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The Palaeocene–Eocene Thermal Maximum (PETM)1,2 was a period of transiently elevated global temperatures marking the earliest Eocene (~56 million years before present (Ma)) that lasted for ~200,000 years3,4 and had a profound influence on the global climate and ecosystems5,6. The PETM is of particular interest because it provides an example from the geological record with multiple similarities to present-day global warming associated with anthropogenic greenhouse gas emissions. Multi-proxy analysis of globally distributed sediment cores has shown that global surface temperatures rose by 5–6 °C during the PETM onset2,7, exceeding even the worst-case Intergovernmental Panel on Climate Change representative concentration pathway 8.5 scenario for temperature rise over the next few centuries8. The PETM is globally associated with a −2‰ to −7‰ carbon isotope excursion (CIE)9. The CIE onset was relatively rapid, followed by a plateau and protracted recovery period9. Mass-balance calculations indicate that the CIE onset was caused by the injection of up to 12,000 gigatons (Gt) of 13C-depleted carbon over a geologically rapid time frame of only a few thousand years10,11.

The widespread emplacement of magmatic intrusions into sedimentary basins during the formation of the North Atlantic Igneous Province (NAIP) around 56 Ma has been implicated as a potential carbon source for instigating the PETM2,12 (Fig. 1). Sill intrusions would have rapidly volatilized organic matter in surrounding sediments, transporting, among others, CH4 and CO2 to the surface by hydrothermal and explosive activity13,14. Geophysical observations show more than 700 potential hydrothermal vent complexes (HTVCs) on the mid-Norwegian margin alone12, and observations from other basins with less extensive seismic coverage such as the East Greenland margin indicate that they were also affected by sill intrusions and hydrothermal venting15. Detailed seismic interpretations placed the majority of the HTVCs close to the Palaeocene–Eocene palaeosurface16, hinting at a temporal correlation between thermogenic degassing and PETM hyperthermal conditions. Sill–sediment interactions are common features in continental large igneous provinces, and several studies have invoked thermogenic degassing as the cause of warming and extinction events associated with other large igneous provinces in the geological record13,17,18. Although the hypothesis that contact metamorphism of sedimentary basins could cause major environmental disturbances has gained substantial traction in recent years, definitive confirmation on the basis of field localities and precise geochronological records was lacking. Even in the comparatively recent NAIP, only a single borehole had previously been drilled into an HTVC, but it was not cored. The 20 samples from around the vent base in this borehole (6607/12-1) appear to show that this vent was active during the PETM CIE19. However, these well-cutting samples cannot be used to precisely determine the formation time of the HTVC; because of fall-in, there is significant uncertainty from which depth in the borehole materials derive. The water depths at which these vents formed and emitted carbon into the water column is crucial to the resulting atmospheric CH4 and CO2 fluxes. A shallow-water or subaerial vent will release gaseous carbon directly into the atmosphere, leading to less oxidation of methane via volatile–water interactions, thus enhancing short-term (decadal) atmospheric warming, as CH4 has a much more powerful greenhouse effect than CO2 (ref. 18). Therefore, further coring of NAIP HTVCs is required to assess the role of thermogenic degassing on the Palaeocene–Eocene carbon cycle, to provide a more precise age control and constrain the palaeowater depths that these vents erupted at.

Fig. 1: HTVCs on the mid-Norwegian margin.
figure 1

a, Structural elements46. Purple colours, extrusive volcanic elements related to continental break-up; green colours, Cretaceous basins; black dots, hydrothermal vents; grey, oceanic crust. Yellow dots, Deep Sea Drilling Project, Ocean Drilling Project and Integrated Ocean Discovery Program drill sites. For complete legend, see ref. 46. Inset shows location of study area. b, Three-dimensional view of seismic reflection data showing the relationship between volcanic intrusions (sills) and the palaeoseafloor depressions formed by the hydrothermal venting. BVU, interpreted Base Vent Unconformity. Industry 3D seismic data courtesy of TGS under a Creative Commons license CC BY 4.0.

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Rapid HTVC formation and infill

High-resolution three-dimensional (3D) seismic data document a shallow HTVC on the Modgunn Arch offshore Norway, a location less than 10 km from the rift axis of the Møre Margin (Fig. 1a). The HTVC consists of an approximately 400-m-deep and 200- to 240-m-wide feeder system that extends vertically from a sill complex at the bottom to a funnel-shaped seafloor crater at the top (Fig. 1b). The sill complex consists of several interconnected intrusions that extend at least 5 km laterally and that are probably several tens of metres thick, given their very high seismic amplitudes in the exploration 3D seismic data (Fig. 1b). The Modgunn Vent crater is approximately 80 m deep with respect to the surrounding palaeoseafloor. The seismic data show two styles of crater infill (Fig. 2). First, there are infilling strata that dip towards the centre of the vent, either draping or downlapping at the bottom and truncated at the top by an erosional unconformity. Second, there is a doming of these reflections in the central part of the vent. The dome is covered by onlapping reflections, suggesting mobilization and uplift of the crater infill after deposition. The seismically incoherent feeder system and the funnel-shaped seafloor depression are typical for HTVCs on the Norwegian Margin12,16,20,21. Similar feeder systems have been described in outcrops in the Karoo Basin (South Africa), where they consist of fragmented sedimentary rocks altered due to fluid migration and high temperatures13. The funnel shape and aspect ratio of the Modgunn Vent crater is similar to diatreme-crater systems in maar volcanoes22,23 and blow-out craters due to drilling accidents24,25,26 (Extended Data Fig. 1), indicating rapid initial formation by fluid overpressure release. The continuous nature of the infilling strata in most of the crater suggests undisturbed sedimentation and limited fluid migration after formation, as opposed to fluid escape systems that have been active for thousands of years27.

Fig. 2: Interpreted high-resolution 3D seismic image of the Modgunn Vent showing the location of the five boreholes.
figure 2

Note the unconformity that forms the top vent reflection, indicating shallow water depth shortly after vent filling. Onlap relationships on the vent fill between the top vent and base vent horizons document doming after the unconformity was formed. Black lines indicate the intervals penetrated by IODP Expedition 396 boreholes. Coloured markers on the boreholes indicate formation tops: orange, top early Eocene; magenta, top vent; dark yellow, top Palaeocene; light yellow, approximate vent conduit limit. Seismic data were depth converted, with 1,600 m s–1 corresponding to average P-wave velocity measured in the boreholes.

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International Ocean Discovery Program (IODP) Expedition 39628 drilled five boreholes up to 200 m below the seafloor and through the crater infill in the Modgunn Vent (U1567A–C and U1568A and B). The boreholes are situated along a 500-m-long transect from the crater rim to almost the centre of the vent next to the dome structure (Fig. 2). This unique drilling profile recorded high sediment core recovery (303.35 m or 82.9% and 239.37 m or 91.83 % for sites U1567 and U1568, respectively), allowing detailed and unparalleled characterization of the crater infill. The infill consists of two lithological units (IV and V) dominantly comprising very dark grey to black diatomite. Ubiquitous ash layers are present throughout the vent fill, attesting to the common occurrence of surface or shallow-water explosive volcanism during this period29 (Fig. 3). The boreholes of the sites U1567 and U1568 did not penetrate any hyaloclastite deposits or intrusive magmatic rocks. The Palaeocene and PETM sections of U1567, in the outer peripheral part of the vent fill, include well-preserved laminated diatomite, whereas the thicker mudstone sequence of U1568, proximal to the vent dome, is characterized by diagenetically altered ash-rich diatomite with much poorer siliceous microfossil preservation. We do not observe evidence for alteration by high-temperature fluids in the recovered sedimentary record. However, operational safety precautions prevented drilling at the centre of the vent, and such signatures, if present, could be confined to the central and deeper parts of the crater that we were not allowed to drill. Core catchers collected within the vent infill (lithological units IV and V; Fig. 3) yielded the dinoflagellate cyst (dinocyst) PETM-marker taxon Apectodinium augustum30. For the same samples, stable carbon isotope analyses of bulk organic matter (δ13Corg) show a characteristic negative CIE of ~2‰ compared with the underlying strata, documenting in situ infill of the crater following the onset of the PETM31 (Supplementary Fig. 1). The presence of graded ash beds and sub-millimetre-scale laminated (altered) diatomite all suggest rapid and largely undisturbed infill consistent with the seismic observations.

Fig. 3: IODP Expedition 396 borehole information showing the late Palaeocene and early PETM fill (lithostratigraphic units IV and V).
figure 3

From left to right, proximity to the centre of the HTVC decreases. The grey background delineates the Modgunn Vent infill. The ‘unconformity’ label indicates the unconformity that formed shortly after the vent; other unconformities are indicated by wiggly lines. The δ13C measurements were carried out on total organic carbon (δ13Corg). Red dots indicate the onset of the PETM CIE dominated by marine organic matter, and yellow dots indicate the PETM CIE with organic material largely derived from terrestrial sources. Biostratigraphic dating is discussed in the text and the electronic supplement. mbsf, metres below seafloor according to IODP’s C-SFA definition; LO, last occurrence; FO, first occurrence.

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Timing of HTVC formation

The greenish mudstones below the crater infill (Unit VI) contain the dinoflagellate cyst (dinocyst) taxon Alisocysta margarita, giving a late Palaeocene age for the host rock sediments in which the vent formed. Stable carbon isotope analyses of bulk organic matter (δ13Corg) from Unit VI samples show steady values of ~−25.8‰ (Fig. 3). Analysed samples from lithological Unit IV and upper part of Unit V (Fig. 3) yielded the dinocyst PETM-marker taxon Apectodinium augustum30 (Extended Data Tables 14). The first occurrence and consistent appearance of the diatom Hemiaulus proteus in these strata further supports a PETM age32. The lowermost samples of Unit V, which are also interpreted as vent infill, show continued stable δ13Corg values matching those in Unit VI and do not contain PETM-marker taxa. Around 10–15 m above the base vent in boreholes U1567B and U1567C is an ~6‰ drop in δ13Corg, marking the PETM CIE onset. Upwards, this is followed by a more moderate (~2‰) negative excursion compared with the underlying pre-PETM strata, documenting further infill of the crater following the onset of the PETM31 (Fig. 3 and Extended Data Fig. 2). The overall CIE shape appears to be influenced by a switch from predominantly marine to terrestrial sedimentary organic matter that was observed directly above the most negative δ13Corg values (Fig. 3). Palaeocene–Eocene terrestrial and marine organic matter are ~4‰ offset33, whereby, in contrast to present day, marine organic matter is more 13C-depleted compared with terrestrial organic matter34. When compared with age-equivalent samples with similar organic matter characteristics, it is clear that both the terrestrial and marine organic matter-dominated samples show δ13Corg values most consistent with those previously observed for the PETM CIE body33 (Supplementary Information and Extended Data Fig. 2). The shape of the CIE also matches that observed in a core from the northern North Sea35, the closest studied section to the Modgunn locality. The recovery phase of the CIE appears to be absent at the Modgunn sites, and we therefore argue that the vent formation occurred just before the onset of the PETM CIE and that the crater infill occurred throughout the latest Palaeocene and earliest phases of the PETM.

The erosional unconformity that forms the top of the vent infill is overlain by lithological Unit III, which consists of dark grey to brownish mudstones with concomitant occurrences of the dinocyst taxa Glaphyrocysta ordinata, Hystrichosphaeridium tubiferum and Deflandrea oebisfeldensis, and infrequent Membranilarnacia compressa (Supplementary Information). This assemblage indicates a middle early Eocene (<50 Ma) age for the unconformity and the sediments onlapping onto the dome structure36, implying that the Unit IV to Unit III erosional unconformity corresponds to a hiatus of >5 Myr. The seismic onlap relationship of the sediments above the unconformity and the dome structure furthermore indicate that remobilization and uplift of some of the crater infill occurred within ~5 Myr after the crater was infilled.

A shallow-water carbon source

The high-resolution 3D seismic data document the extent of the erosional unconformity that truncates the top of the vent infill and the host rock in its vicinity (Fig. 2). The unconformity is present throughout most of the high-resolution 3D seismic cube coverage, but it is more difficult to discern in the lower-frequency exploration 3D seismic data that cover the entire region (Fig. 1b). Nevertheless, regional conventional 3D seismic data show that the unconformity is present within an approximately 20 by 30 km wide area on the Modgunn Arch at the transition between the Vøring and Møre basins. Although deep marine erosion may form unconformities in exceptional oceanographic settings37, the fact that the unconformity on Modgunn Arch is laterally extensive and formed in a marginal basin is direct evidence for a shallow-water or even a short-lived subaerial setting during the earliest early Eocene.

The inferred shallow-water depth of the Modgunn HTVC is supported by the distinctly coastal marine palynological and diatom assemblages in the vent infill. Organic microfossils are overwhelmingly dominated by terrestrial elements (pollen, spores, heterogeneous transported land plant materials, alongside dinocysts with coastal to restricted marine to coastal ecological affinities such as Glaphyrocysta, Hystrichosphaeridium, Cerodinium, Senegalinium and Deflandrea spp.38) of lithological units IV and V (vent infill). The diatom assemblage that accumulated in the crater is dominantly coastal marine, neritic and typified by abundant and diverse Hemiaulus spp. as well as Sceptroneis, Syndropsis and Grunoviella spp., which are often associated with benthic or floating macroalgae39. There is ample evidence for (near-) coastal conditions, but we find no evidence for sedimentary redistribution by wave action, constraining the water depth inside the crater ring to below wave base, often assumed 30 metres (ref. 40).

Implications for PETM origin

The observation that the Modgunn Vent formed under shallow marine conditions implies that its impact on climate was significantly greater than if it had formed in the deep sea. Magmatic intrusion-related hydrothermal systems release both CO2 and CH4 (ref. 41), but for submerged systems, it is well documented that the water column acts as an efficient filter for CH4 as most is oxidized to CO2 in the water column before reaching the atmosphere42. While on decadal–centennial timescales CH4 is 25 times more potent a greenhouse gas than CO2, its atmospheric residence time is short (~9 years), after which it is oxidized to CO243. Therefore, direct and rapid addition of CH4 to the atmosphere results in greater initial warming and has a greater impact on climate and surface carbon feedback processes than does carbon emitted as CO244. Thus, the original CH4/CO2 ratio in HTVC volatiles, the rate of CH4 and CO2 venting and water depth are all highly relevant for the climatic effects of hydrothermal venting45.

Although we do not constrain the overall amount or the speciation of the carbon that was emitted by NAIP-related sill emplacement beyond the estimates by Svensen et al.12, our findings provide direct evidence that widespread HTVCs erupted in very shallow marine settings of the northern North Atlantic region around the time of the PETM. The characteristic CIE as recorded in δ13Corg appears to be positioned within the rapidly deposited vent infill but above the crater base. As this is observed in several, but crucially not all, boreholes in the transect, it is most likely that the studied vent formed just before the onset of the PETM and refilled during the onset and body of the CIE. The high-resolution C-isotope curve from Site U1567C places the CIE onset 11–15 m above the vent base (Fig. 2), which paired with exceptionally high sediment and ash accumulation rates indicate that the vent formed probably only a few millennia before the PETM onset (Supplementary Information). Notably, the stratigraphic record of this early infill is missing near the centre of the HTVC (U1568A) (Fig. 3), which could imply sediments could not accumulate there until around millennia after crater formation due to ongoing hydrothermal activity and/or slumping into the (active) crater centre

The shallow marine setting allowed for efficient injection of methane and other volatiles into the atmosphere at the time of formation. The Modgunn Arch is close to the ocean–continent boundary and therefore among the HTVCs on the mid-Norwegian margin that are closest to the rift axis, suggesting that many other vents were in equally shallow water or even above sea level at this time. This is supported by similar shallow near-coastal conditions reconstructed using palynological analyses of the cuttings obtained from the only other HTVC that has so far been drilled on the Norwegian Margin (well 6607/12-1; refs. 12,19). The direct and rapid injection of large volumes of hydrothermal gases, including methane, into the atmosphere at this time increases the potential impact of hydrothermal venting on global climate. Most important, our constraints on both the timing and environment of venting in the Northeast Atlantic are conclusive evidence for hydrothermal venting immediately before the PETM onset, and therefore it probably played a major role in driving hyperthermal conditions.

Methods

Seismic processing and interpretation

The high-resolution 3D seismic data were acquired in summer 2020 on board the Norwegian RV Helmer Hanssen using the P-Cable system47. This system consists of fourteen 25-m-long hydrophone cables spaced 12.5 m apart perpendicular to the ship’s steaming direction48. Each hydrophone cable contains eight receiver groups with a group interval of 3.125 m. Two mini-GI airguns with a total volume of 90 inch3 provided seismic energy with high frequency and relatively large bandwidth (20–400 Hz) at a shot interval of 6 s. The dominant frequency of the seismic data is at 170–180 Hz. The 3D seismic data were processed applying a standard, well-established processing sequence48,49. The sequence consists of removal of bad channels, geometry assignment, tide static and residual static corrections, compensation for amplitude loss (spherical divergence), de-ghosting in the pre-stack domain, band-pass filter, 3D binning at 6.25 × 6.25 m and normal moveout correction, mean stack, 3D spatial filtering to further reduce noise and 3D Stolt migration using a constant average water velocity. Seismic interpretation used the commercially available KingdomSuite seismic and geological interpretation software from S&P Global50 and the Petrel software from Schlumberger51. All five boreholes (U1567A–C and U1568A and B) at Modgunn Vent were integrated with the 3D seismic data to identify key stratigraphic marker horizons Top Palaeocene and Top early Eocene as well as vent infill and the top vent unconformity using the P-wave velocities measured on the cores and within the boreholes.

Biostratigraphy

For most pre-Quaternary core-catcher samples from holes U1567A (n = 21), U1567B (n = 9), U1568A (n = 25) and additional samples from U1568B (n = 2), approximately 5–10 cm3 (~10 g) of sediment was taken for palynological processing with strong acids (HCl and HF). Shipboard processing followed a shortened version of standard palynological laboratory protocols52. Samples were first soaked in a small volume (~5 ml) of 10% HCl to dissolve minor amounts of carbonate before addition of a larger volume (~25 ml) of 38–40% HF to partly dissolve silicates, all in 50 ml plastic centrifuge tubes. After cold HF digestion on a vortex shaker for ~2–4 h, samples were centrifuged at ~3,200 rotations per minute to separate the residue from HF and facilitate decanting the supernatant. Subsequently, the residues were treated twice with 30–35% HCl to remove any silica gels that may have formed and finally rinsed twice with demineralized water to neutralize any remaining acids. After each of these steps, samples were centrifuged, and supernatants were decanted. The residues were then sieved to remove large and small organic and residual mineral particles using 250 μm and 15 μm nylon sieves and an ultrasonic bath. The fraction between 15 and 250 µm was concentrated again using a centrifuge and mounted on glass microscope slides using glycerine jelly as the mounting medium and finally sealed with nail varnish for more permanent conservation. Each slide was entirely analysed for age-diagnostic species36,53 using a Zeiss transmitted light microscope at ×100–400 magnification and, when sample quality permitted, for a broad description of the palynofacies.

Shipboard analysis of biosiliceous microfossils was largely from smear slides using Zeiss transmitted light microscopy at ×630 and ×1,000 magnification, with selected samples sieved at 15 µm after disaggregation with 15% H2O2. Post-expedition analyses followed the slide preparation method of Warnock and Scherer54. Analysis of in situ diatomite laminations was carried out on board using a Hitachi TM-3000 scanning electron microscope. Further details on the biostratigraphic analysis are provided in the Supplementary Information.

Carbon isotopes

The total organic carbon (TOC) and stable carbon isotope ratios (δ13Corg) of each sample were determined by powdering and decalcifying using 1 M HCl for 72 h. The samples were oven dried at 50 °C and re-homogenized. Between 5 and 15 mg of decalcified sample was transferred to tin capsules and loaded into a Costech Analytical Zero-Blank Autosampler. The δ13Corg measurements and TOC concentrations were analysed using a Thermo Fisher Scientific Flash Elemental Analyzer, coupled to a Thermo Fisher Scientific DeltaV Isotope Ratio Mass Spectrometer at the CLIPT Lab, University of Oslo. Each sample was run in duplicate to test reproducibility, which was <0.06‰ and <0.01 wt% for δ13Corg and TOC, respectively.