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Holocene landscape reconstruction of the Wadden Sea area between Marsdiep and Weser

Explanation of the coastal evolution and visualisation of the landscape development of the northern Netherlands and Niedersachsen in five palaeogeographical maps from 500 BC to present

Published online by Cambridge University Press:  20 May 2015

P.C. Vos  and
E. Knol
P.C. Vos*
Affiliation:
Deltares, Department of Applied Geology and Geophysics, PO Box 85467, 3508 AL Utrecht, the Netherlands
E. Knol
Affiliation:
Groninger Museum, PO Box 90, 9700 ME, Groningen, the Netherlands
*
*Corresponding author: Email: peter.vos@deltares.nl
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Abstract

This paper describes the background of five palaeogeographical maps between the Marsdiep and the Weser River, and discusses the natural and anthropogenic processes driving the coastal changes during the last part of the Holocene. Before 2500 BC, during the first half of the Holocene, tidal basins were formed in the lower lying Pleistocene valley system as a result of the Holocene sea-level rise. The tidal basins were filled during the second half of the Holocene and on the deposits from the Pleistocene in the hinterland large coastal peat bogs developed. These peat bogs were vulnerable and sensitive to marine ingressions when the peat surface subsided due to drainage, compaction and erosion. During the Subatlantic (450 BC to present), the different ingression systems in the coastal area between Marsdiep and Weser had their own histories in timing and evolution. The ingressions were naturally caused by lateral migration of coastal barrier and tidal-inlet systems or by changes in the natural drainage system in the hinterland. From the Late Iron Age onwards, humans started to be the major cause of ingressions. By reclaiming and cultivating the seaward margins of coastal peat bogs, these areas subsided significantly and were flooded by high storm surges. When coastal areas were embanked during the historical period, the situation for the lower lying peat lands became more dramatic. When the sea dikes breached, the peat land was flooded, leading to casualties and huge material damages and loss of land. Drowning of the peat lands of the Jade and Dollard in the 14th and 15th centuries are examples of such catastrophes.

Keywords

Holocene geologylong-term coastal evolutionpeat subsidenceauto-compactioningressions
Type
Original Article
Information
Netherlands Journal of Geosciences , Volume 94 , Issue 2 , June 2015 , pp. 157 - 183
Copyright
Copyright © Netherlands Journal of Geosciences Foundation 2015 

Introduction

Recently a visual reconstruction has been made of the development of the coastal landscape of the northern Netherlands and Niedersachsen. This was done in the framework of the exhibition Het verdronken land is vruchtbaar (The drowned land is fertile) in the Groninger Museum (21 October 2013 to 9 February 2014). For this exhibition five palaeogeographical maps were compiled of the area between the Marsdiep tidal inlet and Weser Estuary (Vos & Knol, Reference Vos and Knol2014). The exhibition was part of the EU programme INTERREG IVa, a Dutch–German cross-border cooperation project.

Geological, geomorphological, archaeological and historical information of the coastal area of the northwestern Wadden Sea (Fig. 1) was used for designing these map reconstructions, reflecting the dynamic evolution of the coastal landscape of the Wadden Sea since 500 BC. The maps are indispensable for understanding the prehistoric occupation of the undiked salt marshes of the Wadden Sea. Human occupation of the marsh areas of northwest Germany and the Netherlands began in the Late Bronze Age and Early Iron Age (Taayke, Reference Taayke1996; Strahl, Reference Strahl, Endlich and Kremer2005). The background of the compilation of the map series and the main driving mechanisms responsible for the coastal evolution will be discussed. A major research topic of this paper is the role humans played in the transformation of the peat landscape by inducing large ingression systems in the coastal area.

Fig. 1. Locations of the Wadden Sea study area between the Marsdiep and the River Weser.

Origins of tidal basins and ingression systems

Geological processes and human interventions induced major changes in the Holocene coastal landscape. As a result of the global Holocene sea-level rise, after the last glacial period (the Weichselian) the Pleistocene landscape of the northern Netherlands and northwest Germany changed into a marine environment. Tidal channels locally eroded the subsoil and the lower parts of the Pleistocene valleys were flooded. These valley systems turned into tidal basins and where large rivers such as the Eems and Weser debouched into the sea they became estuaries (Fig. 2). The sea-level rise also led to a groundwater-table rise in the higher Pleistocene areas close to the expanding marine domain. Thus peat started to grow in the transitional Pleistocene areas.

Fig. 2. Location of the Early Holocene tidal basins in the northern Dutch and northwestern German coastal areas.

The Early Holocene Wadden Islands, tidal basins and estuaries migrated landward as a result of ongoing sea-level rise (van der Spek, Reference van der Spek1994a,Reference van der Spekb; Flemming & Davis, Reference Flemming and Davis1994; Oost, Reference Oost1995; Chang et al., Reference Chang, Flemming, Tilch, Bartholomä and Wöstmann2006; Kosian, Reference Kosian2009). In the last half of the Holocene the sea-level rise decreased sharply and the tidal basins silted up for the major part (Vos & van Kesteren, Reference Vos and van Kesteren2000; Vos & Knol, Reference Vos, Knol and Knol e.a.2005; Vos & de Langen, Reference Vos, de Langen and Huisman2008, Reference Vos, de Langen and Nicolay2010). The change from a drowning and retreating coastal area to a seaward expanding coastal area took place between about 5000 and 4250 BC (Cleveringa, Reference Cleveringa2000; Bungenstock & Schäfer, Reference Bungenstock and Schäfer2009) because from that period onwards the sediment supply to the basins outpaced the sea-level rise (Beets & van der Spek, Reference Beets and van der Spek2000). Because of the deteriorating natural drainage the peat area in the hinterland expanded strongly, in combination with the silting up of the tidal basins the salt-marsh area along or at the margins of the basins prograted seaward.

This study shows that from the Subatlantic onwards new sea branches intruded on the salt marshes and coastal peat bogs (Fig. 3). These ingressions may have a natural or an anthropogenic origin or a combination of both. One natural cause of new ingression systems was drowning of the coastal peat area when a protective natural coastal defence was lost, for instance by the lateral shift of a barrier and tidal-inlet system (N1; Fig. 4). The salt marshes became sensitive to erosion because of increases in the wave attacks on the salt-marsh coastline. When the protective salt marsh disappeared, the peat area behind became vulnerable to erosion. Because of the high water content of peat, it is very sensitive to compaction and subsidence. When peat was eroded, hardly any sediment (organic material) remained behind. The new accommodation space led to an increase in the tidal prism. As a consequence, the tidal channels and tidal inlet increased in size because of the linear relationship between the tidal volume and the (wet) cross-sectional area of the tidal channels (Sha & de Boer, Reference Sha and de Boer1991; Oost, Reference Oost1995; van der Spek, Reference van der Spek1994b). The increased tidal prism caused an increase in tidal range and maximum storm surge level (extreme high water, EHW). More and larger tidal channels improved the natural drainage, oxidation and subsidence of the drained peat. When the subsiding peat surface was flooded during storms, clay was deposited on top of it, which meant that the sediment load increased. Because of the weight of the clay the peat subsided further. This process is known as auto-compaction: subsidence of wetland peat by the gravitational pressure of newly deposited and infiltrated clay on and in the peat (Allen, Reference Allen1999; Long et al., Reference Long, Waller and Stupples2006). This favoured the self-reinforcing process of peat drowning.

Fig. 3. Locations of the active tidal systems in the northern Dutch and northwestern German coastal areas during the Subatlanticum. Green: tidal channels belonging to the old tidal basins which at the time had not yet silted up completely and where the tidal channel was still active (date indicates the last time at which the tidal basin system was still functioning). Red: locations of the ingression channels (dates indicate the active period of the ingression system).

Fig. 4. Schematic reconstruction of a naturally drowning peat landscape, before 100 BC, induced by erosion of the protecting coastal barriers and salt-marshes by tidal inlet and channel migration. This led to the drowning and formation of channels and creeks in the peat landscape, which resulted in subsidence of the peat surface caused by auto-compaction and drainage of groundwater via the channel system. The reconstruction is inspired by the Peasens ingression system. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Ingressions were also enhanced by the silting-up of the basin margins, forcing drainage from the peat to the lower lying (more compacted) hinterland, from where a new outlet was needed. Thus new outlets in the coastal system were created, implying a local transgressive development (N2; Fig. 5).

Fig. 5. Schematic reconstruction of a naturally drowning peat landscape, before 100 BC, caused by changing and migrating natural drainage systems in the hinterland. The driving processes of the subsidence of the peat surface were the enlargement of the new channel system, auto-compaction by deposition of a clay layer on top of the peat in that area, drainage of groundwater and oxidation due to natural drainage by the newly formed channels and creeks. The reconstruction is inspired by the Middelzee ingression system. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Since the late Iron Age/Roman Period humans have played an important role in the self-reinforcing processes by artificially draining the margins of the coastal peat landscape. This has led to a significant lowering and drowning of the inhabited peat land, leading to new ingressions (A1; Fig. 6). From the Late Medieval Period, when the salt marsh and peat lands were diked on a large scale, subsidence in the embanked coastal peat lands further increased. This led to catastrophic situations when dikes collapsed during storms, leading to large land losses (A2; Fig. 7).

Fig. 6. Schematic reconstruction of an anthropogenically drowning peat landscape, after 100 BC, as a result of reclamation and cultivation of the marginal zone of the coastal peat bog. The driving processes of the subsidence of the peat surface were drainage of groundwater, inundation of the peat land and enlargement of the tidal channels, auto-compaction by deposition of a clay layer on top of the peat and oxidation due to artificial drainage. The reconstruction is inspired by the Lauwerszee and Harlebucht ingression systems. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Fig. 7. Schematic reconstruction of an anthropogenically forced drowning of the peat landscape, after 1200 AD, caused by diking of the salt-marsh area and peat landscape and by artificial drainage of the land via sluices. The driving processes of the subsidence of the peat surface were drainage of groundwater, oxidation due to artificial drainage, catastrophic inundation of the peat land and erosion of the peat surface, and disappearance of the peat out of the system by floating and drifting peat islands. The reconstruction is inspired by the Dollard and Jade ingression systems. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Relevance of palaeogeographic maps

Landscape evolution with many ingressions and reclamations in the past can be used as a sounding board for studies related to coastal protection and future long-term development of the northern Dutch and German coastal zone and for prospective archaeological research. The reconstruction maps for the different archaeological periods indicate where habitation was possible and where it was not. Intertidal flat environments with semi-daily tides were unfit for habitation but highly silted-up salt marshes were suitable if settlements were built on dwelling mounds. The high biological productivity of this area made this tidal landscape very attractive for habitation. Not the whole salt-marsh area was suitable for occupation. The lowest parts, the pioneer zones, were not suitable because of frequent inundations. Geoarchaeological research in Friesland has revealed that salt marshes were inhabited only if the cover of salt-marsh clay had reached a minimum thickness of about 80 cm (Vos, Reference Vos and Besteman1999). By then the marsh had been silted up to the middle marsh level and it flooded less than about 50 days per year (Vos & Gerrets, Reference Vos and Gerrets2004). Regional palaeogeographic maps, which display these depositional environments, can thus be used as prospective maps. By linking this knowledge to geological layer information it can be assessed at which depth archaeological finds may be expected.

A future development in palaeogeographic mapping would be to add the subsurface (depth) to the two-dimensional map images such that three-dimensional landscape models can be constructed. By adding the time dimension to these models even 4D landscape reconstructions are possible. With advanced spatial palaeolandscape models, mid- and long-term morphodynamics can be better understood and forecast: the past as a key to the future, and an opportunity for future palaeogeographic research.

History of Holocene landscape reconstructions

Long tradition of landscape reconstruction in the Netherlands

In the Netherlands there is a long tradition of composing palaeogeographic maps. The manuscript map of the Roman period by Arnoldus Buchelius (1565–1641) is the oldest known reconstruction map of the Netherlands. It is based on Roman writers such as Tacitus and Pliny. In 1574, Jacob van der Mersch made a reconstruction map of the drowned and lost lands in the Dollard following similar Flemish maps of the drowned lands along the Westerschelde and Oosterschelde (Knottnerus, Reference Knottnerus and Essink2013). Later historians investigated the courses of former rivers such as the Fivel in Groningen and lateral migrations of the Wadden Islands (van Veen, Reference van Veen1930; Isbary, Reference Isbary1936).

In the 1950s Pons and co-workers began the first map reconstructions of the Dutch coastal area based on the geological data of Noord-Holland and Flevoland, and subsequently of the whole of the Netherlands (Pons & Wiggers, Reference Pons and Wiggers1959, Reference Pons and Wiggers1960; Pons et al., Reference Pons, Jelgersma, Wiggers, de Jong and de Jong1963). In the 1970s and 1980s regional studies of Groningen and Friesland were done (Roeleveld, Reference Roeleveld1974; Griede, Reference Griede1978; Griede & Roeleveld, Reference Griede and Roeleveld1982) and it became clear that before the Middle Ages large parts of the western and northern Netherlands were covered with an extensive peat bed that in many places has almost or completely disappeared. This peat bed covered West Friesland and the lower parts of Friesland and Groningen (Borger, Reference Borger2007; Slofstra, Reference Slofstra, Huisman, Bekkema, Bos, de Jong, Kramer and Salverda2008). This finding changed the palaeogeographic map picture dramatically as compared to the previous palaeogeographic maps of Zagwijn (Reference Zagwijn1986).

The idea of an extensive peat cover on the sandy areas of Oostergo, Westergo and the Groninger Wold, confirmed by several observations below cemeteries, was quickly embraced by archaeologists and historical geographers. It agrees with the fact that there are hardly any archaeological observations in the time span between Late Neolithic and Bronze Age finds on the one hand, and Medieval finds on the other. The medieval colonisations and their consequences for the peat area were the subject of many archaeological and historical studies: Wassermann (Reference Wasserman1985), Mol et al. (Reference Mol, Noomen and van der Vaart1990), Casparie & Molema (Reference Casparie and Molema1990), Groenendijk & Schwarz (Reference Groenendijk, Schwarz and Knottnerus1992), de Langen (Reference de Langen1992), Knol (Reference Knol1993), Fokkens (Reference Fokkens1998), Schwarz (Reference Schwarz2004, Reference Schwarz and Schmid e.a.2005), Ligtendag (Reference Ligtendag1995), Knottnerus (Reference Knottnerus2005, Reference Knottnerus2008), Bakker (Reference Bakker2001, Reference Bakker2002, Reference Bakker2003), Brinkkemper et al. (Reference Brinkkemper, Bijkerk, Brongers, Jager, Kosian, Spek and van der Vaart2006), Spek (Reference Spek, Huisman, Bekkema, Bos, de Jong, Kramer and Salverda2008), Groenendijk & Bärenfänger (Reference Groenendijk and Bärenfänger2008), van den Broek (Reference van den Broek2011) and Kortekaas (Reference Kortekaas2013).

Many subregional reconstructions were made during previous decades, often with an archaeological background, of the IJsselmeer (or former Zuiderzee area; Lenselink & Koopstra, Reference Lenselink, Koopstra, Rapporl and Soonius1994; Lenselink & Menke, Reference Lenselink and Menke1995), the Lauwerszee region (Vos, Reference Vos1992; Groenendijk & Vos, Reference Groenendijk and Vos2002), Westergo (Vos, Reference Vos and Besteman1999; Vos & Gerrets, Reference Vos and Gerrets2004), the northern Dutch coastal area (Vos & Knol; Reference Vos, Knol and Knol e.a.2005; Vos & Bungenstock, Reference Vos, Bungenstock and Kegler2013; Vos & Knol, Reference Vos, Knol and Essink2013), Oostergo (Vos & de Langen, Reference Vos, de Langen and Huisman2008) and the Eems-Dollard (Vos, Reference Vos2011).

Elsewhere, regional palaeogeographical maps were produced of Zeeland (Vos & van Heeringen, Reference Vos and van Heeringen1997), the Oer-IJ (Vos et al., Reference Vos, Bunnik, Cremer and de Vries2010) and the Kop van (northern part of) Noord-Holland (Lambooij, Reference Lambooij1987; Woltering et al., Reference Woltering, Besteman, van Regteren Altena and Hallewas1999). The Nationale Onderzoeksagenda Archeologie (National Research Agenda Archaeology; Vos, Reference Vos2006) was an incentive for constructing new palaeogeographic maps of the Netherlands resulting in the Atlas van Nederland in het Holoceen (Atlas of the Netherlands in the Holocene; Vos et al., Reference Vos2011). An update of these maps (version 2.0) has been made in Vos (Reference Vos2013a). Amongst other features, in this new version a distinction is made between intertidal flats (flooded twice daily) and salt marshes (flooded only during spring tide and/or storm surges), and the reconstructed peat expansion of the 100 and 800 AD maps has been modified significantly based on new data from the area to the northeast of the town of Schagen (Vos, Reference Vos2012). The distinction between mudflats and salt marshes on the new maps makes clear where people could settle (salt marshes) in the tidal area and where they could not (sand and mudflats). It provides an insight into the occupation possibilities in the past and the opportunity of finding archaeological sites.

Coastal reconstructions in Germany

Unlike in the Netherlands, palaeogeographic reconstructions in northwestern Germany have mainly been made by historians and archaeologists, and focus in particular on coastline development. In 1909, Ramaer compiled a series of maps from the late Middle Ages (1250 AD) up to the present in which the evolution of the Eems–Dollard region in both countries was reconstructed. A map of this area in 1000 AD was compiled by Wasserman (Reference Wasserman1985). A detailed study of the mouth of the Eems based on ancient nautical maps is also available (Lang, Reference Lang1955, Reference Lang1958).

In 1943 a series of reconstructions of the Ostfriesische islands from 1623 onwards was made by Backhaus. Sketches of the original locations of Langeoog Island, from the 8th to the 2nd century BC and from the 1st and 13th centuries AD, were compiled by Barckhausen (Reference Barckhausen1969).

Linke's (Reference Linke2001) study of the geology of Neuwerk Island is useful for reconstructing the landscape there. Rough sketch maps of the coastal evolution from 7500 and 6500 BC to 800 AD were published by Flemming & Davis (Reference Flemming and Davis1994). Homeier (Reference Homeier1969, Reference Homeier1977) reconstructed the successive coastlines and made a regional reconstruction of northwestern Germany around 800 AD. He rightly suggested a major expansion of peat areas in the higher Pleistocene sandy areas. Behre (Reference Behre1999) reconstructed the coastlines of the marsh areas in the northwestern German coastal area for 1500 and 1800 AD. For the Reiderland, Behre (Reference Behre1986a) made detailed landscape reconstructions. As part of his sea-level studies, he also proposed palaeo-coastlines. The study of the Jade–Weser area resulted in a number of palaeogeographic maps for the beginning of the Christian era and for the years 800 AD and 1362 AD (Behre, Reference Behre1999; Reference Behre2004, Reference Behre2005). Palaeogeographic maps of the area around the Jadenbusen and Weser were made by Behre (Reference Behre2012) for the time slices around the birth of Christ, and 800, 1300, 1362 and 1520 AD. The peat land extension on these maps was derived from geological map data and did not change in these reconstructions.

Laser altimetry data of the ground level (Actueel Hoogtebestand Nederland (AHN) in the Netherlands, Digitale Geländmodelle (DGM) in Germany, Light Detection And Range (LIDAR in the UK) up to now have hardly been used in geo- and archaeo-landscape research of Niedersachsen. The study of Heinze (Reference Heinze2013) of the area around Bensersiel was one of the first.

Methods of palaeogeographical map reconstruction

Data and scale

The main depositional environments in the coastal system are tidal channels, sand- and mudflats, salt marshes and peat bogs. Information about the extent of these environments in the past has been derived from geological, geomorphological and pedological map data and observations. Using dating techniques, archaeological data and historical sources, the palaeo-sedimentary environments have been reconstructed. The level of detail of the palaeolandscape maps depends on the scale of the mapping programme (national, regional or local), and the available geological and archaeological data.

The Marsdiep–Weser reconstructions have been made at a working scale of 1:100.00 and thus they are between the ‘regional’ and ’national’ mapping scales, which are compiled at scales of 1: 25.000/50.000 and 1: 500.000/1.500.000, respectively.

The most important basic data for the map reconstructions are from geological and pedological mappings, geoarchaeological research and elevation data of the present-day surface. This is especially the case for the maps of 500 BC, 100 AD and 800 AD, whereas the maps for 1500 and 2000 AD rely heavily on historical and recent topographical data, the AHN elevation maps. Pedological maps provide insight into the extent of the peat and clay cover, and the occurrence of palaeochannel fills at the surface. The geological maps supply data about the Holocene units in the deeper subsurface and the top of the Pleistocene deposits (see references to Dutch and German geological and pedological maps in the appendix). For the new lithostratigraphy of the Netherlands see de Mulder et al. (Reference de Mulder, Geluk, Ritsema, Westerhoff and Wong2003), and for the adjusted lithostratigraphy of the Northern Netherlands see Vos (Reference Vos2013b). For the background to the geological mapping of the coastal area of Niedersachsen see Streif (Reference Streif1989a).

On the AHN surface elevation maps the deposition patterns of the last phase of sedimentation are well illustrated. In many places the marine sedimentation stopped in the Late Medieval period, when large parts of the coastal area were diked. Morphological surface structures recognised on the elevation maps are, for example, salt-marsh ridges. For the determination of the age of these landscape forms 14C and OSL methods have been used to date the deposits of the coastal landscapes, and geoarchaeological information from excavations has been used in dating the ages of the different palaeo-environments. The geoarchaeological research carried out within the framework of the archaeological key sites in the Northern Netherlands is documented in Vos (Reference Vos and Besteman1999, Reference Vos2001a,Reference Vosb, Reference Vos2002a,Reference Vosb, Reference Vos2004, Reference Vos2007, Reference Vos2011, Reference Vos2012), Vos & Groenendijk (Reference Vos and Groenendijk2005), Vos & de Vries (Reference Vos and de Vries2009, Reference Vos and de Vries2011, Reference Vos and de Vries2012), Vos et al. (Reference Vos, Bunnik, Cremer and de Vries2010), Theunissen et al. (Reference Theunissen, van Doesburg, Vos and Laarman2005), Lubbers & Osinga (Reference Lubbers and Osinga2007), Waldus & Vos (Reference Waldus and Vos2006), Waldus et al. (Reference Waldus, Vos and van der Heijden2005) and Dresscher & Vos (Reference Dresscher and Vos2010). The use of archaeological data for the coastal reconstruction of the Northern Netherlands is described in Vos & Gerrets (Reference Vos and Gerrets2004).

Landscape reconstruction of the Dutch part

The Dutch part of the map reconstructions are based on the second-generation Atlas maps of the Netherlands (Vos, Reference Vos2013a). As mentioned above, a large number of recent regional reconstructions was available, allowing great regional detail. In the new maps the tidal areas have been subdivided into mudflats and salt marshes, with the (relatively) high-lying salt marshes and tidal levee systems indicated separately. The ridges formed along the former salt marsh and tidal creeks and are up to several decimetres high. These morphological features can be easily recognised on the AHN elevation map. In the dating of these ridges archaeology contributed to a large extent (e.g. Vos & Gerrets, Reference Vos and Gerrets2004).

Landscape reconstruction of the German part

The landscape reconstruction of the German part of the survey area relied heavily on the geological maps of Niedersachsen (1:25.000). From these, an overview map of the top of the Pleistocene surface has been made (Holozän basis; GHBK25, see appendix). From the geological surface maps (GK25) the extent of the peat and clay layers near the surface could be determined and the patterns of large tidal channel systems could be copied. The periods during which tidal channels were active in the coastal region of Niedersachsen have been derived from the coastline reconstructions and maps of Behre (Reference Behre1999, Reference Bakker2001, Reference Behre2004, Reference Behre2012). These maps supply important data for the expansion of channel systems and the timing of salt-marsh losses.

For the dating of peat, ages have been used as indicated by Streif (Reference Streif2004) in five coastal geological cross-sections between the Eems and Weser. For the reconstruction of peat bogs on higher Pleistocene grounds, the Campsche Karte von Ostfriesland (Camp's map of Ostfriesland) from 1806 was very valuable (Willem Camp, 1761–1855; republished by Henninger et al., Reference Henninger, Kappelhoff and Schumacher2005). On this map, the high moorlands and low fens which were still widespread at the beginning of the 19th century are indicated. Based on this and other historical information, the Landesamt für Bergbau, Energie und Geologie compiled a map of the original distribution of moors in the Niedersächsisches Bodeninformationsystem (NIBIS). This information is used for map reconstructions from 500 BC to 1500 AD.

Much of the reconstructed original peat cover has disappeared since the 20th century. The remainder, depicted on the map of 2000 AD, has been derived from the geological map of Niedersachsen. The older the reconstruction maps (1500 and 800 AD), the more the extent of the peat bogs, compared with the Campsche Karte and moor reconstructions of the NIBIS.

It is assumed that already between the 9th and 19th centuries parts of the peat disappeared due to human activities (land reclamation and peat extraction). In the maps of 500 BC, 100 AD and 800 AD, the extent of the peat and the river courses in the higher Pleistocene area have been kept the same, an arbitrary choice.

The DGM map images have been used particularly to reconstruct the watercourses in the higher Pleistocene sand areas. The DGM elevation data were available only in a raw form through the internet, therefore the morphological surface structures in the coastal areas (salt-marsh ridges and tidal levee systems) could not be mapped in Germany with the same accuracy as in the Dutch part.

In the oldest maps (500 BC–800 AD), the Ostfriesische Wadden Islands have been located between the reconstructed main tidal channel systems, somewhat more to the north than the current coastline of the Wadden Islands as the islands have moved landward (Flemming & Davis, Reference Flemming and Davis1994). For the position of the islands on the map of 1500 AD the reconstructions by Backhaus (Reference Backhaus1943) and Barckhausen (Reference Barckhausen1969) and the map of Waghenaer from 1575 are important guidelines. For the reconstructions up to 1500 AD the locations of the islands have a large degree of uncertainty.

Landscape reconstruction from the Bronze Age onwards

In Figs 8–12 the landscape evolution of the Dutch and northwestern German Wadden Sea region is visualised after the Bronze Age (2000–650 BC), the period when the colonisation of the coastal areas began. The settlers lived on higher parts of the salt-marsh area. Some finds from the Late Bronze Age (Strahl, Reference Strahl, Endlich and Kremer2005) suggest that locally humans lived in the marshes but not on a large scale. This is remarkable since from a landscape perspective the salt-marsh area was suitable for habitation if settlements were raised artificially. Apparently, there was little need for the Bronze Age humans to settle in the Wadden Sea coastal area. The occupancy of the higher, dry – and not peat covered – Pleistocene soils was sufficient. Around 600 BC pioneers from the margins of the German estuaries migrated to the Dutch salt marshes, soon followed by people from Drenthe (Taayke, Reference Taayke1996). Humans constructed dwelling mounds in these marshes to be safe during storm flood inundations. In Friesland these dwelling mounds are called terpen, in Groningen wierden and in Germany Wurten or Warften.

Fig. 8. Palaeogeographic map of the study area around 500 BC.

Fig. 9. Palaeogeographic map of the study area around 100 AD.

Fig. 10. Palaeogeographic map of the study area around 800 AD.

Fig. 11. Palaeogeographic map of the study area around 1500 AD.

Fig. 12. Palaeogeographic map of the study area at 2000 AD.

700–100 BC (Fig. 8)

In the Early Iron Age (650–0 BC), the Dutch tidal basins were still open to a great extent, and the salt marshes of the German part were located mainly within the current Wadden Sea. In subsequent periods, the northern Dutch tidal basins silted up more and more, and became salt-marsh land, whereas in large parts of the northwest German coast the salt marshes were subject to erosion and retreated because of the exposed position to the sea.

Around 500 BC parts of the ancient tidal basins of the Boorne, Hunze, Fivel and Ur-Jade were still open, and the Zuiderzee had not yet come into existence. Two large Flevo lakes were present in the IJsselmeer region. The Overijsselse Vecht River flowed into the northern Flevo Lake, which was connected with the Wadden Sea. Through this outlet, marine influence was noticeable in the surroundings of Medemblik (Vos et al., Reference Vos, Bazelmans, Weerts and van der Meulen2011).

As a result of ingressions in the northern and southern Flevo lakes around 400 BC, the Zuiderzee came into existence (Vos et al., Reference Vos, Bazelmans, Weerts and van der Meulen2011). In this period the Oer-IJ stopped draining the southern Flevo Lake and the Utrechtse Vecht River started to silt up. Since then the peat area around the Zuiderzee and the Utrechtse and Overijsselse Vecht rivers discharged into the Wadden Sea. Through the enlarged outlet the sea penetrated more and more, resulting in further erosion and flooding of the peat area. Observations at the location Schagen de Nes, northeast of Schagen (Vos, Reference Vos2012), show that already in the Middle Iron Age clay was deposited on the peat along the draining channels. The drowning of the peat in this region continued into the Middle Ages (450–1500 AD). It is likely that humans played a role in this drowning because in the northern part of Noord-Holland many traces of Roman and medieval peat reclamations occur.

Around 500 BC the salt-marsh area in the tidal basins of the Boorne, Hunze and Fivel rivers had expanded strongly as the result of a continued silting-up. With the silting of the Boorne tidal basin the drainage systems of the Marne and Middelzee became the outlet for the hinterlying peat area and they increased in size and became ingression systems. The expansion of the Middelzee in western Oostergo began around 1200–1000 BC. In the first stage this was a natural ingression that continued until Roman times, when marine influence of the expanding channels of the Middelzee became increasingly noticeable in the region around Sneek (Vos, Reference Vos2007; Vos & de Vries, Reference Vos and de Vries2009, Reference Vos and de Vries2011).

In the eastern part of Oostergo, the area between the Boorne and the Hunze basins, large-scale marine flooding took place in the peat area present at that time (Griede, Reference Griede1978). This ingression channel is named after the local Paesens River, which continued until Engwierum. On both banks of this palaeo-channel clay was deposited on the peat. The development of the Paesens system did not have an anthropogenic cause because humans did not yet inhabit this part of the coastal area on a large scale. The ingression of the Paesens system into the peat area of De Kolken is related to the opening of the coastline east of Ameland. In the first half of the Holocene the coastal area there protruded into the sea for a long time. This headland in the coastline was related to the Pleistocene High of Damwoude in the subsurface, a continuation of the Drents Plateau. It is assumed that due to the straightening and retreat of the coastline near Ameland the coastal barrier to the east was eroded. The hinterlying peat area was not protected anymore, and subsequently a self-reinforcing peat drowning process started, resulting in the Paesens ingression system.

The silting-up of the Hunze and Fivel basins continued gradually after 500 BC. The enlargement of the salt marshes in these areas has been archaeologically dated on the basis of the ages of dwelling mounds (terpen), which become younger seaward (Vos & Knol, Reference Vos, Knol and Knol e.a.2005).

Around 500 BC, the main channel in the Eems estuary was located near the current dike between Emden and Greetsiel. In the Iron Age and Roman Period (0–450 AD) this channel migrated towards the area between Bierum and the Punt van de Reide. There, this led to a landward (transgressive) shift of the mudflat/salt-marsh border and clay deposition on the adjacent peat area (Theunissen et al., Reference Theunissen, van Doesburg, Vos and Laarman2005). These deposits are referred to as the Eems Clay (de Smet, Reference de Smet1960, Reference de Smet1962). In contrast, on the German side of the Eems silting-up occurred as a consequence of the diversion of the main channel and the marshes expanded seaward, and tidal channels, such as the Sielmönkener Bucht, gradually silted up (see map reconstructions in Vos & Bungenstock, Reference Vos, Bungenstock and Kegler2013 and Vos & Knol, Reference Vos, Knol and Essink2013).

Northwest of Norden a Pleistocene high, the continuation of the Oldenburger-Ostfriesland Plateau, was oriented in the direction of the island of Juist. This Pleistocene headland, the High of Norden, is comparable to the Damwoude High. Around 500 BC a salt-marsh area called Bant was present at this high. This salt-marsh area gradually disappeared due to continuing erosion and the enlargement of the tidal flat area (Lang, Reference Lang1951; Haarnagel, Reference Haarnagel1979). The tidal-flat/salt-marsh coastline between Esens and Wangerooge was located in the current Wadden Sea (Heinze, Reference Heinze2000; Niederhöfer, Reference Niederhöfer2013), and the inland coastal peatbog had reached its northernmost position. Only small peat-draining rivers like the Benser, Harle and Crildumer debouched into the Wadden Sea. At that time no large ingression had yet developed in this region.

The Ur-Jade (the forerunner of the current Jadebusen) and the Maadebucht together formed a tributary of the Weser estuary with its mouth between Butjadingen and Cuxhaven (Behre, Reference Behre2012). The Ur-Jade and Ur-Maade were drainage rivers of the hinterlying peat area.

In the course of the Iron Age, in both the German and Dutch parts of the Wadden Sea, occupation intensity increased. This is evidenced by the increase in the number of mounds in these areas. Also the border zone of the peat bogs adjacent to the coastal area was more and more intensively occupied, amongst others, between Leeuwarden and Sneek (Lubbers & Osinga, Reference Lubbers and Osinga2007) and along the seaward margin of the former peat bog northwest of Bensersiel (Heinze, Reference Heinze2000). Thus humans played an increasingly important role in shaping the rural landscape from Roman times onwards (Behre, Reference Behre2012). In the salt marshes and the adjacent peat zone, ditches and trenches were dug on a large scale. In all archaeological excavation sites from that period artificial drainage structures have been encountered. The ditches were connected to natural drainage systems, so that drainage of the area was improved artificially.

As a result of the digging of the ditches, tidal water could be transported easier and faster from the Wadden Sea to the hinterland through the dug ditches and canals. The drainage pattern of natural channels and creeks was artificially changed so that channel systems could cannibalise others, and the groundwater level in the drained area was lowered, allowing oxygen to penetrate the soil so that peat material decomposed (also below the clay cover) and disappeared, particularly at the seaward margin of the peat lands. Grey, organic and humus-poor clays were formed because the plant material of the marsh surface was oxidised completely.

Particularly along the seaward margin of the peat the effects of anthropogenic interventions were extensive because artificial drainage there resulted in strong subsidence. Large-scale man-made parcellation patterns from that time occur, amongst others, in Schagerbrug (west of Schagen), Hempens (south of Leeuwarden; Waldus, Reference Waldus1999) and near Kolken (Nicolay, Reference Nicolay2010). The palaeolandscape research at the archaeological site of Arkum (south of Bolsward) showed that the grey clay cover was deposited from the (tidal) ditches that had been dug there, since major tidal creeks were lacking in the area. Those ditches drained the area well and the groundwater level in the marsh was lowered. From about 100 AD onwards no organic matter was retained in the salt-marsh clay anymore and a grey, humus-poor clay was deposited. Also east of Arkum (near Sneek) the seaward margin of the peat area was silted over after the Late Iron Age and a clay layer was deposited. There too, it is plausible that the digging of ditches played an important role in the silting over. It is likely that the Middelzee tidal channel north of Sneek was a ditch or canal initially. Its straight course and the fact that this channel cuts through a Pleistocene ridge in the subsoil support this view. The incision of the channel to a depth of about 10 m –NAP is explained by the fact that this ‘anthropogenic channel’ has taken over part of the discharge of the Marne (Vos & de Vries, Reference Vos and de Vries2011). This expansion of the tidal storage area of the Middelzee resulted in strong tides and thus to an enlargement and deepening of the man-made ditch.

Small-scale dike structures were already made in the Late Iron Age and Roman Period. Remnants of these dike structures have been found during excavations in the dwelling mounds of Wijnaldum, Dongjum, Peins-Oost and Anjum (Bazelmans et al., Reference Bazelmans, Gerrets, Koning and Vos1999; Nicolay, Reference Nicolay2010). They were primarily intended to protect the farmlands around the dwelling mounds (terps).

100 BC–400 AD (Fig. 9)

During the Late Iron Age and Roman times, at increasingly more locations in the northwestern Dutch and German Wadden Sea, marine sedimentation in the marginal peat lands took place. Clay deposits from that time on the marginal peat bed have been found in the northern part of Noord-Holland (Vos, Reference Vos2012), in the region around Sneek (Lubbers & Osinga, Reference Lubbers and Osinga2007) and east of Leeuwarden near Wartena in the central and eastern part of Groningen (Wold area and vicinity of Appingedam; de Smet, Reference de Smet1960, Reference de Smet1962), and in the coastal area between Norden and Esens (Streif, Reference Streif2004). This is striking because in the tidal basins of the rivers Boorne (Westergo) Hunze, Fivel (Vos, Reference Vos and Besteman1999; Vos & van Kesteren, Reference Vos and van Kesteren2000) and east of the Eems estuary between Emden and Greetsiel (Behre, Reference Behre1999) the development of the salt marshes was largely regressive. Subsidence in the border zones of the peat areas – caused by human reclamations – is likely to have played a role all around the northwestern Wadden Sea. However, more factors may have played a role in the drowning of the border zones of peat areas. The continuous sea-level rise will certainly have contributed to the inundation during major floods. The average sea level rose by about 5–10 cm per century (Kiden et al., Reference Kiden, Denys and Johnston2002, Reference Kiden, Makaske and van de Plassche2008). In addition, specific regional factors may have played a role, such as an increase in the tidal inlet system, by which the maximum storm surge levels in the tidal hinterland could rise.

In the northeastern part of Groningen, the southwestward migration of the Eems Channel certainly had an impact on the drowning of the peat in the hinterland during the Late Iron Age and the Roman period.

In this period, in Wangerland, west of the Weser estuary, the sea intruded into the peat area and the Crildumerbucht ingression system developed (Behre, Reference Behre1999, Reference Behre2004, Reference Behre2012). Datings of the top of the peat – below the covering clay layer – indicate, however, that landward of the ingression system peat development continued until the Roman period (Streif, Reference Streif2004). It is not clear whether the ingression of the Crildumerbucht system had a natural cause (erosion of the protecting coastal barrier), an anthropogenic origin or a combination of both. The more southerly Maadebucht system was further enlarged in the Iron Age (‘Duinkerke I deposits’, cf. Behre, Reference Behre1999). At that time the Jadebusen remained free from major flooding and stayed a (high) peat moor area until the Late Middle Ages (1000–1500 AD).

400–1000 AD (Fig. 10)

During the Migration Period (400–500 AD) the occupation intensity in the salt-marsh area of the northwestern Wadden Sea reduced sharply and so did the reclamation activities. In Friesland, at a few locations near Sneek and Wartena, a very thin peat layer developed in the clay cover, the Layer of Tinga (Vos, Reference Vos2001a). The Layer of Tinga is associated with decreasing anthropogenic activity during the Migration Period. As a result, the man-made drainage deteriorated and peat growth recovered locally (Vos & de Langen, Reference Vos, de Langen and Huisman2008).

The occupancy of salt marshes at the seaward margin of the peat area in the northern Netherlands and northwestern Germany increased strongly again during the Early Middle Ages when the large-scale peat reclamations started, leading to full cultivation of the coastal peat bog and the adjacent peat-moor area on the Pleistocene soils. They caused a significant subsidence in the surface of the seaward margin of the peat area. Because of subsidence the seaward margin of the peat area was flooded during storms and as a result the clay cover expanded strongly in all coastal regions of the northwestern Wadden. Concomitantly the tidal currents to the hinterland strengthened, which in turn led to an enlargement of the tidal channels. Consequently, the Middelzee increased further and the drainage of the Marne River was reactivated.

The Lauwerszee reached its maximum extent in the Early Middle Ages. It is likely that this ingression system had grown already in the Roman Period (Vos & de Langen, Reference Vos, de Langen and Nicolay2010). In contrast, the Peasens ingression system silted up even more. The drainage function of the Peasens system was taken over by the man-dug Dokkumer Grootdiep, which discharged into the Lauwerszee system. The subsidence resulting from peat reclamation enabled the tidal system of the Lauwerszee to enlarge. Near Stroobos, in the seaward margin of the system, the first marine influence has been dated around 700 AD (Vos & Groenendijk, Reference Vos and Groenendijk2005). Between 700 and 1000 AD the system expanded further and large parts of the coastal peat area in this region were covered with a grey clay layer. The Lauwerszee also took over the drainage of the Hunze River by means of a new channel between Zoutkamp and Ezinge, and the noticeable bend in the Hunze River, known as Reitdiep, originated. Previously the Hunze flowed to the Wadden Sea through the northern part of Hunsingo. Humans probably contributed to the coming into existence of the Reitdiep by digging a connecting canal between the Lauwerszee system and the Hunze River, a canal comparable with the Dokkumer Grootdiep. Because of the strong current, the Lauwerszee channel started meandering in this area. These meanders are much larger than those in the Dokkumer Grootdiep. The new course of the Hunze – through the Lauwerszee ingression system – caused the old mouth of the Hunze tidal basin to be silted up definitively to salt-marsh level.

In the Early Middle Ages (450–1000 AD), probably before 800 AD, also in the northwestern German coastal area a new ingression system, the Harlebucht, developed in the peat bog in which the Harle River discharged (Behre, Reference Behre1999). The loss of a protective coastal defence due to the migration of the islands of Spiekeroog and Wangerooge, and the emergence of a large tidal inlet are considered to be the main causes (Streif, Reference Streif1989b). This transgressive coastal development is very similar to that of the Paesens ingression system. In the formation of the Harlebucht system – just like in the Lauwerszee area – the anthropogenic lowering of the peat surface also played a role in the drowning process (Fig. 6; Fig. 13). South of the Harlebucht, the Crildumerbucht and Maadebucht ingression systems also increased in size due to flooding of the hinterlying coastal peat area. Anthropogenic subsidence effects in the Late Middle Ages are mentioned in the German literature and are particularly associated with salt-mining activities or ‘selnering’ (Bantelmann, Reference Bantelmann1967; Behre, Reference Behre2004).

Fig. 13. Schematic cross-section reconstructions through the coastal area of the northern Netherlands (north–south orientation) between 1000 BC and 2000 AD.

East of the Eems estuary no major marine ingressions occurred in the Early Medieval period. The protective coastal barrier consisting of salt-marsh deposits and the relatively minor human interventions are explanatory of this. The same reasons apply also to the Dollard and Jade areas, where no major marine ingressions occurred in this period.

Parts of the Dutch and German Wadden Sea area silted up during the Early Middle Ages. This was the result of sediment supply, which enabled the salt-marsh shorelines to expand (e.g. the Peasens system, the old Hunze tidal-basin system, Fivel Bay, the Sielmönkener Bucht and the salt-marsh shorelines near Butjadingen and near Land Wursten). In the northern part of Noord-Holland large-scale erosion occurred in the Early Middle Ages, as is evidenced by the formation of mudflat deposits in the former peat area. The protective coast was breached to a great extent and the remaining parts of the coastal barrier moved landward (Schoorl, Reference Schoorl1999). A big ingression in the Zijpe occurred in the Early Middle Ages.

1000–1500 AD (Fig. 11)

The Zuiderzee enlarged during the Middle Ages (Ente, Reference Ente1986; Ente et al., Reference Ente, Koning and Koopstra1986; Lenselink & Koopstra, Reference Lenselink, Koopstra, Rapporl and Soonius1994), erosion during major storms playing a major role. For example, during the great storm of 1170 AD a large piece of land, seaward of the current dike at Stavoren, was lost (Schoorl, Reference Schoorl1999) and the Marsdiep came into existence (Schoorl, Reference Schoorl1973). As the inland sea increased in size, wave attack on the shorelines became stronger because of the increasing fetch. The Marsdiep tidal inlet became increasingly important during the Middle Ages (Sha & de Boer, Reference Sha and de Boer1991). However, only in the 15th century was the watershed between North Sea and Wadden Sea (on the line Texel-Schagen) broken and a large channel offered a direct connection with the Zuiderzee (Schoorl, Reference Schoorl1999).

The effects of anthropogenic interventions in the coastal landscape became dramatic in the Late Middle Ages, when the major part of the northern Dutch and northwestern German salt-marsh area was embanked. In the course of the 11th century the construction of dikes had become necessary in areas with strong subsidence. In the previous periods the water flowed back to the sea in a natural way after a flood. However, after the artificial subsidence of the land, water remained present and could only be discharged to the sea during low water through a system of dikes and sluices. The Wolddijk around the strongly subsided peat land near Bedum is an example. The dike had already been constructed there for the reclamation of the seaward salt-marsh area. In the following centuries, the entire coastal area of northern Groningen was diked (Knol, Reference Knol, Borger, Breuker and de Jong2010, Reference Knol2013a). In this way almost the entire marsh area of the northwestern Wadden Sea area of the Netherlands and Germany was diked between 1200 and 1300.

As a result of this diking water could no longer be stored in the salt marshes during storms, leading to the impoundment of water against the dikes and an increase in maximum storm water levels in the Wadden Sea. The increase of storm-surge level and the lowering of the soil surface behind the dikes due to drainage created ideal conditions for major catastrophes. When dikes broke, water plunged into the low-lying polders with disastrous consequences for humans and animals.

Inundations were not only the result of extreme high sea-water levels. In areas where the ground level had dropped sharply, the water in these polders could not discharge easily anymore to the sea. Particularly during periods of heavy rainfall during winter, this resulted in stagnant ponds in the lowest areas. Where the surface level of the area dropped below the mean low water (MLW) level, the discharge during low water through a system of sluices did not work anymore and the low-lying polders could only be kept dry by artificial drainage techniques such as mills.

In diked (peat) areas where strong subsidence had taken place, permanent damage could occur in the form of permanent loss of land when it was hit by a flood disaster. Examples are the peat lands in the western and central part of the Jadebusen (Wartenberg & Freund, Reference Wartenberger and Freund2012; Wartenberg et al., Reference Wartenberger, Vött, Freund, Halder, Frechen, Willershäuser, Schnaidt, Fischer and Obrocki2013) and Dollard (Vos & Knol, Reference Vos, Knol and Essink2013). These areas have in common that in the subsurface Pleistocene valley systems are present and in these valleys a very thick package of peat had developed. This peat package in the Jadebucht and Dollard made these areas highly vulnerable to oxidation of the top layer and soil subsidence when they were artificially drained. Before the dikings and reclamations in the Late Middle Ages, the peat surface there was a few metres above sea level and was protected against coastal erosion by a salt-marsh zone, a natural barrier. After the embankments, the peat surface dropped significantly, even to below mean high water (MHW) level. If a dike broke, water flowed into the peat area during every tide and created large and deep channels that could not be closed by humans anymore (Figs 7 and 14). In contrast, in the lateral located embanked salt marsh areas – with a clay-sandy subsoil – the permanent loss of land after a dike breakthrough was very limited. The surface level of these marsh areas was still above the MHW level at that time because the subsidence, caused by artificial drainage, was relatively small. After the breakthrough, the dikes around these areas could easily be repaired because they fell dry again after the storm flood inundation.

Fig. 14. Schematic north–south cross-section reconstructions of the Dollard area between 1000 and 2000 AD.

The disastrous Marcellus flood in 1362 was responsible for the great drowning of the peat lands of the Jadebusen (Behre, Reference Behre1999), and the entire low-lying peat area was permanently lost. Also, open water connections arose between the Jade and Weser River through the Heete and the Lockfleth, which some 150 years later in the 16th century was diked again. These openings did not become large tidal channels because they occurred in the watershed area between the Jadebusen and the Weser estuary. The relatively low current velocities here resulted into a rapid silting-up of these openings.

In the profile reconstruction of Fig. 14 the drowning of the Dollard between 1000 and 2000 AD is shown. The Dollard was lost only in the 15th century (Knottnerus, Reference Knottnerus and Essink2013) when quarrels about maintenance led to a deterioration of the dikes and the 1412 Cecilia flood caused drowning of large parts of the eastern part of the Dollard. An ingression of the west side of the Eems meander in front of the city of Emden turned Nesserland into a peninsula. The western part of the Dollard area was at that time still protected by an emergency dike between Reide and Finsterwolde, but was lost in the great Cosmas and Damianus flood of 1509. This flood also breached the eastern levee of the Eems meander and Nesserland became an island, which, together with the Punt van Reide, forms the remainder of the tidal levees of the Eems (Knol, Reference Knol2008; Knol, Reference Knol2013a,Reference Knol and Essinkb). Because of erosion and drifting away of large lumps of peat after the inundations (floating peat islands), an inland sea arose with the deepest parts below 4–5 m –NAP. The origin of the Dollard and Jade was ascribed especially to the behaviour of the local elite who, in their feuds, mutually destroyed dikes and sluices (Acker Stratingh & Venema, Reference Acker Stratingh and Venema1855; Ramaer, Reference Ramear1909; Breuer, Reference Breuer1965).

The ingression of the Leybucht east of the Eems estuary between Greetsiel and Norden is comparable to that of the Jade and Dollard. A low-lying peat area was also flooded, to be diked again in the course of the subsequent centuries as it silted up for the major part. It is different, however, in that no deep inland sea developed. Probably the Leybucht developed in the 12/13th centuries and the floods of 1362 and 1374 further enlarged the ingression in the peat hinterland (Behre, Reference Behre1999). Also in case of the Leybucht, humans undoubtedly played a major role in the subsidence of the soil resulting from peat reclamations, a low surface level and lakes being the result (Schwarz, Reference Schwarz2004, Reference Schwarz and Schmid e.a.2005). Behre (Reference Behre1999, Reference Behre2004) assumes a link between the origin of the Leybucht and the erosion of the salt-marsh island of Bant in the Wadden Sea, northwest of Norden. This would have caused the loss of the natural coastal defence, making the hinterland vulnerable. However, the former marsh island was located at a certain distance north of the Leybucht system (Figs 10 and 11). More likely it was mainly the low surface of the peat that enabled the sea to penetrate far inland and led to the creation of the Leybucht and a large tidal channel. The development of the large channel of the Leybucht promoted erosion of the Bant. The wave attack on the island was enhanced due to a larger sea opening to the hinterland. In any event, the exposure of Bant to the sea in combination with anthropogenic peat extraction for salt production was harmful (Behre, Reference Behre1999). The last remnant of the Bant was lost permanently to the sea after 1780 (Behre, Reference Behre1999).

Its namesake, the island of Bant in northeast Frisia, was lost permanently after 1500. The cause of the disappearance was the lateral shift of the Lauwersgeul (Vos, Reference Vos1992). Until the 14th century the tidal channel of the Lauwers discharged east of Schiermonnikoog. In the course of the 14th century the channel broke through the mudflat between Schiermonnikoog and the mainland of northeast Friesland. A large new inlet evolved, comprising the Westgat and the Zoutkamperlaag. Thus wave attack from the sea on the northeastern coast of Friesland increased strongly. The dike northeast of Wierum had to be rebuilt more inland as the result of strong coastal erosion and the graveyard, located on the seaside of the old dike, disappeared.

1500–2000 AD (Fig. 12)

After 1500 AD the land loss was more than compensated for by the accretion of new land. The northern part of Noord-Holland silted up strongly and the silted-up salt marshes were diked in stages. The same holds true for the Middelzee, the Fivel system, the Leybucht and the Harlebucht.

After the great floods in the Jadebusen and Dollard rapid sedimentation took place in the newly formed inland seas. The landward areas of these inner seas quickly silted up to salt-marsh levels and were diked in stages. Over last 60 years deepening and dredging of the tidal channels have changed the hydrodynamic conditions in the Eems estuary. The Eems-Dollard mudflats and salt marshes have been silting up over the last few centuries, but since the 1980s – the large Eems fairway deepening – erosion and deposition alternate and no clear net sedimentation occurs anymore (Commissie voor de Milieueffectrapportage, 2014). This intervention in the tidal system has led, amongst other things, to an increase in estuarine turbidity levels, which strongly affect the ecosystem of the estuary (Bos et al., Reference Bos, Büttger, Esselink, Jager, de Jonge, Kruckenberg, van Maren and Schuchardt2012; de Jonge et al., Reference de Jonge, Schuttelaars, van Beusekom, Talke and de Swart2014).

From the 19th century onwards the intertidal coastal zone along the embanked mainland has also been reclaimed using wooden structures along the dike in which silt was trapped. When such reclamation areas had silted up to the level of the salt marsh they were diked.

In the 20th century the Zuiderzee and the Lauwerszee were cut off from the Wadden Sea by large dikes. Thus the Wadden Sea area has been reduced. In particular, the salt-marsh areas are only a fraction of what they once were. After 1500 AD the peat area also decreased considerably. The coastal peat and the peat areas on the higher Pleistocene grounds (Groenendijk, Reference Groenendijk1997; Spek, Reference Spek2004) have largely disappeared due to large-scale peat-cutting for fuel (turf) and salt, and by oxidation of peat due to exploitation.

Discussion of the Subatlantic genesis of the Wadden Sea area

Forcing factors and processes

The driving mechanisms of the coastal evolution of the northern Dutch and German landscapes since 500 BC have much in common (mechanisms visualised in Figs 4–7), but each ingression system had its own specific development (Fig. 3).

The ingressions in the coastal peat areas of Paesens and Harlebucht have the disappearance of a protective coastal barrier in common, and the sea penetrated far into the hinterlying peat area. However, the timing was different. The Paesens system evolved in the Early/Middle Iron Age and silted up in the course of the Middle Ages, whereas the Harlebucht was only formed in the Early Middle Ages and silted up (and was diked) in the Modern Age.

The evolution and geometry of the Dollard and the Jadebusen are also very similar and related to a thick peat layer developed in former Pleistocene valley systems. These diked peat areas were very vulnerable to subsidence due to reclamations. Because of their low elevation these areas were permanently lost after major flood disasters in the Late Middle Ages, the Jadebusen in 1362 AD and the Dollard in 1412 and 1509 AD.

The course of tidal channels was likely affected by humans digging ditches. The straight Middelzee channel north of Sneek was formed in Roman times, probably due to the digging of a ditch or canal between the ingression systems of the Marne and the Middelzee. A dug water connection probably also ensured that the Reitdiep near Zoutkamp, the connection between the Hunze and Lauwerszee, evolved in the Early Middle Ages, such that the Hunze Valley silted up completely in the subsequent period. There are also similarities between the losses of the islands named Bant in the Dutch and German Wadden Sea. Both islands were lost in the Late Middle Ages and Modern Age as a result of the channel diversion exposing the islands to strong wave attack.

Similarly to the genesis of the landscape, the occupation histories of the Dutch and German coastal areas also shows strong similarities. The colonisation of salt marshes – directly on the marsh soil (Flachsiedlungen) and/or dwelling mounds (wierden and terpen) – took place on a large scale from the Early Iron Age onwards. The creation of artificial dwelling mounds continued until the diking of the salt-marsh areas in the Late Middle Ages.

The prehistoric occupations of the seaward margins of the peat areas of the Netherlands and Germany also show similarities, for instance the former seaward margins of the peat between Leeuwarden and Sneek, and those seaward of the dike near Bensersiel. There the occupation began in the Middle/Late Iron Age in fens which were silted over by salt-marsh clays in the Late Iron Age/Roman Period, indicating a (relative) increase in the maximum storm surge level. However, the subsequent development of the landscape in these regions was different due to the location of the areas relative to the open sea. The seaward margins of the peat areas near Leeuwarden–Sneek had a sheltered position in the hinterland of the silting-up Boorne tidal basin, whereas the area at the seaward side of the dike near Bensersiel was exposed and was eroded by the sea after the Middle Ages.

Sea-level fluctuations and coastal development

The Subatlantic sea-level rise – about 15 to 5 cm per century (Kiden et al., Reference Kiden, Denys and Johnston2002, Reference Kiden, Makaske and van de Plassche2008) – played a role in the drowning of the coastal peat lands but was not the major driving mechanism determining the development of the ingression systems. Natural or anthropogenic subsidence of coastal peat bogs on a vertical scale of decimetres to metres was the main cause (Figs 4–7). This view is in contrast with earlier views (Ter Wee, Reference Ter Wee1976; de Groot et al., Reference de Groot, van Adrichem Boogaert, Fischer, Klijnstra, van Montfrans, Uil, ter Wee, van Weperen and Zanstra1987; Streif, Reference Streif1989b; Behre, Reference Behre1999). The evolution of the ingression systems (Duinkerke 0, 1, 2 and 3) was earlier explained by cyclical sea-level fluctuations. Periods of (alleged) rapid sea-level rise were linked to transgression phases and marine sedimentation, and periods of declining sea-level rise (or even falling sea level) to regression phases and peat formation (Roeleveld, Reference Roeleveld1974; Griede, Reference Griede1978; van de Plassche, Reference van de Plassche1985; Menke, Reference Menke, Müller-Wille e.a., Higelke, Hoffmann, Menke, Brande, Bokelmann, Saggau and Kühn1988; Behre, Reference Behre1999, Reference Bakker2001, Reference Bakker2003), a view now regarded as outdated (e.g. Vos & van Heeringen, Reference Vos and van Heeringen1997; Beets et al., Reference Beets, van der Spek and van der Valk1994; Beets & van der Spek, Reference Beets and van der Spek2000; Vos & van Kesteren, Reference Vos and van Kesteren2000; Bungenstock & Schäfer, Reference Bungenstock and Schäfer2009). The evolution of tidal systems after 500 BC shows that the coastal development within those systems was not cyclical and that each system has its own history. Prograding and retrograding (salt-marsh) coastlines may occur at the same time within one and the same system, determined by local factors (e.g. compare the Boorne tidal basin and the Middelzee). Also in the Eems tidal area opposite developments occurred from the Iron Age until into the Middle Ages at the two sides of the estuary. Southwestward migration of the Eems channel between Delfzijl and Reiderland caused erosion at the Dutch side and coastal expansion at the German side.

The Holocene sea-level curves for the Dutch coastal area show a smooth arc shape (e.g. Jelgersma, Reference Jelgersma1966; Kiden et al., Reference Kiden, Denys and Johnston2002, Reference Kiden, Makaske and van de Plassche2008) while the curves for the German coast – in particular those of the last half of the Holocene – show strong fluctuations (Behre, Reference Behre1986b, Reference Bakker2001, Reference Behre2003; Menke, Reference Menke, Müller-Wille e.a., Higelke, Hoffmann, Menke, Brande, Bokelmann, Saggau and Kühn1988). The recent sea-level curve (Behre, Reference Behre2003) has aroused much international criticism (Bungenstock & Weerts, Reference Bungenstock and Weerts2010; Baeteman et al., Reference Baeteman, Waller and Kiden2011), focusing on the unreliability of peat layers and archaeological materials as palaeo-sea-level indicators and the fact that sea-level index points were taken all over the southern North Sea. In the southern North Sea, the subsidence is not the same everywhere due to differences in glacio-isostasy so that each region has its own relative sea-level curve. The post-500 BC index points used by Behre consist largely of archaeological observations from settlements in salt marshes in the German coastal area. These archaeological index points provide information about the maximum or extreme palaeo-storm surge level in a region (EHW) – humans lived above this level – but are not good indicators of the palaeo-mean sea level (MSL) or palaeo-MHW level since there is no linear relation between the MSL along the coast and the EHW level on the salt marshes.

Conclusions

The main driving factors in the long-term coastal evolution of the northwestern Dutch–German Wadden Sea region were relative mean sea-level rise in the first part of the Holocene and subsidence of the coastal peat bogs in the Late Holocene when the peats were intensively drained by humans.

In the Early Holocene the fast relative sea-level rise induced drowning of the Pleistocene valley systems, which led to formation of tidal basins (Fig. 2). As a consequence of a decreasing rate of sea-level rise the tidal basins were filled with sediment and silted up for a large part in the Middle Holocene. In the marginal zone of the basins towards the higher Pleistocene sand area, large salt marshes and coastal peat bogs came into existence.

From the Subatlantic period marine ingressions into the coastal peat bogs occurred (Fig. 3).

Natural and/or anthropogenic drainage of the peatlands – and subsequent compaction and oxidation – was the main cause of this drowning. Natural causes were the development of new tidal channels, which could develop in the tidal hinterland when a protective sea wall was eroded (such as the Paesens system; Fig. 4) or when a main tidal channel, which drained the hinterland, found a watercourse (such as the Boorne/Middelzee system; Fig. 5).

From the Late Iron Age humans started to drain the marginal area of the coastal bogs by digging ditches on a large scale. The result of these reclamations was that the cultivated peat lands subsided significantly, these areas were drowned during storm tides and a clay layer was formed on top of the peat. This resulted in an auto-compaction process that enhanced the subsidence of the peat (e.g. the Middelzee/Marne system near Sneek; schematic profile reconstructions of Figs 6 and 13).

From the Late Medieval Period onwards, when the salt-marsh areas were embanked and the adjacent peatlands were exploited, the subsidence was dramatic. When the protecting dikes breached, this led to catastrophes and permanent losses of the low-lying peat lands (e.g. the Dollard area; schematic profile reconstructions of Figs 7 and 14).

The moderate sea-level rise of about 5–10 cm per century from the Iron Age onwards enhanced drowning of the coastal peat lands but was not the major driving force of the Subatlantic ingression systems because the Subatlantic subsidence of the drained and drowned peat bog areas had a vertical scale of decimetres to metres.

The landscape reconstruction of the Wadden Sea area between Marsdiep and the Weser (Fig. 3, Figs 8–12) shows that each ingression system has its own history, that humans played a significant role in the drowning process and that no natural cyclic trans- and regression mechanism can be held responsible for this.

Acknowledgement

The research for this study was carried out within the framework INTERREG IV A-programme Deutschland-Nederland and we thank the European Regional Development Fund, the Ministerie für Arbeit, Wirtschaft und Verkehr Niedersachsen and the provinces Groningen, Drenthe and Friesland for their financial support in the project. The Waddenacademie in Leeuwarden is thanked for its financial contribution to make this publication possible. We appreciate the advice and data source references of our German colleagues Friederike Bungenstock and Martina Karle of the Niedersächsisches Institut für historische Küstenforschung (NIhK) and Holger Freund of the Institut für Chemie und Biologie des Meeres (ICBM), which allowed us to compile the reconstructions of the area of Niedersachsen. We thank the members of the Terpen Project (a cooperation of Groningen University and the province of Friesland), Gilles de Langen, Johan Nicolay, Marco Bakker and Theun Varwijk, and Hennie Groenendijk (province of Groningen) for their cooperation in landscape reconstruction of the coastal area of the northern Netherlands. Sieb de Vries is thanked for drafting the map figures, Roel Savert for drawing the profiles (both Deltares) and Hans Smit for improving the English text in the first draft of the manuscript. We are grateful to the reviewers Poppe de Boer, Cecile Baeteman and Kees Kasse, and the associate editor Geert-Jan Vis, whose criticism and advice improved the manuscript significantly.

Supplementary material

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/njg.2015.4

Appendix

Maps used for this study

Pedological maps 1:50,000 of the northern Netherlands

  • STIBOKA, 1971–1991. Bodemkaarten van Nederland, Stichting voor Bodemkartering, Wageningen.

  • Bodemkaart van de Waddeneilanden Vlieland, Terschelling, Ameland en Schiermonnikoog (1986)

  • Bodemkaart van Nederland, Blad 3 West Uithuizen en Blad 3 Oost Uithuizen (1987)

  • Bodemkaart van Nederland, Blad 5 West Harlingen en 5 Oost Harlingen (1976)

  • Bodemkaart van Nederland, Blad6 West Leeuwarden, 6 Oost Leeuwarden en het vasteland van de kaartbladen 2 West en 2 Oost (1981)

  • Bodemkaart van Nederland, Blad 7 West Groningen (1973)

  • Bodemkaart van Nederland, Blad 7 Oost Groningen en Blad 8 Nieuwerschans (1986)

  • Bodemkaart van Nederland, Blad 10 West Sneek en 10 oost Sneek (1974)

  • Bodemkaart van Nederland, Blad 11 West Heerenveen (1976)

  • Bodemkaart van Nederland, Blad 11 Oost Heerenveen (1971)

  • Bodemkaart van Nederland, Blad 12 West Assen (1991)

Geological maps 1:50,000 of the northern Netherlands

German maps

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Figure 0

Fig. 1. Locations of the Wadden Sea study area between the Marsdiep and the River Weser.

Figure 1

Fig. 2. Location of the Early Holocene tidal basins in the northern Dutch and northwestern German coastal areas.

Figure 2

Fig. 3. Locations of the active tidal systems in the northern Dutch and northwestern German coastal areas during the Subatlanticum. Green: tidal channels belonging to the old tidal basins which at the time had not yet silted up completely and where the tidal channel was still active (date indicates the last time at which the tidal basin system was still functioning). Red: locations of the ingression channels (dates indicate the active period of the ingression system).

Figure 3

Fig. 4. Schematic reconstruction of a naturally drowning peat landscape, before 100 BC, induced by erosion of the protecting coastal barriers and salt-marshes by tidal inlet and channel migration. This led to the drowning and formation of channels and creeks in the peat landscape, which resulted in subsidence of the peat surface caused by auto-compaction and drainage of groundwater via the channel system. The reconstruction is inspired by the Peasens ingression system. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Figure 4

Fig. 5. Schematic reconstruction of a naturally drowning peat landscape, before 100 BC, caused by changing and migrating natural drainage systems in the hinterland. The driving processes of the subsidence of the peat surface were the enlargement of the new channel system, auto-compaction by deposition of a clay layer on top of the peat in that area, drainage of groundwater and oxidation due to natural drainage by the newly formed channels and creeks. The reconstruction is inspired by the Middelzee ingression system. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Figure 5

Fig. 6. Schematic reconstruction of an anthropogenically drowning peat landscape, after 100 BC, as a result of reclamation and cultivation of the marginal zone of the coastal peat bog. The driving processes of the subsidence of the peat surface were drainage of groundwater, inundation of the peat land and enlargement of the tidal channels, auto-compaction by deposition of a clay layer on top of the peat and oxidation due to artificial drainage. The reconstruction is inspired by the Lauwerszee and Harlebucht ingression systems. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Figure 6

Fig. 7. Schematic reconstruction of an anthropogenically forced drowning of the peat landscape, after 1200 AD, caused by diking of the salt-marsh area and peat landscape and by artificial drainage of the land via sluices. The driving processes of the subsidence of the peat surface were drainage of groundwater, oxidation due to artificial drainage, catastrophic inundation of the peat land and erosion of the peat surface, and disappearance of the peat out of the system by floating and drifting peat islands. The reconstruction is inspired by the Dollard and Jade ingression systems. For map legend see Figs 8–12; for cross-section legend see Fig. 13.

Figure 7

Fig. 8. Palaeogeographic map of the study area around 500 BC.

Figure 8

Fig. 9. Palaeogeographic map of the study area around 100 AD.

Figure 9

Fig. 10. Palaeogeographic map of the study area around 800 AD.

Figure 10

Fig. 11. Palaeogeographic map of the study area around 1500 AD.

Figure 11

Fig. 12. Palaeogeographic map of the study area at 2000 AD.

Figure 12

Fig. 13. Schematic cross-section reconstructions through the coastal area of the northern Netherlands (north–south orientation) between 1000 BC and 2000 AD.

Figure 13

Fig. 14. Schematic north–south cross-section reconstructions of the Dollard area between 1000 and 2000 AD.

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