-8 stands out as a prolonged warm period in our record, with $\sim \mathrm{2}$ °C of warming at the onset of the interstadial. After gradual cooling, TMAF averages 6.4 °C from 36–30.5 kyr b2k. H3 is again associated with an increase in TMAF, most likely associated with a prolonged freezing season.

Figure 10

Comparison of ELSA brGDGT temperature reconstruction with regional and global paleoclimate records. (a) brGDGT temperature reconstruction (Raberg21_adj). (b) North Atlantic SST from core MD01-2444 based on alkenone $U_{\mathrm{37}}^{k{}^{\prime }}$ proxy (Martrat et al., 2007). (c) Pollen-based temperature reconstructions from the SW coast of the Iberian peninsula (MD95-2042; Sánchez Goñi et al., 2002) and northwest Mediterranean Sea (MD99-2343; Sánchez Goñi et al., 2021). MTCO is the mean temperature of coldest month; DJF is the December, January, and February mean temperature. (d) Greenland ${\mathit{\delta }}^{\mathrm{15}}$ N temperatures (Kobashi et al., 2017; Kindler et al., 2014). (e) Earthworm calcite grain warm-season land surface temperatures (LSTs) from German loess (Prud'homme et al., 2022). (f) Antarctica temperature anomalies from $\mathit{\delta }$D (Jouzel et al., 2007). (g) Atmospheric CO${}_{\mathrm{2}}$ estimated from the EPICA ice core (Bereiter et al., 2015). (h) Incoming solar insolation for 50° N during summer (black line) and winter (dashed blue line) (Laskar et al., 2004).

[Figure omitted. See PDF]

From 29–24 kyr b2k, TMAF reaches the lowest levels of the record ($\sim \mathrm{6.2}$ °C), in good agreement with the timing of maximal glacier extent in the Alps (Seguinot et al., 2018), British Isles, and Baltic lowlands (Clark et al., 2009). The estimate of 2.6 °C cooling during the LGM compared to the modern period is substantially less than noble gas estimates of 9.1 °C LGM cooling from the Paris Basin at 26 kyr BP (Bekaert et al., 2023) and the results of a global paleoclimate data assimilation ($\sim \mathrm{10}$ °C cooling at our site for 23–19 kyr BP; Tierney et al., 2020). However, considering the stronger seasonal variability during the LGM, and thus the longer freezing period, changes in TMAF are expected to be smaller than MAAT. Beetle (Coleoptera) remains from Auel Maar indicate that during the LGM, temperatures of the warmest month were 6 to 9.5 °C, whereas temperatures of the coldest month were $-\mathrm{20}$ to $-\mathrm{30}$ °C (Britzius and Sirocko, 2022), approximately double the annual temperature range compared to the modern period. Scaling the modern monthly climatology to match these temperatures would yield a TMAF between 5.8 and 4.3 °C, which overlaps with our estimated 4.0–8.3 °C, taking into account calibration uncertainty (Fig. 11). HadCM3 model output yields a TMAF of 6.3 °C over the 24–29 kyr period, nearly identical to the brGDGT estimate (Leonardi et al., 2023; Beyer et al., 2020). In the model output, the number of months above freezing was 6–7 months during MIS 2–3, with an amplified seasonal temperature range of mean monthly temperature up to 26 °C (modern range is 16 °C) (Fig. 9). The enhanced seasonal range helps to explain the much smaller TMAF cooling compared to MAAT (Fig. 11).

Figure 11

(a) Comparison of modern seasonal temperature range for the modern period, LGM based on climate models (Beyer et al., 2020), LGM based on Coleoptera remains (Britzius and Sirocko, 2022), and a hypothetical Heinrich stadial scenario in which winter temperatures decrease, while peak summer temperatures remain the same. (b) Comparison of TMAF and MAAT for modern, LGM, and H3 based on different methods. NGT LGM is for the noble gas temperatures from Bekaert et al. (2023), and DA LGM is for the data assimilation results from Tierney et al. (2020). Note that the Coleoptera temperature range was obtained by scaling modern monthly temperatures to match the Coleoptera estimates of warmest and coldest months; the ranges represent likely values based on a simple assumption about the monthly temperature pattern but are not a calibrated estimate.

[Figure omitted. See PDF]

Two samples suggest anomalously high TMAF near modern values during GI-2 (the ages of these samples are slightly younger than GI-2, but we attribute them to GI-2), which suggest seasonally warm temperatures, though additional data would be needed to confidently confirm this interpretation. The pattern of deglacial warming captures major features such as the Bølling–Allerød warm period, Younger Dryas stadial, and rapid warming during the early Holocene. The Bølling–Allerød (GI-1) TMAF is slightly warmer than modern and 2.8 °C warmer than H1. Chironomid-based summer temperature reconstructions from the alpine region and NW Europe suggest broadly similar magnitudes of warming from H1 to GI-1 (Heiri et al., 2015, 2014). The low sampling resolution precludes meaningful estimates of Younger Dryas cooling. Mid-Holocene temperatures average 12.3 or 3.5 °C warmer than the modern period, suggesting a strong Holocene thermal maximum combined with strong seasonality in response to high summer insolation. The magnitude of the HTM is greater than estimated from pollen-based summer temperature reconstructions (Mauri et al., 2015; Renssen et al., 2009; Martin et al., 2020) but is similar to the magnitude of warming in chironomid-based reconstructions from the alpine region (Heiri et al., 2015).

Our GDGT temperature reconstruction shows substantially dampened millennial-scale climate variability in comparison with paleoclimate records from the North Atlantic region. Table 3 shows the temperature and warming estimated for each Greenland interstadial (GI) and the early Holocene. For all but one GI from 59–24 kyr b2k (GIs 3–16), the warming is less than 1 °C, which is less than the error in the temperature calibration (2.14 °C). We calculate a mean warming of 0.5 $\pm$ 1.3 °C for GIs 1–16, significantly less than observed in Greenland (average $=$ 5.5 °C). These results suggest that Dansgaard–Oeschger (DO) cycles had a minimal impact on warm-season temperatures in central Europe. This finding is surprising, considering the major changes observed in aquatic productivity and redox conditions in Auel Maar and other lakes in western Europe (Wohlfarth et al., 2008) during DO cycles. In Lake Van, eastern Anatolia, brGDGT temperature reconstructions show TMAF changes up to 8 °C during DO cycles. Higher variability in the Republic of Türkiye in response to DO cycles is surprising, given the evidence that DO cycles were more prominently expressed with greater proximity to the North Atlantic (Fohlmeister et al., 2023). Pollen records from Europe indicate major vegetation shifts associated with DO cycles (Wohlfarth et al., 2008; Moreno et al., 2014; Duprat-Oualid et al., 2017; Guiot et al., 1993; Sánchez Goñi et al., 2008; Britzius et al., 2024), and shifts in ${\mathit{\delta }}^{\mathrm{18}}$O (Spötl and Mangini, 2002; Moseley et al., 2014) and ${\mathit{\delta }}^{\mathrm{13}}$C (Genty et al., 2003) measured on speleothems indicate major changes to atmospheric circulation and terrestrial ecosystems, respectively. However, our record supports the hypothesis that these changes were driven primarily by variability in winter temperatures associated with expanded sea ice (Denton et al., 2005, 2022; Flückiger et al., 2008). Changes in the duration of the growing season likely had a major impact on biotic proxies such as pollen and lake productivity.

Quantitative estimates of millennial-scale temperature fluctuations from terrestrial archives in Europe are rare beyond the past 15 kyr. Additionally, estimates of seasonal temperatures are challenging to interpret due to the difficulty of disentangling multiple climate signals. Isotopic measurements of earthworm calcite granules from the Rhine Valley, Germany, were used to estimate approximately 1–4 °C warmer land surface temperatures during warm seasons during interstadials compared to stadials (Prud'homme et al., 2022). Clumped isotope measurements on snails in Hungary indicate a difference of 4–7 °C between stadial and interstadial phases for the growing season (Újvári et al., 2021). Temperatures estimated from diatom assemblages at Les Échets, France, suggest 0.5–2 °C of summer warming during GIs between 18–36 kyr BP (Ampel et al., 2010). Pollen assemblages from marine sediments on the Iberian margin and in the Mediterranean suggest that winter (DJF) temperatures in the Iberian peninsula and southern France decreased by approximately 1.5–4 °C during Heinrich stadials 4 and 5 (Sánchez Goñi et al., 2021). The mean temperature of the coldest month in Iberia was estimated to be approximately similar to modern day during interstadials of the last glacial but cooled by as much as 8 °C during H4 (Sánchez Goñi et al., 2002). Moraine records from Alpine glaciers provide evidence of muted millennial-scale summer temperature variability in Europe; simulations of Alpine ice extent fit the moraine records better when forced by temperatures scaled to the Antarctica temperature record, rather than Greenland (Seguinot et al., 2018). Model simulations of DO type variability also provide variable results. Two simulations done with LOVECLIM (long-term evolution of climate) using perturbations in AMOC yielded very different estimates for DO cycle temperature variability. Using the LOVECLIM model, Van Meerbeeck et al. (2011) estimated 8 °C warming in Europe during the warmest month and 17 °C warming during the coldest month for a stadial–interstadial transition during early MIS 3, whereas Menviel et al. (2020) report 1.5 °C warming of MAAT over Europe associated with stadial–interstadial changes at 37 kyr BP, also using LOVECLIM. A modeling study that isolated the impact of AMOC changes showed that, in Europe, spring temperatures changed more than any other season in response to a shift from weak to strong AMOC, with 3.5 °C of warming in spring compared 2 °C in summer (Flückiger et al., 2008). The variations in spring temperatures would have important implications for the brGDGT proxy by changing the length of the non-freezing season.

Table 3

Temperatures of warm events recorded by ELSA GDGT reconstruction and compared to temperature changes recorded in Greenland.

The GDGT temperature reconstruction shows a variable response to North Atlantic Heinrich stadials. H5 and H3 are associated with slight warmings in our reconstruction, and H1 has relatively mild temperatures. These results appear to be consistent with major meltwater pulses recorded in sediments from the Bay of Biscay, indicating melting of European ice sheets and glaciers during Heinrich stadials 1–3 (Toucanne et al., 2015), which would require relatively warm summers. Denton et al. (2022) summarize existing evidence for relative warmth during Heinrich summers.

The seasonal response of lacustrine brGDGTs to the non-freezing season is a primary reason why our estimate of stadial–interstadial temperature variability is lower than other records from Europe. Over the instrumental period, TMAF and MAAT are nearly the same for our study area (8.77 °C vs. 8.1 °C); however, during the last glacial period, with cooler temperatures and increased continentality, the difference between MAAT and TMAF would have increased substantially (Fig. 9). We demonstrate that it is possible for the combination of cooler MAAT and increased seasonality to increase TMAF by simulating a hypothetical H3 monthly temperature pattern that has the July temperature simulated by HadCM3 for the LGM from Beyer et al. (2020) but with a 5 °C greater seasonal range; i.e., January temperatures are 5 °C colder (Fig. 11). A 5 °C colder temperature is realistic for a Heinrich event based on a similar or even greater range of variability in the mean temperature of coldest months (MTCO) during millennial-scale events in a pollen-based reconstruction from the Iberian Margin (Fig. 10; Sánchez Goñi et al., 2002). Compared to the LGM values, this simulated Heinrich stadial would have MAAT 2.6 °C cooler, but TMAF is 1.1 °C warmer. This assumes a constant shape of the annual temperature cycle; however, particularly cold spring temperatures during Heinrich stadials (Flückiger et al., 2008) could enhance this effect. This response to the changing duration of the non-freezing period dampens the variability in brGDGT temperature reconstructions when colder temperatures are associated with increased seasonal amplitude, highlighting the importance of incorporating knowledge of the recording season of paleoclimate archives when interpreting paleoclimate records (Kwiecien et al., 2021). Temperature calibrations rely on an assumption that brGDGTs respond to TMAF, but detailed knowledge of seasonal production of brGDGTs might improve the interpretation of temperature reconstructions, particularly because the organisms producing brGDGTs in lakes are not yet identified. Field monitoring studies of lacustrine brGDGT production suggest that production can be dominated by relatively short periods in the year and can be triggered by mixing events (Loomis et al., 2014; Van Bree et al., 2020), which could bias the temperature signal to record conditions associated with lake mixing (typically 4–8 °C for temperate lakes).

Overall, our data add to a growing body of evidence that changes in seasonality, and particularly changes in winter climate, defined the abrupt millennial-scale climate events of the last glacial period, while summer temperatures remained relatively stable and moderate.

GDGT distributions measured on a composite sequence of lake sediments from the Eifel Volcanic Field, Germany, provide a unique tool to reconstruct temperature fluctuations in central Europe during the past 60 kyr. A comparison of modern GDGT distributions in soils and lakes from the Eifel provides insights into the accuracy of the various published brGDGT temperature calibrations. We find that lake stratification likely leads to a cold bias in brGDGT temperature estimates and that this bias can be corrected using the relationship between the residuals of the temperature calibrations in this region and the IIIa${}^{\prime \prime }$ isomer, which is exclusively produced in anoxic conditions. We find that the multivariate calibration model of Raberg et al. (2021) performs best and, after adjusting for the effect of lake stratification, produces a temperature reconstruction that resembles other temperature reconstructions from the past 60 kyr. The adjusted Raberg21 model is less affected by non-climatic factors, such as changing sources of brGDGTs. A proxy–model comparison shows generally good agreement and highlights the important role of seasonality in the temperature recorded by brGDGTs. Our centennial-resolution reconstruction of TMAF indicates that early MIS 3 experienced non-freezing-season temperatures only slightly cooler than present and that LGM TMAF was approximately 2.6 °C cooler than the present. The TMAF reconstruction shows only minimal 0–1 °C temperature fluctuations across Greenland stadial–interstadial transitions, providing strong evidence that these millennial-scale climate events primarily affect the winter season and shortened growing seasons, but peak warm-season temperatures were less affected. The seasonal signal of TMAF provides a unique constraint on our understanding of past changes to seasonal temperature cycles and thus may be a useful target for modeling studies of past climate. Our high-resolution, continuous temperature reconstruction is unique for the European continent and therefore will be of interest for studies of paleoecology and archeology.