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Investigating past interglacial climates not only help to understand how the climate system operates in general, it also forms a vital basis for climate predictions. We reconstructed vertical stratification changes in temperature and salinity in the North Atlantic for a period some 400ka ago (MIS11), an interglacial time analogue of a future climate. As inferred from a unique set of biogeochemical, geochemical, and faunal data, the internal upper ocean stratification across MIS 11 shows distinct depth-dependent dynamical changes related to vertical as well as lateral shifts in the upper Atlantic meridional circulation system. Importantly, transient cold events are recognized near the end of the long phase of postglacial warming at surface, subsurface, mid, and deeper water layers. These data demonstrate that MIS 11 coolings over the North Atlantic were initially triggered by freshwater input at the surface and expansion of cold polar waters into the Subpolar Gyre. The cooling signal was then transmitted downwards into mid-water depths. Since the cold events occurred after the main deglacial phase we suggest that their cause might be related to continuous melting of the Greenland ice sheet, a mechanism that might also be relevant for the present and upcoming climate.
Recent global warming is amplified in the North Polar region through enhanced glacier melting1 and a reduction of the seasonal sea ice cover2. It is also expected that the northward propagation of oceanic and atmospheric heat and moisture from the adjacent North Atlantic region might experience significant changes due to Greenland Ice Sheet (GIS) melting3, sea ice loss in the Arctic4 and the feedback mechanisms related to these processes.
Our understanding of potential responses of the climate to these changes may be improved through investigations of past climate analogues of the upcoming period. Marine isotope stage 11 (MIS 11), a warm period which started around 425ka, shares some aspects with our anticipated future climate, such as amplified warming in parts of the Arctic region5,6, intense melting of the GIS7,8,9,10 and, as a consequence, enhanced freshwater input into the subpolar-polar seas during this period11,12.
Although a vigorous Atlantic Meridional Overturning Circulation (AMOC) is usually inferred for MIS1113,14,15,16, interglacials as such were not free of notable climate instabilities as reflected in surface and deep waters of the North Atlantic17,18. In spite of minor variability evident in some terrestrial records19,20, the peak of MIS 11, i.e. MIS 11 sensu stricto (ss), is generally regarded as a rather stable interglacial period, at least on an interglacial time scale13,16,21. However, if the GIS was indeed continuously releasing meltwater during the course of this rather long interglacial8, there could also have been notable effects on the vertical ocean structure as well as on ocean circulation and climate. Considering the currently ongoing melting of the GIS, an investigation of such effects would help to understand the impact of future climate developments.
To unveil interglacial climate development and potential climate variability during MIS 11ss, we have reconstructed sea water properties at various depth layers combining organic and inorganic analyses of different proxy carriers. Sea surface temperatures (SSTs) were derived from the unsaturation index of long chain alkenones 22, organic compounds produced by haptophyte algae (depth habitat 0–30m), while temperatures of subsurface waters were reconstructed from the TEX86 index23 derived from ammonia-oxidizing Thaumarchaeota, which highest abundances are often found in subsurface water layers24. To assess temperature changes in intermediate water layers25 the δ18O composition of deep-living planktic foraminifers Globorotalia truncatulinoides sinistral (s) and dextral (d) were used. In addition, our temperature reconstructions are accompanied by the stable hydrogen isotopes of C37 alkenones26 (δD) and the δ13C of planktic foraminifer G. bulloides as surface salinity and subsurface water ventilation proxy, respectively. We compare these data with records which were mainly established in previous studies: SSTs based on planktic foraminiferal census counts27, the relative abundances of Globigerina bulloides27 and Turborotalita quinqueloba (new data) as environmental markers, grain counts of ice-rafted debris (IRD) as a measure for relative iceberg abundance27, benthic δ13C as a deep water ventilation proxy15 as well as benthic and planktic δ18O27.
The site where core M23414 was taken (53°32′ N, 20°17′ W; 2196m water depth) currently underlies the western edge of the North Atlantic Current (NAC; Fig. 1), one of the most important elements of the AMOC. This location is ideal to detect lateral changes in Subpolar Gyre (SPG) configuration, since the present-day physical property differences between relatively saline and warm waters of the NAC and less saline and cold western waters of the SPG are well established. The strength of the SPG is defined by its feeding currents, the northward-flowing warm water of the NAC and the southward-flowing polar water of the East Greenland Current (EGC).
According to foraminiferal SST and IRD records Termination V, the transition between full glacial conditions of MIS 12 and full interglacial conditions of MIS 11, i.e. MIS11ss, ended around 420ka at site M23414. A sharp decrease or a complete cessation of IRD input is commonly applied in the middle latitudes of the North Atlantic to identify the main ending of terminations28,29. However, our records of foraminiferal δ18O as well as alkenone δD (see SI) imply that global ice volume decrease persisted well into MIS 11ss for the next 10 kyrs. Moreover, it was accompanied by a gradual interglacial temperature rise of at least 3°C as inferred from foraminiferal, , and temperature records (Fig. 2). Thus, at site M23414 the start of the period of maximal temperatures occurred relatively late (410ka) and was coincident with the time of minimal global ice volume/global sea level highstand. This time interval was therefore defined as the regional climate optimum30. The pattern revealed in core M23414 is in accordance with Antarctic ice-core31, terrestrial7, and marine16,21,32,33,34,35 records, which all show that the climate optimum occurred in the middle of MIS 11ss. Such a late occurrence of the climate optimum during MIS 11ss is different from the Holocene and the last interglacial when temperature rose immediately after the deglaciations. This has recently been explained by the misalignment of precession and obliquity maxima during MIS 11 that caused a gradual temperature rise at the beginning of the interglacial and an occurrence of the climate optimum during the second insolation peak within MIS 1136,37. The delay of the climate optimum in the North Atlantic during this period might additionally be aggravated by feedback mechanisms related to continuous melting of the GIS11,12 as well as enhanced freshwater export from a warm Arctic5. This resulted in the formation of a buoyant surface layer in the Nordic Seas11,12, which obstructed the northward Atlantic water propagation.
The benthic δ18O and IRD records imply that significant glacier re-advance down to sea-level happened around 396ka, which marks the end of MIS 11ss. However, a slight change towards climate deterioration is reflected by increase of benthic and planktic δ18O, increase of IRD content and decrease of temperatures even earlier, around 405ka, which designates the end of the climate optimum. Thus, MIS 11ss can be subdivided into three phases: a postdeglacial warming phase, which lasted ca 10ky, the climate optimum lasting ca 5ky, and a phase of progressive interglacial demise lasting ca 9ky. The total estimated duration of MIS 11ss at site M23414 is around 24ky.
The temperature records derived from and reveal an intra-interglacial transient cold event centered around 411ka, i.e. near the very end of the prolonged phase of global ice volume decrease (Fig. 2). Interestingly, the SSTs derived from show a mere drop of ~2°C only, whereas the temperature reconstruction for the 0–200m water layer indicates a much more drastic decrease of ~6°C. The transient cold event coincided with increases in the δ18O of the deep dwelling planktic foraminifers G. truncatulinoides (s) and (d) (Fig. 2). The amplitudes of both increases reach 0.4‰ which corresponds to 1.8°C temperature decrease when neglecting other potential factors38. This is in agreement with the drop in the SST, but it is smaller than the one reconstructed from the . Perhaps the latter combines actual temperature changes with an effect of a vertical or seasonal migration of Thaumarchaeota. That might happen during interglacial cooling episodes in response to an eastward expansion of colder, more productive waters to the SPG, which then resulted in an enhanced algal production at our site. A competition for nutrients such as ammonium could have pushed the Thaumarchaeota to greater depths or to colder seasons39. Our suggestion about changes in water mass configuration is also corroborated by an increase in relative abundance of the planktic foraminiferal species G. bulloides from 20% before the cold event to 36% during its culmination (Fig. 2). The elevated occurrence of this species seems to be associated with the SPG, as according to the core top census data, the relative abundance of G. bulloides westward of site M23414 reaches up to 65%40 (See SI for details). After the culmination of the cold event all proxies demonstrate an abrupt return to the environmental conditions that prevailed before the cold event had started.
It is intriguing that only δ18O of deep-living planktic foraminiferal species G. truncatulinoides (s) and (d) bear a clear signature of the cold event around 411ka, while the δ18O of Neogloboquadrina pachyderma (dextral) does not (Fig. 2). An enhanced freshwater influence on the shallower depth habitat of N. pachyderma (d) might be the cause for the latter observation, as this would counter-balance the temperature effect on the δ18O. Indeed, evidence for a freshwater input comes from a 15‰ decrease observed in alkenone δD just prior to the cold event at 412ka (Fig. 2). Because effects of global ice volume changes can be neglected at this time, the open ocean changes in the δD of C37 alkenones mainly reflect salinity changes with approximately 4–5‰ of δD per salinity unit26 (see SI for details). Hence, a freshening of the upper water layer by ~3 salinity units seems to be a realistic estimation, suggesting a substantial freshening possibly related to ice sheet retreat and meltwater release. Other, more indirect, evidence of surface water freshening during the cold event comes from a decrease of 0.6‰ in δ13C of G. bulloides, which might reflect reduced ventilation of subsurface water due to an enhanced stratification (Fig. 2). That assumption is strengthened by a simultaneous increase in the relative abundance of the subpolar planktic foraminifer T. quinqueloba, a species well-adapted to colder temperatures and ice margin environments (see SI for details). The cold event at 411ka seems to have affected the δ18O signature of the entire water column of the region since there is a positive response also seen in benthic δ18O values at this time in our core and nearby21. However, it is difficult to give a straightforward interpretation to this fluctuation in the benthic δ18O considering the absence of a response in the benthic δ13C record (Fig. 2). An explanation for the latter might be that the bottom of our core site is ventilated from a different source than its surface and that benthic δ18O represents a mixture of at least two signals: ice volume and temperature. Another cold event with similar, but less pronounced, features is revealed in our records in surface and subsurface waters around 414ka.
Recognition of these cold events by using multiple proxies characterizing different water depths allows for reconstructing changes in the SPG during these episodes. Each of the cold events started with a freshwater injection, which changed the salinity at the surface. This freshwater input was associated with slight surface water cooling, which further evolved into substantial cooling affecting deeper water layers as inferred from the and the δ18O signature in G. truncatulinoides (s) and (d). Thus, the here identified cold events occurred in two distinct steps, implying that the first step amplified the initial cooling trend. Such a behavior of the climate system requires an involvement of feedback mechanisms as well as certain thresholds in the climate system, which allow for an abrupt amplification of cooling and a return of the system to its former state. The most important of them should be related to changes in surface water buoyancy as indicated by paleoceanographical observations and modeling experiments for both glacial and interglacial AMOC operational modes18,41,42,43,44,45.
Although MIS 11ss is generally considered as a climatically stable interglacial period, at least one widespread cold event was identified in the Holsteinian terrestrial records from northern Europe. Although initially its occurrence was explained by non-climatic forcing that did not have regional significance (i.e. wildfire or a volcanic eruption46,47), more careful investigation of its evolution led to a conclusion that this cold event was climatically induced and most likely related to a short lived AMOC oscillation at the end of the global sea level rise20,48. Nevertheless, no MIS 11 paleoceanographical research has focused on abrupt cold events so far, most likely due to ambiguity of their appearance in the marine records in which they were indicated either by a single data point and/or by a single record.
Further northwestward of site M23414, at ODP Site 983 (Fig. 1), two brief but significant cold events are clearly recognizable after the main period of deglacial IRD input had ceased49 (Fig. 3). The earlier cold event at Site 983 was associated with an IRD input, but the younger cold event, which occurred at the end of global ice volume decrease, was substantially more pronounced as seen in the increase of N. pachyderma (s) relative abundance. Therefore, the timing and expression of these cooling events suggest that they likely represent the cold events identified in M23414. Although at site M23414 the benthic δ13C record does not resolve the cold events (Fig. 2), at Site 983 the younger cold event is reflected by δ13C of C. wuellerstorfi50 indicating an association with the slowing down of AMOC (Fig. 3). This apparent inconsistency can be solved by considering the different deep water sources at these sites. The supra-regional character of at least the youngest of these two events is supported by -based SST reconstructions from farther south and southeast of the SPG33,34,35,51, which all register a short climate deterioration at the end of postglacial warming, i.e. at the end of the global sea lever rise.
According to our age model the cold events at 411 and 414ka were obviously not linked to orbital forcing52,53 (Fig. 3). Moreover, their short durations do not fit with a connection to orbital forcing or other long-term drivers of climate variability. Although we cannot rule out as a cause flood-outburst events as described for the Holocene45 and MIS 5e54, but considering the long duration of post-glacial warming during MIS 11ss and the timing of the cold events near the end of postglacial sea level rise we would rather connect them to a continue release of meltwater from the GIS. Similar polar water advances into the SPG attributed to the ice sheet retreat was inferred for MIS 5e55. However, during MIS 5e these advances were associated with smaller temperature amplitudes which might be explained by less intensive melting processes. This seems plausible considering that MIS 5e was also of much shorter duration in comparison to MIS 11ss56. In contrast, enhanced and prolonged warmth during the early phase of MIS 11ss in the North Atlantic as well as the Arctic5,6,27 could have accelerated GIS melting and leading to its instability57,58. This may have resulted in a rather rapid (i.e. in comparison to the elapsed part of the Holocene) deglaciation of Greenland9 with further development of a forest vegetation over its southern parts which is an unique environmental feature for the last million years7. The continuous GIS decay during MIS 11ss resulted in an extensive eastward expansion of the polar waters in the Nordic Seas11,12,30. This was also corroborated by icebergs persistently arriving into the central Nordic Seas during MIS 11ss59. It is reasonable to assume that under such conditions deep water production could occur only in the southern part of the Nordic Seas (Norwegian Sea) because the fresh and cold buoyant surface layer in the central Nordic Seas would push the Atlantic water downward preventing deep water production11,12. Considering this one can assume that AMOC, although intense on interglacial time scale13,14,15,16, could experience enhanced sensitivity to freshwater inputs into the North Atlantic eventually resulting in short-term AMOC variability. Our assumption about an influence of GIS melting on AMOC is in accordance with modern observations that have registered suppression of deep water convection (though a slight one so far) in the Labrador Sea in response to the recent acceleration of the GIS loss60. Our results underscore the intricate interdynamic behavior of the North Atlantic climate system. Furthermore, if the present-day rapid summer melting of the GIS continues1, the resulting freshening of the surface ocean may well lead to fundamental structural changes in both ocean and atmospheric circulation as reconstructed for MIS 11.
The complete description of methods including of sample preparation for inorganic and organic analyses is provided in Supplementary Information (SI).
The analysis is based on the relative abundances of isoprenoid glycerol dibiphytanyl glycerol tetraethers (GDGTs) (Schouten et al.23). For GDGT analyses, the polar fractions of the total lipid extracts were dried under N2, dissolved in a mixture of hexane and isopropanol (99:1, v/v) and filtered using a 0.4μm PTFE filter. GDGT relative abundances were determined with high performance liquid chromatography/atmospheric pressure positive ionization-mass spectrometer (HPLC-MS) equipped with an auto-injector and Agilent ChemStation chromatography manager software. The core top value of 12.7°C derived from 0–200m matches well with the modern summer temperatures (Fig. S1). Standard deviation of replicate measurements ranges between 0–0.9°C. The0–200m temperature estimates presented in the main text were also compared to reconstructions derived from other widely used TEX86 calibrations (Fig. S3; all equations are placed in SI).
The ketone fractions from the total lipid extracts were analyzed by gas chromatography using an Agilent 6890 gas chromatograph (column CP SIL5CB, 25 mx0.32mm, film thickness 0.12μm) and a temperature program as follows: from 70 to 130°C at 20°C/min, and then to 320°C at 4°C/min, at which it was held isothermal for 15min with constant pressure 70kPa. Helium was used as a carrier gas. The SSTs were reconstructed according to ref. 22 (SST=(−0.44)/0.033). SST value reconstructed from the core tope sample (15.7°C) is close to the modern summer SST (Fig. S1B).
The hydrogen isotopic compositions of the alkenones were determined by a GC/Thermal Conversion/isotope ratio monitoring mass spectrometer (GC-TC-irMS) using a Thermo Electron DELTA V mass spectrometer coupled to a GC-isolink. The GC was equipped with a CPsil 5 CB column, 25meters long, 0.32mm wide with a film thickness of 0.4μm. The temperature program was used as follows: start at 70°C increased with 20°C min−1 to 145°C than with 8°C min−1 to 200°C followed by 4°C min−1 to 320°C where it was kept isothermal for 25min. Helium was used as a carrier gas with a constant flow of 1ml/min. The H3+ correction factor was determined daily and was constant at 5.70±0.03 ppm mV−1 for one batch of samples and 5.71±0.03 ppm mV−1 for the majority of the samples. A standard mixture of C16-C32 n-alkanes with certain isotopic composition (MIX B prepared by Arndt Schimmelmann, University of Indiana) was used as a control of the systems performance and samples were only run if the average deviation of the alkanes was below 5‰ from their off-line determined value. H2 gas pulses with a predetermined isotopic composition were let into the ion source before and after each sample run for a standardization of the measurements. Squalane with a known δD value of −170±4.0‰ was co-injected with each sample. The average of the δDsqualane measurements was −159.3±4.2‰. The δD measurements were performed for the combined C37:2 and C37:3 alkenones. Replicate measurements were produced when possible. Standard deviation of replicate measurements ranges between 0.8‰ and 3.7‰.
Foraminiferal census counts were performed using >150μm sediment subfractions. Each sample was split by means of a microsplitter to a subsample which contained a minimum of 300 foraminiferal tests. In order to retrieve SSTs from planktic foraminiferal abundances, the Transfer Function Technique27 (TFT) was used. IRD were counted in >150μm fraction27. In samples with a low IRD content IRD counts were performed separately from foraminiferal counts in order to achieve a better statistical accuracy of the results.
Stable isotope measurements on planktic and benthic foraminifera were performed at the Stable Isotope Leibniz Labor (University of Kiel) using a Finnigan MAT 251 mass spectrometer with analytical accuracy of 0.07‰ and 0.03‰ for δ18O and δ13C, respectively. All measurements were calibrated on the Vienna Pee Dee Belemnite isotope scale (VPDB).
All data presented in this paper are available at www.pangaea.de.
How to cite this article: Kandiano, E. S. et al. Response of the North Atlantic surface and intermediate ocean structure to climate warming of MIS 11. Sci. Rep. 7, 46192; doi: 10.1038/srep46192 (2017).
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The organic geochemical analyses were mainly produced in the frame of EC grant (the European Union’s Seventh Framework Program, Marie Curie Actions-Intra-European Fellowships for Carrier Development, grant agreement 302442 (PICKS)) with a contribution of grant supported by Deutsche Forschungsgemeinschaft (DFG) Ba 1367/8; Marcel van der Meer was funded by the Dutch Organization for Scientific Research (NWO) through a VIDI grant. Inorganic geochemical analyses were produced in the frame of the DFG project TH 200/40-1. This work was carried out in part under the program of the Netherlands Earth System Science Centre (NESSC), financially supported by the Ministry of Education, Culture and Science (OCW). We thank A. Mets, J. Ossebaar, M. Baas, and M. Verweij for analytical support.
The authors declare no competing financial interests.
Author Contributions E.K. performed the organic analyses as well as the foraminiferal and IRD counts. S.S. and M.v.d.M. advised E.K. on organic geochemical sample preparation and analysis. M.v.d.M. contributed to alkenone and δD analyses. K.F. conducted the first set of alkenone analyses. E.K. and H.B. compiled all other data and wrote the manuscript. All authors contributed to data interpretation and writing.