Afsluitdijk | |
Image Alt: | Afsluitdijk |
Coordinates: | 53°N 15°W |
Country: | Netherlands |
Purpose: | flood protection and land reclamation |
Construction Began: | 1927 |
Opening: | 1932 |
Dam Length: | 32km (20miles) |
Dam Elevation Crest: | 7.25m (23.79feet) above sea level |
Dam Width Crest: | 90m (300feet) |
The Afsluitdijk (in Dutch; Flemish ˈɑfslœydɛik/; Western Frisian: Ofslútdyk; Low German; Low Saxon; German, Low; Saxon, Low: Ofsluutdiek; English: "Closure Dyke") is a major dam and causeway in the Netherlands. It was constructed between 1927 and 1932 and runs from Den Oever in North Holland province to the village of Zurich in Friesland province, over a length of 32km (20miles) and a width of 90m (300feet), at an initial height above Amsterdam Ordnance Datum of between 6.7m (22feet) along the section at Friesland, and 7.4m (24.3feet) where it crosses the deep channel of the Vlieter. The height at the greater sea depths west of Friesland was required to be a minimum of 7 metres everywhere when originally constructed.
Increases to the height of the Afsluitdijk have been made several times since 1958, when height increases were undertaken during regular maintenance periods as a result of the North Sea Flood of 1953, with the section between the Dutch; Flemish: Stevinsluizen and Dutch; Flemish: Lorentzsluizen sluice complexes seeing the crest level raised to 7.8 metres.[1] Major upgrade works commenced in 2019, with one of the design conditions being that only limited wave overtopping during the design storm condition be permitted. The design proposed by the successful contractor to meet this criterion will see a further increase in the height of the dam, by approximately 2 metres.[2]
The Afsluitdijk is a fundamental part of the larger Zuiderzee Works, damming off the Zuiderzee, a salt water inlet of the North Sea, and turning it into the fresh water lake of the IJsselmeer. It is a major landwinning project and a quicker road-connection between the North and West of the Netherlands.
The highway on the Afsluitdijk was the initial demonstration site for a 130km/h speed limit in the Netherlands.[3]
The Afsluitdijk (literally translated: shut-off-dyke) was completed in 1932, thereby shutting off the Zuiderzee (lit: Southern Sea) from the North Sea.[4] Until then, the Zuiderzee had been a large bay south of the North Sea which gave maritime access to five provinces of The Netherlands, and particularly during the Dutch Golden Age provided a protected entrance and exit for the harbour of Amsterdam and several other important Dutch sea harbours. Furthermore, the Zuiderzee provided relatively shallow and calm fishing grounds for the many towns bordering the bay. However, the opening of the North Sea Canal (Noordzeekanaal) in 1876 gave a much shorter direct entrance to the Amsterdam harbour, and overfishing had depleted the shallow bay. In the second half of the 19th century, the Dutch population was exploding, and there was an increasing need for land for agriculture and animal husbandry. The Dutch already had centuries of experience of building dykes around lakes, emptying them and converting them to fertile polderland.
The next large project was to convert the Zuiderzee into polder. In 1886, a few notables established the Zuiderzee Society to investigate whether reclamation was feasible. One of the most prominent members of the society was Cornelis Lely, a civil engineer, prominent member and later chairman of the society.[5] In 1891 he designed the first plan for the closure and reclamation of the Zuiderzee.
In 1913, Lely was Minister of Water Management, and land reclamation was included in the government program. His plan was initially opposed, particularly for its huge costs and also by the fishing industry. But after the flood of 1916 and the famine of 1918, opinions were ready for this mega project and the parliament agreed, but it took another 9 years, until 1927, before the works actually began.
Wieringen was connected to the mainland with the short Amsteldiepdijk in 1925; the Dutch; Flemish: Afsluitdijk would be 20mile in length. The inland side is heavy stone; the seaward side is boulder clay with brushwood mattresses above, weighed down by basalt boulders and old concrete.[6] Previous experience had showed that boulder clay was superior to just sand or clay for a structure like the Afsluitdijk, with the added benefit that till was in plentiful supply in the area; it could be retrieved in large quantities by simply dredging it from the bottom of the Zuiderzee. Work started at four points: on both sides of the mainland and on two specially made construction-islands (Kornwerderzand and Breezanddijk) along the line of the future dyke.
From these points, the dyke slowly grew by ships depositing till into the open sea until it breached the surface. The nascent dyke was then strengthened from land by basalt rocks and mats of willow switch at its base. The dyke could then be finished off by raising it further with sand and finally clay for the surface of the dyke, on which grass was planted.
As the dyke grew, physicist Hendrik Antoon Lorentz calculated the force of the tide as the smaller gap made it stronger. Ten thousand workers, 27 large dredges, 13 floating cranes, 132 barges, and 88 tugs worked on the project at the end, timed to close the dyke at low tide; it was finished on 28 May 1932. Construction progressed better than expected; at three points along the line of the dyke there were deeper underwater trenches where the tidal current was much stronger than elsewhere. These had been considered to be major obstacles to completing the dyke, but all of them proved to be relatively straightforward. Two years earlier than initially thought, the Zuiderzee ceased to be, as the last tidal trench, the Vlieter, was closed by a final bucket of till. The IJsselmeer was born, even though it was still salty at the time.
The dyke itself however was not finished as it still needed to be brought up to its required height and a road linking Friesland and North Holland (the current A7/E22 motorway) also remained to be built. On 25 September 1933, the Afsluitdijk was officially opened, with a monument designed by architect Willem Marinus Dudok marking the spot where the dyke had been closed. The amount of material used is estimated at 23e6m3 of sand and 13.5e6m3 of till and over the years an average of around four to five thousand workers were involved with the construction every day, relieving some of the unemployment following the Great Depression.
Besides the dyke itself, there was also the necessary construction of two complexes of shipping locks and discharge sluices at both ends of the dyke. The complex at Den Oever includes the Stevin lock (named after the son of mathematician and engineer Simon Stevin, Hendrik Stevin, who was the first making a plan to close the Zuiderzee in 1667[7]) and three series of five sluices for discharging the IJsselmeer into the Wadden Sea; the other complex at Kornwerderzand is composed of the Lorentz locks (named after the physicist) and two series of five sluices, making a total of 25 discharge sluices. It is necessary to routinely discharge water from the lake since it is continually fed by rivers and streams (most notably the IJssel river that gives its name to the lake) and polders draining their water into the IJsselmeer.
The height of the crest of the Afsluitdijk was originally determined based on insufficient data about wave run-up. This became apparent soon after the first significant storm surge following the completion of the works, which occurred in December 1936. During the storm, the water in the Wadden Sea reached to around half a metre below the dike. For the crown height, storm surge heights indicated by the Dutch; Flemish: Staatscommissie Lorentz (SCL) (English: Lorentz State Commission) were primarily used, based on storm surges that had occurred in the period 1825–1926.
According to committee's predictions, if the Zuiderzee had been closed during the 1825–1926 period, the highest water level reached would have been 3.1 metres above Amsterdam Ordnance Datum at Den Oever, and about 3.4 metres on the Friesland coast. However, the commission drew attention to the fact that in a very rare and unfavourable set of circumstances, even higher storm surge heights were possible.[8]
Water level reached during storm in 1894 | ||
Δ | Calculated level increase with new dike | |
A | Calculated level with closed-off Zuiderzee | |
ΔG | Predicted increase in wave run-up. |
Location of the area or tide gauge | Z | Δ | A | ΔG | |
---|---|---|---|---|---|
Kaaphoofd | 250 | 43 | 293 | 0 | |
Den Helder, gauge | 248 | 44 | 292 | 0 | |
Oostoever | 260 | 48 | 308 | 15 | |
Westerland (Wieringen) | 247 | 79 | 326 | 15 | |
Den Oever | 233 | 113 | 346 | 25 | |
Kornwerderzand | 270 | 100 | 370 | (15) | |
Harlingen | 269 | 77 | 346 | 15 | |
Nieuw Bildt | 271 | 13 | 284 | 5 | |
Ameland, Waddenkust | 330 | 8 | 335 | 0 | |
Terschelling, Waddenkust east | 340 | 0 | 325 | 0 | |
Terschelling, harbour | 286 | 14 | 300 | 0 | |
Vlieland, harbour | 287 | 16 | 303 | 0 | |
Vlieland Waddenkust, Posthuis | 260 | 32 | 292 | 10 | |
Eierland near Cocksdorp | 280 | 30 | 310 | 0 | |
Texel, Oostkaap | 245 | 79 | 324 | 10 | |
Texel, Oudeschild | 254 | 65 | 319 | 10 | |
Texel, South Point | 240 | 50 | 290 | 0 |
The lower value was based on the assumption that wave run-up in the shallow area near the Frisian coast would be reduced. However, it became evident as early as 1934 that this assumption was incorrect due to the narrowness of the shallow zone. To address this issue, a section of the dike body was removed. Despite these adjustments, a 1937 storm revealed that they were insufficient, leading to an increase in the crest height to 7.4 metres.
Later research on storm surge flood levels in the Netherlands by Pieter Jacobus Wemelsfelder and Johan van Veen, along with the devastating effects of the storm surge of 1953, would bring the reality of such extremely rare cases to light.[9] [10] [11]
In determining the height for the construction of the inner berm, different considerations were employed compared to those for the main dam crest height. The primary requirement for the crest was to ensure the dike would not be breached during the most severe anticipated storm. To achieve this, the crest was designed to be elevated enough so that, at most, only a single wave could reach it. The IJsselmeer side of the dam was designed with a lower factor of safety than the Wadden Sea side, as it was anticipated that even under unfavourable conditions, such as a southwest storm over the IJsselmeer with a high average water level, the waves would not exceed about 3.5 metres above Amsterdam Ordnance Datum. Consequently, the berm was constructed to a height of approximately 4 metres.
The inner berm slope toward the future water level of the IJsselmeer (or Amstelmeer) was designed to be steeper than the outer slope, with a ratio of approximately 1:3. The majority of the dam's core consisted of sand, while boulder clay on the exterior provided resistance against water flow, limiting seepage and enhancing dike breach protection. A layer of armourstone, composed of basalt rock, was utilized on the outer slope.
During construction, the slopes were partially fortified with basalt columns and Belgian block stone Dutch; Flemish: Belgische Bloksteen, a block-shaped, hard variety of limestone. Block stone served as a more affordable and widely available alternative to basalt, and the Dutch Government resisted purchasing large quantities of basalt to avoid potential price increases, instead planning to gradually replace the block stone with basalt.
Following the 1953 storm, a subsequent storm in 1954 caused significant damage to the Afsluitdijk. Although the 1953 water level was not as extreme at the Afsluitdijk as in the southern Netherlands, the intense wave action resulted in severe damage to a large portion of the block stone, which was later replaced by basalt. In response to recommendations from the Dutch; Flemish: Deltacommissie, the commission responsible for the Delta Works, it was deemed necessary to elevate the dike level. However, this was considered less urgent compared to the issues in Zeeland after the 1953 storm. A decision was made to prioritize the Delta Works while also incrementally increasing the Afsluitdijk height to 7.4 metres.
On 23 September 1954, on the centenary of Cornelis Lely, a statue, made by Mari Andriessen, was unveiled by Queen Juliana on the North Holland side of the Afsluitdijk. On May 9, 2007, the statue was relocated near to the Vlieter Monument. The official unveiling, on the occasion of the 75th anniversary of the dyke, was performed on 24 May 2007 by Prince Willem-Alexander.
In 2012, the State Secretary for Infrastructure and the Environment, Joop Atsma, issued a statement detailing the factors influencing the decision to replace the locks at Kornwerderzand. A naviduct would have a high construction cost compared with standard locks and bridges, but would benefit the economy by reducing delays. After the cost–benefit analysis of all potential solutions was considered, a decision was made to strengthen the existing locks. However, it is quite possible that a naviduct will be built to replace the locks when they reach the end of their useful life in 2050.[12] The work started in April 2020 and was planned to take three years; during the work, the highway remained in operation, however the bicycle path was closed.[13] In 2022 the improvement of the main dike body was completed. Additional works (the fish migration river,[14] new locks and the pumping station) were at that moment not yet ready.
Provision for a railway line linking North Holland and Friesland (between Anna Paulowna and Harlingen) had been included on the Afsluitdijk, in the form of a linear reservation, along with extra drawbridge abutments at the locks. However, construction of the line was never undertaken by the Dutch track operator (ProRail), for reasons of cost and relative lack of benefits. The reservation and abutments for the rail line were utilized instead for a second carriageway for the dyke's two-lane highway in the 1970s, transforming the latter into today's four-lane A7 motorway.
On 12 and 13 May 1940 it was the site of the Battle of the Afsluitdijk, where Fort Kornwerderzand became the only Dutch line of defense that successfully withstood a Wehrmacht attack during the conflict, and was one of the few Blitzkrieg defeats suffered by the Wehrmacht.
Rijkswaterstaat will strengthen the Afsluitdijk in the coming years to safeguard its future and to continue to protect the Netherlands against the force of water. Its renovation began in 2018. The government has taken this opportunity to give room to more initiatives. As part of the renovation programme, Daan Roosegaarde's Icoon Afsluitdijk enhances the iconic status of the Afsluitdijk with a second layer of light and interaction. The three designs of light and interaction developed by Roosegaarde and his team are entitled Gates of Light, Windvogel and Glowing Nature. Development Partners for this project are: Kitepower, Wageningen University and Research, TTB, Eurocarbon, Versalume.[15] [16]
Gates of Light is a futuristic entrance at both sides of the dyke. Inspired by retroreflective wings of butterflies, Daan Roosegaarde brings a new light on the 60 monumental floodgates which were designed by Dirk Roosenburg in 1932, the grandfather of the Dutch architect Rem Koolhaas. They have been restored with a retroreflective layer which is illuminated by the passing cars' headlamps.
Windvogel is a tribute to the Dutch astronaut Wubbo Ockels. Ockels had the dream to realise smart kites which generate power by having them stay aloft for long periods of time. He was one of the pioneers in the field of kite power generation and professor of the research group at Delft University of Technology from which the startup Kitepower arose. Each of the Windvogel kites generates from 20 to 100 kW which can supply energy for up to 200 households.
Glowing Nature shows the beauty of nature on the Afsluitdijk by means of an encounter between man, biology and technology. The exhibition, located in one of the historical bunkers, provides an interactive experience with live algae, one of the oldest microorganisms in the world. Only when you perfectly maintain and take care of these algae do they give natural light for an extended period of time.