ICDP workshop COring the NOrth Sea Cenozoic focused on the scientific objectives and the technical aspects of drilling and sampling. Some 55 participants attended the meeting, ranging from climate scientists, drilling engineers, and geophysicists to stratigraphers and public outreach experts. Discussion on the proposed research sharpened the main research lines and led to working groups and the necessary technical details to compile a full proposal that was submitted in January 2016.
The COring the NOrth Sea Cenozoic (CONOSC) project aims for continuous coring
of the Cenozoic sedimentary record of the southern North Sea Basin. The
headlines of the planned research are summarized in two main questions.
In order to achieve this one has to investigate source–sink
interrelationships, carbon burial, and river development in relation to
changing Cenozoic climate gradients and evolving alpine tectonics in a site
where terrestrial and marine signals can be integrated and compared.
Furthermore, a high-resolution geologically and climatologically based
timescale calibration of north-western Europe is needed to analyse the
Cenozoic extinction rates, speciation, and migration patterns. The southern
North Sea Basin combines a continued setting at the hinge line of land and
sea, and active subsidence through much of the Cenozoic to meet conditions
for obtaining such an integrated record.
Secondary objectives of the drilling project include detailed and direct downhole geophysical monitoring of natural and human-induced seismicity.
Although the North Sea Basin (NSB) is extensively drilled for hydrocarbons, the Cenozoic part of the infill is generally not targeted and high-quality cores as well as a high-resolution stratigraphical framework for this era are lacking. Therefore, CONOSC aims to drill the Cenozoic sedimentary record at two onshore sites in the Netherlands that collectively span the larger part of the Cenozoic in a marginal marine geological setting. The Quaternary and Neogene record will be targeted in the Roer Valley Graben in the south of the country, while the Paleogene will be retrieved from well-developed sequences in the northern part of the Netherlands. It is intended to core the full Cenozoic sequence at both sites, respectively ca. 1800 and ca. 1000 m.
The ICDP workshop in Driebergen/Utrecht addressed four main topics. First and foremost the science questions and technical challenges, such as downhole seismic monitoring. What is the problem to be solved and how innovative are the scientific contributions? Secondly, the feasibility of the project: what is known about the drilling sites, technical operations, well-logging methods, core treatments, and sampling? Furthermore, attention was paid to scientific partnerships and cooperation with external partners like E&P operators, regional authorities, and partners active in geothermal energy and subsurface storage. Finally, ideas on outreach and education were discussed.
The main Cenozoic global climate events along the deep sea benthic isotope record (Zachos et al., 2008).
The CONOSC research plan is subdivided into six main themes, of which the discussion highlights are summarized in the following.
One of the important issues in palaeoclimate and palaeobiology is that a high-resolution record of the Cenozoic in the NSB can be tied firmly into a regional and global context, and patterns can be quantified and compared. The cored Cenozoic sequences will provide detailed analysis of a number of globally significant events ranging from the early Eocene thermal maxima (PETM, ETM2, Fig. 1) to the conditions surrounding the arrival of hominins in north-western Europe and their impact on the NSB (Fig. 2). A key aspect is that the Cenozoic cooling seems much stronger here than in other parts of the world at similar latitudes, and that especially seasonality of the climate increased. Throughout the Cenozoic, the target regions experienced climates ranging from subtropical swamps to polar desert. Hence, the retrieved record can help to improve modelling warm temperatures at high latitudes (polar amplification), and specifically detect the varying role of the North Atlantic current in this region.
Late Pliocene–Pleistocene targets against the deep see benthic oxygen isotope stack of Lisiecki and Raymo (2005). The climate/vegetational context is very important for landscape reconstruction with respect to the northward migration of hominins.
Schematic representation of a dense downhole array of seismic sensors coupled with a LOFAR surface array. Potential monitoring at the reservoir level falls outside the scope of CONOSC.
Both marine and terrestrial ecosystems experienced dramatic turnovers throughout the Cenozoic, but only partly due to climate. In north-western Europe in particular, increasing isolation though orogeny and seaway closure dramatically reduced the flora and faunal exchange and migration, leading to extinction and endemism. This may include the floristic response to increasing geographical (Alpine, Carpathian) isolation of northern Europe. But it will also show the effects on biogeography and evolution resulting from the closure of the Oligocene–Miocene interior seaways between the North Sea and the Mediterranean and the Paratethyan system. The rates and response times of these ecosystems transitions are key data that are currently lacking.
As the targeted sediments were deposited in a marginal shallow marine setting, they can contribute to understanding climate-induced changes of the terrestrial ecosystem with changing marine facies systems. Combined with a number of other proxies the pattern of changing (palaeo)climate can make a significant contribution to the understanding of the Cenozoic evolution of the NSB system. It also may contribute to understanding migration pathways of exotic species, especially during the lower Cenozoic in the NSB.
Other issues in this theme concern hydrological changes and sediment transport through river input during hyperthermals and subsequent cooling stages, to indicate signals for volcanism and tectonics, and the extent of euxinia in the NSB.
It is considered vital that a great number of biological and chemical proxies
be analysed. Organic fossil groups are known to be very important in the
basin (pollen and spores, dinoflagellate cysts), but also benthic and
planktic foraminifera, and in selected intervals also nannofossils and
molluscs. A number of geochemical techniques may be applied, e.g. stable
isotopes, Rock Eval pyrolysis for the hydrogen and oxygen index (HI is a
measure of the hydrogen richness in marine algae, lipids and proteins; OI
measures the oxygen richness of a source rock due to high CO
A well-dated and detailed stratigraphical record of the marginal sedimentary record in the southern NSB is a prerequisite for establishing the palaeoclimate and palaeovegetational response from greenhouse to icehouse on the margins of this mid-latitude marine basin. Established timescales do provide a rough calibration, but the increasing isolation and changing biogeography and sediment provenance mean that many timescales are “floating” chronologies in north-western Europe. Existing but outdated terrestrial standards can be much improved by providing the regional catchment-scale signals integrated with marine proxies. The improved biostratigraphy will allow a significant amount of earlier biostratigraphical work to be reappraised and integrated into a new synthesis for the regional Cenozoic basin evolution.
There are good opportunities to provide an integrated stratigraphy with
dinoflagellate cysts as backbone, complemented with calcareous microfossils,
potentially nannofossils, magnetostratigraphy, and selected calibration
points from geochronology (e.g. OSL,
Current induced seismicity in the northern Netherlands urgently requires
improved monitoring and fundamental knowledge of the exact origin to improve
risk assessments of mature gas fields in inhabited areas. The scientific
drilling provides the opportunity to implement long-term seismic monitoring
(more than 10 years) after coring, and possibilities for additional
monitoring are being investigated (e.g. downhole temperatures, dynamics of
freshwater to salt-groundwater transition, downhole pressures, and Earth
magnetism). The seismic monitoring will be incorporated into the existing
KNMI/NAM and LOFAR (low-frequency array) seismic 2-D networks (Fig. 3). The great
depth (up to 1000 m) of installed sensors and the coupling to the LOFAR
network will provide a 3-D component to the existing surface-based sensor
networks. Due to the increasing number of human-induced earthquakes
(resulting from gas extraction), there is high societal relevance for
monitoring the northern site. The southern site is situated in the Roer
Valley rift systems where naturally occurring earthquakes have been recorded
since the Middle Ages. The largest known earthquake there had a magnitude of
Scientifically long-term seismic monitoring is necessary for an in-depth
understanding of induced earthquakes, fault reactivation, and rupturing. Data
retrieved from greater depths are needed for validating existing
geomechanical models. The dense downhole array will provide data that can be
used to fill in the existing gap in regional-scale earthquake monitoring
(
The scientific questions comprise such issues as sedimentation rates and
cyclicities, which is a subject that is strongly related to a continuous and
accurate geochronology. Palaeomagnetic logging is seen as a prerequisite for
retrieving a highly accurate age model of the cored sequences. Careful core
scanning can help to detect volcanic ash layers and even impact ejecta which
may be very useful time markers. Core scanning and analysing provide detailed
insights into a number of layer properties so far unknown for the Cenozoic
sediments in the NSB. This includes amongst others the fundamental properties
of clays (e.g. the Boom clay), quantification of heterogeneities and
hydromechanical properties, etc. Gas (hydrocarbons and CO
Combining geophysical subsurface monitoring methodologies and the downhole variations in properties is needed to improve the interpretative value of these methods. Time-lapse gravimetry can be applied to improve shear-wave and induced earthquake models.
To determine the source and volumes of sediments deposited in the NSB, provenance studies have to be carried out. This can be done by combining different provenance indicators (e.g. XRF – bulk geochemistry; isotope analysis on zircons, micas, and feldspars; analyses of grain size and shape; pollen as source markers; clay mineralogy; and analysis of apatite fission-track provenance ages). A full data integration of these different proxies is seen as an innovative challenge: how to discriminate significant signals from general noise in the data sets and how to combine the provenance proxies with marine palaeobiological proxies? Complicating factors will be the reworking of sediment and lost or buried source areas. It is of great importance that existing archives of data (e.g. heavy mineral data at geological surveys and universities) can be explored and combined with newly retrieved data from the cores. Provenance data and a reliable age model will improve the insights into the evolution of drainage networks supplying sediment to the NSB. With respect to this aspect, the project will generate new palaeogeographical maps, and thus the (neo)tectonic and morphological evolution of the NSB will be known in greater detail than before.
Deep drilling up to 1000 m or more is often related to practical issues like mining, exploration, and exploitation of energy, water resources, and a number of governmental objectives. However, ICDP projects are primarily conducted to elucidate fundamental scientific questions and innovations.
Therefore, cooperation with industrial and scientific partners is of vital importance. In the course of developing a full proposal the CONOSC project has already involved a number of third parties that are interested in cooperating and contributing to the project. Some of them made specific demands on sampling; others will provide “in kind” contributions. It is intended to incorporate these activities as much as possible in the full proposal.
Equally important is the outreach to the general public and to explain why the scientific community conducts such a deep coring project in the NSB. Why do we want to know in great detail the past climate and evolution of the NSB, and why is Earth science a relevant science?
As the Netherlands is a densely populated country, public support and
therefore outreach are of utmost importance. The CONOSC project has to
generate early and open information channels to the broader public. Interest
in CONOSC should be generated by linking the project to issues that are in
the minds of people. Professional documentaries and videos showing the
development of the project and the execution of the coring and sampling are
seen as ways to help the project be embraced by the public. Recent IODP
(
Numerous additional issues were discussed during the workshop that cannot be covered in this brief report. However, all information will used to compile the full proposal. Practical but crucial issues on sampling and coring will be elaborated in the next months. In order to get a quick initial idea on the ages and ranges of the cored sections, it is agreed that first a biostratigraphical analysis will be carried out on core catcher material. All discipline groups will use standardized analytical methods and we will also work on a generally applicable system for data management and evaluation. It is intended that the Geological Survey of the Netherlands will take care of core storage and sample treatment (i.e. core scanning, description, photographs, sub-sampling session). Together with ICDP they will look for the best solution in data management tools.
All participants, including potential partners to cooperate with, are thanked for their valuable contributions to the workshop and their open-minded attitude during the various discussions.
More information on CONOSC and its progress can be found on the project's
websites (
Those interested in joining the CONOSC challenge are invited to contact Timme Donders (t.h.donders@uu.nl).
The authors wish to thank Paul Pearson and Phil Gibbard for their constructive reviews. ICDP is gratefully acknowledged for providing workshop funding. Edited by: T. Wiersberg Reviewed by: P. Gibbard and P. Pearson