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Zuiderzee Works

The Zuiderzee Works (: Zuiderzeewerken) is a comprehensive project in the designed to enclose and partially reclaim the , a shallow that posed recurrent flood risks to adjacent provinces. Enacted through the Zuiderzee Act of 1918, the initiative transformed the saline Zuiderzee into the freshwater , yielding approximately 1,650 square kilometers of reclaimed land suitable for agriculture while establishing a vital for and . The project's core achievement, the 32-kilometer constructed between 1927 and 1932, sealed the sea from the , preventing tidal surges and enabling systematic drainage of enclosed basins. Subsequent phases focused on polder creation, beginning with the drained in 1930, followed by the in 1942, and the expansive complex—East Flevoland in 1957 and South Flevoland in 1967—through dike construction, pumping, and soil improvement. These efforts not only expanded by nearly 20% in key regions but also mitigated flood vulnerabilities that had historically devastated areas like the 1916 flood displacing thousands. Engineering innovations included mat-breaking techniques to consolidate soft seabed soils and extensive systems for controlled freshwater inflow from the IJssel River, balancing salinity reduction with ecological stability. The Zuiderzee Works exemplifies Dutch mastery of water control, influencing global practices, though partial abandonment of further reclamations in the 1970s preserved residual lakes like the for amid shifting environmental priorities. Recognized as a landmark of , the project enhanced and population capacity in a delta nation, with the enduring as a multifunctional barrier supporting roadways and defenses.

Historical Context

Geological and Early Human Interactions

The Zuiderzee region, encompassing much of the central , developed during the epoch amid post-glacial sea-level rise and sediment deposition from rivers like the and IJssel, resulting in extensive bogs, marshes, and shallow lagoons such as the prehistoric . These low-lying landscapes, part of a subsiding basin known as the Zuiderzee Low, experienced ongoing compaction of organic layers, which lowered the land surface relative to sea level and heightened vulnerability to tidal incursions. Coastal dunes initially acted as barriers, confining inland waters, but the area's geological instability—characterized by soft silts and clays—facilitated episodic flooding. The modern inlet formed abruptly on December 14, 1287, during , a catastrophic storm tide originating in the that overwhelmed the dune barrier between and the mainland, inundating approximately 1,250 to 1,650 square kilometers of and farmland. This event transformed the former lagoon into a brackish tidal sea extending over 120 kilometers inland, with surges reaching several meters above normal levels and causing an estimated 50,000 to 100,000 deaths across the . Subsequent storms enlarged the inlet, but the 1287 breach marked the primary geological reconfiguration, shifting the region from protected freshwater systems to a dynamic environment prone to and . Human occupation in the Zuiderzee area dates to prehistoric times, with evidence of hunter-gatherers exploiting coastal resources before farming communities established settlements on natural levees and early artificial mounds around 3000 BCE. By the Early , circa 500 BCE, coastal dwellers, particularly in the northern and eastern fringes, constructed terpen—man-made earthen mounds layered with clay, dung, and refuse—to elevate homes and livestock above recurrent floods in tidal salt marshes. These terpen, numbering over 1,200 in the broader coastal zone including former Zuiderzee islands like and , grew organically through centuries of habitation, reaching heights of up to 15 meters and supporting agrarian lifestyles centered on cattle herding, fishing, and salt production. Sites such as preserve layered archaeological remains from multiple prehistoric phases, illustrating adaptive strategies to the volatile environment long before medieval inundations amplified risks.

19th-Century Proposals and Flood Risks

In the early , the remained a persistent source of risk for surrounding low-lying provinces, with surges frequently breaching dikes and inundating agricultural lands and settlements. The most severe event occurred during the , triggered by a northwest coinciding with spring tides, which caused over 65 dike breaches along the coast and Zuiderzee shores. This disaster, the largest of the century in the , flooded approximately two-thirds of Friesland's territory, drowned around 800 people nationwide (with hundreds more in the Zuiderzee vicinity, including 379 in alone), and inflicted widespread damage to infrastructure and farmland. Recurring inundations, such as those in subsequent decades, underscored the vulnerability of the region's fragmented dike system to influences and westerly gales, prompting calls for systemic beyond repairs. These flood hazards, coupled with the successful enclosure and drainage of inland lakes like the (completed in 1852), inspired initial proposals to and reclaim the Zuiderzee itself. In 1849, Dutch engineer Bernhard Pieter Gesinus van Diggelen presented a detailed plan envisioning a across the sea's northern entrance, followed by systematic pumping to create arable polders, aiming to add vast tracts of farmland while mitigating tidal risks. Additional schemes emerged, including a 1866 proposal to redirect the IJssel River while partially enclosing the basin, and Gerrit Leemans' 1877 design for phased and . Proponents argued that reclamation would not only generate economic value through but also enhance flood security by converting the open into a controlled freshwater lake, though critics highlighted uncertainties in stability, feasibility, and costs exceeding initial estimates. Despite technical innovations like steam-powered pumps demonstrated in prior projects, these 19th-century initiatives stalled due to political divisions, fiscal constraints, and debates over ecological impacts on fisheries versus land gains. The proposals nonetheless established foundational engineering concepts, such as alignment options for the closure dam, that influenced later 20th-century implementations. Flood events continued to erode confidence in partial measures, setting the stage for renewed advocacy after persistent vulnerabilities were exposed into the early 1900s.

The 1916 Storm Flood as Turning Point

The Zuiderzee flood of 1916, known as the Zuiderzeevloed, struck during the night of 13–14 January amid a severe that generated high winds and elevated sea levels, causing dikes to breach at multiple locations encircling the inlet. Breaches occurred in at least dozens of places, inundating low-lying polders and coastal areas in provinces including and with saltwater, which rendered farmland unproductive for years due to salinization. The flooding displaced communities, destroyed homes, and led to the loss of substantial livestock, with reports indicating that cattle herds in affected regions like were halved, exacerbating economic hardship for farmers reliant on dairy production. Human casualties totaled 51, including 19 deaths in and 32 from shipwrecks at sea during the storm, underscoring the vulnerability of both land-based and maritime activities around the . Rescue efforts were hampered by the storm's ferocity and the extent of inundation, covering thousands of hectares, though timely evacuations in some areas mitigated higher losses among residents and approximately 3,000 cattle in specific polders. Queen Wilhelmina personally inspected the disaster zones, highlighting its national significance amid , when the ' neutral status still exposed it to supply disruptions and food shortages. This event marked a pivotal shift in attitudes toward Zuiderzee management, as the repeated demonstrations of risk—compounded by wartime vulnerabilities in and fisheries—elevated Cornelis Lely's long-advocated closure plan from theoretical proposal to urgent necessity. Prior debates had stalled over costs and ecological concerns, but the 's tangible devastation, including salted soils and decimation, generated widespread public and political for damming the inlet to create freshwater lakes and reclaim land for farming, directly catalyzing the Zuiderzeewet of that authorized the works. The disaster empirically validated causal arguments for , proving that the open Zuiderzee's dynamics amplified storm surges and , thereby overriding opposition from interests who feared loss of livelihoods.

Planning and Political Development

Cornelis Lely's Vision and Iterations

Cornelis Lely, a born in 1854, developed the foundational plan for the Zuiderzee Works as technical advisor to the Zuiderzeevereniging starting in 1886. His 1891 proposal envisioned constructing a 32-kilometer dike, the , connecting Den Oever in to Zurich in to enclose the inlet, transforming it into a freshwater lake for controlled and . This would enable the creation of multiple polders—initially including in the northwest and larger southern expanses—yielding approximately 2,000 square kilometers of from the shallow sea, leveraging steam-powered pumps for and drawing on surveys confirming clay-rich bottoms suitable for . The scheme aimed to mitigate chronic flooding, enhance through expanded farmland, and reduce maintenance costs for the fragmented dike system encircling the , building on precedents like the 19th-century but scaled to address the inlet's 5,000 square kilometers. Lely refined his calculations through desk-based modeling and 1891 expeditions across the to evaluate sediment composition and tidal dynamics, confirming the feasibility of full enclosure over partial measures. As Minister of and Water Management from , he advocated for implementation amid growing flood risks, culminating in a 1916 redesign finalized after that year's storm surge inundated regions like , killing dozens and destroying homes, which underscored the urgency beyond economic debates. The core elements—dike with integrated sluices for IJssel River outflow and salinity control, followed by phased polder encirclement and drainage—remained consistent, prioritizing hydraulic stability with a lake level managed at 40 centimeters below to prevent seepage. Political resistance, particularly over costs estimated at 400 million guilders and impacts on fishing, prompted iterations; Lely scaled back legislative proposals to prioritize the and initial like when facing fiscal opposition, deferring fuller southern reclamations. The Zuiderzeewet, enacted June 14, 1918, enshrined this phased approach, authorizing the dike's construction first while mandating studies on water levels and ecology, reflecting compromises that delayed but preserved the vision's scope. Subsequent wartime shortages and postwar priorities further adapted execution, yet Lely's framework guided the project's core until his death in 1929, with reclamations totaling 1,650 square kilometers by the 1960s, short of the original ambition due to abandoned elements like the .

Economic Justifications and Cost-Benefit Analyses

The economic justifications for the Zuiderzee Works centered on addressing chronic flood risks, accommodating through for agriculture, and enhancing national , particularly in the aftermath of shortages. Proponents, including Cornelis Lely, argued that reclaiming approximately 200,000 hectares of fertile land would generate an annual economic surplus of 0.5 million guilders from farming, while reducing maintenance costs for existing polder dikes and improving . These benefits were framed as long-term investments to support a growing , with the 1898 report by the Zuiderzee Society emphasizing job creation and self-sufficiency over immediate fiscal returns. Cost-benefit analyses conducted prior to approval quantified the enclosure and partial reclamation as financially viable. The 1901 draft act, based on Lely's plan, estimated total costs at 43-44 million euros (equivalent to 5-6.3% of GDP at the time), comprising 27 million euros for enclosure works—including 14 million euros for the —and 17 million euros for initial , plus 2.1 million euros in compensation for affected fishermen. Benefits included 10 million euros in immediate drainage cost savings and 30 million euros in avoided future reclamation expenses, alongside unquantified gains in flood safety, freshwater storage, and shipping efficiency, leading to the conclusion that net returns justified the project despite upfront budgetary strain equivalent to 66% of the central government's annual budget. Subsequent evaluations reinforced these assessments, with the 1916 flood providing empirical validation by demonstrating damages that exceeded the projected costs of the alone. Later analyses, such as those post-1953 floods, indicated that the enclosure's flood protection benefits had recouped construction expenses through averted losses, though fisheries declined without full offset in the original models. Modern retrospectives, including 2011-2014 cost-benefit studies on renovations, affirm the original framework's soundness, estimating that adaptive measures like pumps yield billions in savings over dike-raising alternatives while enhancing freshwater reserves threefold for minimal additional investment.

Stakeholder Conflicts in Early Debates

Early debates surrounding Cornelis Lely's 1891 proposal for enclosing the centered on tensions between national flood protection and ambitions versus localized economic dependencies, particularly the industry's reliance on the inlet's rich fisheries. Fishermen, numbering in the thousands and centered in ports like and , vehemently opposed the plan, arguing it would eradicate their primary fishing grounds for and other species, thereby threatening livelihoods sustained by seasonal Zuiderzee harvests. This resistance was compounded by longstanding divisions among fishermen themselves, with eastern groups protesting western use of fyke-trawlers that depleted stocks, a dating back centuries and complicating unified opposition. The 1894 Staatscommissie, tasked with evaluating closure effects, acknowledged these impacts and recommended compensatory measures, including pensions and relocation aid, to mitigate the foreseen dissolution of the Zuiderzee fisheries sector. Provincial stakeholders exhibited divergent interests, with North Holland and Friesland provinces advocating strongly for the project to enhance agricultural expansion and safeguard coastal populations from recurrent floods, viewing the enclosure as a means to reclaim arable land and improve infrastructure connectivity. In contrast, Groningen province raised alarms over potential alterations to Wadden Sea currents and sedimentation patterns, which could exacerbate flood risks in northern coastal areas, as articulated by figures like Lambertus Helbrig Mansholt during pre-1918 deliberations. Rijkswaterstaat engineers further fueled technical debates by questioning the feasibility of Lely's dike design across the unpredictable Zuiderzee mouth, citing risks of scour and structural failure based on hydraulic modeling of the era. Economic analyses amplified these rifts; while proponents like the Zuiderzee Society—founded in 1886 by Age Buma and P.J.G. van Diggelen—projected long-term benefits exceeding costs through polder productivity, opponents highlighted immediate fiscal burdens estimated at 192 million guilders, alongside underestimations of fishery compensation needs. B. Demmer's 1901 General Committee report, for instance, pegged required fisherman payouts at 14 million guilders, far surpassing Lely's proposed 4.5 million, underscoring undervaluation of displaced communities. These conflicts manifested in parliamentary scrutiny, where progressive-liberal elites prioritized a nationalist "struggle against water" narrative, framing the works as essential for and amid early 20th-century pressures. The 1905 Neeb-Committee advised against full compensation, instead promoting occupational transitions for fishermen into or , a stance criticized for ignoring entrenched cultural ties to maritime traditions. Lely himself, in 1918 debates preceding the Zuiderzee Act's passage, defended the enclosure by invoking the over parochial provincial claims, though vagueness on exact compensation fueled ongoing protests that persisted into the . Despite these frictions, the 1916 storm flood tilted momentum toward proponents, yet early debates revealed a pattern of sidelining and regional voices in favor of centralized imperatives, setting precedents for parliamentary adjustments rather than comprehensive stakeholder reconciliation.

Engineering and Construction

Design of the Afsluitdijk

The Afsluitdijk's design, rooted in Cornelis Lely's 1892 proposal to enclose the inlet, prioritized a straight, efficient barrier spanning natural shallows between Den Oever in and Zurich in to minimize material demands and leverage stable sandbank foundations for settlement control. This 32-kilometer alignment reduced exposure to deep channels, enabling phased construction via temporary dams and caissons while directing tidal currents to aid silt deposition for base stabilization. The overall structure emphasized earthen dike principles refined from centuries of flood defense, with a broad crest width of 90 meters to integrate a roadway for access and future traffic, balancing load distribution against potential under self-weight exceeding 10 million tons. Core impermeability relied on a compacted boulder clay and earth fill, forming a trapezoidal cross-section that tapered from base widths up to 200 meters to resist hydrostatic pressure and shear from wave forces up to 5 meters high during storms. Seaward slopes, facing North Sea gales, incorporated brushwood mattresses—woven willow bundles—sunk as flexible filters to consolidate subsoil, topped with graded stone layers and basalt boulders (sourced from the Rhineland) weighing 1-3 tons each to dissipate energy and curb erosion, a technique proven in prior polder works. Inland revetments used heavier quarried stone for rigidity against the emerging freshwater basin's level fluctuations. Initial crest elevation reached 7.25 meters above Normaal Amsterdams Peil (NAP), calibrated via hydraulic models to overtop rarely under design floods equivalent to the 1916 Zuiderzee disaster. Hydraulic integration featured discharge sluice complexes at endpoints: Den Oever's multi-gate array handled IJssel River inflows, while Kornwerderzand managed residual sea connections, totaling approximately 25 operable floodgates with vertical sliding mechanisms for selective flushing to expel salt and control lake salinities below 0.5 parts per thousand within years. These reinforced concrete structures, capped at 8-10 meters high, included navigational locks for vessels and were positioned to exploit tidal differentials for passive drainage, obviating early pumps and ensuring causal separation of marine and lacustrine regimes. Monumental towers by architect Dirk Roosenburg enhanced visibility for operational cues, underscoring the design's fusion of utility and durability against long-term subsidence rates of 1-2 cm annually.

Construction Timeline and Techniques (1920s-1930s)

Preparatory works for the commenced in 1920, focusing on initial site assessments and material sourcing, but were temporarily halted due to economic downturns before resuming at full capacity in 1925. The primary spanned from 1927 to 1932, during which workers built the 32-kilometer dam connecting Den Oever in to Zurich in , employing manual labor alongside early mechanized and transport to layer sand, clay, and stabilizing till. This earthen structure incorporated reinforcements for added durability against forces. Concurrently, reclamation efforts advanced with the , where dike construction linking Wieringen to the mainland started in 1927, achieving enclosure by 1929 through sequential embankment building that withstood sea pressures. followed in 1930 via large-scale pumping stations that expelled approximately 100 billion liters of seawater, transforming the 20,000-hectare basin into dry land suitable for . These techniques relied on ring dikes and centrifugal pumps, marking an evolution from windmills to electric-powered systems for efficient . The Afsluitdijk's completion on August 28, 1932, sealed the , initiating its freshwater transition, while Wieringermeer's success validated scaled-up methods for subsequent works. Labor-intensive processes, including mats and piled foundations, ensured structural integrity amid challenging marine conditions.

Initial Drainage and Flood Control Measures

Following the partial enclosure of the in December 1929, initial efforts relied on large-scale pumping stations to remove seawater and lower the water table for . Two primary stations were constructed: the diesel-powered Leemans station and a steam-powered facility, both operational by February 1930, enabling continuous pumping that achieved full within six to nine months, reducing the polder's water level approximately 5 meters below the Dutch (). This process involved expelling over 200 million cubic meters of water into the adjacent , testing the feasibility of mechanized on a 20,000-hectare scale prior to the Afsluitdijk's completion. Flood control during this phase centered on the integrity of the enclosing ring dike, which spanned 28 kilometers and connected to the nascent works, preventing ingress from storm surges while pumps operated. Reinforcement of the dike with clay cores and monitoring for seepage ensured stability against tidal influences, as the lay exposed to the Zuiderzee's fluctuating levels until the full barrier's closure. These measures mitigated risks from residual marine pressures, drawing on lessons from the 1927 Andijk pilot , a 40-hectare trial site drained via smaller steam pumps to validate and pumping efficacy. Upon the Afsluitdijk's completion on August 28, 1932, flood control extended to the nascent through integrated discharge s at Den Oever and Kornwederzand, designed to release excess freshwater inflows from rivers like the IJssel during high-water periods into the . These 17 complexes, each comprising multiple gates, allowed gravity-based outflow when levels were lower, maintaining elevations between -0.40 and -0.20 meters NAP to avert shoreline inundation. Initial operations post-closure prioritized controlled freshening, with river discharges gradually diluting salinity from 30 ppt to under 1 ppt within three years, while management prevented overflow from precipitation or melt events. Subsequent drainage in the basin incorporated these sluices alongside polder-specific pumps, ensuring that early reclamations like remained protected from backflow as the lake stabilized. This combination of mechanical dewatering and hydraulic regulation formed the foundational strategy, enabling safe agricultural preparation of peaty soils by 1931 without major inundation incidents.

Reclaimed Polders

Wieringermeer: First Major Reclamation

The polder, encompassing approximately 200 square kilometers of seabed, represented the initial large-scale reclamation effort within the Zuiderzee Works, demonstrating the feasibility of converting saline waters into prior to the Afsluitdijk's completion. Construction of the enclosing dike commenced in 1927, linking the island of Wieringen to the mainland and isolating the designated area from the inlet. The dike, engineered with a clay core for imperviousness and reinforced slopes to withstand wave action, spanned key segments including connections from Wieringen's northern tip. By December 1929, the enclosure was fully sealed, allowing drainage operations to proceed using two primary pumping stations equipped with diesel-powered centrifugal pumps capable of handling heads up to 6 meters. The Leemans station, named after hydraulic engineer Wilhelmus François Leemans and constructed in the late , served as a cornerstone of the effort, discharging into adjacent canals for expulsion back to the . Full was achieved by September 1930, transforming the former marine basin into dry land through systematic that removed billions of cubic meters of water over months of continuous operation. Post-drainage, the polder's clay-rich soils required initial consolidation and salinization mitigation before agricultural use, with early settlement focused on and suited to the fertile sediments. This reclamation, independent of the main , validated Lely's phased approach by yielding productive land ahead of broader hydrological changes, though it later faced inundation in 1945 during wartime retreat. The project's success underscored the efficacy of mechanized pumping over traditional windmills, enabling reclamation at depths averaging 5-7 meters below .

Noordoostpolder: Wartime and Postwar Efforts

The reclamation of the , the second-largest in the Zuiderzee Works at approximately 480 square kilometers, advanced significantly during despite the challenges of . Dike construction commenced in 1936 with the development of a working port at , followed by ring dike building from and starting in 1937, culminating in the closure of the on December 13, 1940. efforts began on January 7, 1941, via the Buma pumping station near , employing electric pumps to lower water levels through a network of canals, trenches, and pipes; the reached sufficient dryness at 4.40 meters below by September 9, 1942. Wartime disruptions included electricity shortages that elevated water levels and required temporary quays, as well as fuel scarcity necessitating manual ditch digging by large workforces, though authorities provided oxen and engines to sustain progress and incorporated local workers seeking to evade forced labor deportation to . Under occupation, the nascent polder served as a critical refuge for the Dutch resistance and civilians evading persecution, earning the nickname "Nederlands Onderduikers Paradijs" (Dutch Paradise for People in Hiding) due to its expansive, sparsely populated terrain offering concealment. By 1943–1944, an estimated 20,000 individuals were hidden there, supported by organized resistance networks led by figures such as Albert Knipmeijer, who issued protective documents, and Harmen Visser in Vollenhove; these efforts fostered heightened anti-German sentiment and included weapon drops and sabotage activities. German responses escalated in late 1944 with raids, including one on August 7 arresting 130 young men for frontline labor and a major operation on November 17 detaining around 1,800 workers, which hampered harvesting and workforce availability; the polder also witnessed approximately 29 aircraft crashes in 1944–1945. Liberation arrived in April 1945, with resistance forces handing over control on April 17 and Canadian advances marking the end of occupation, though incidents like Visser's killing on April 16 underscored the perils. Postwar efforts prioritized rapid settlement and agricultural transformation to cultivate the fertile clay soils into productive farmland, commissioning all three pumping stations—Buma, Vissering, and Smeenge—fully to maintain dryness. A rigorous selection process vetted applicants based on age, marital status, financial stability, education, agricultural proficiency, social engagement, and even household inspections including wives' linen closets, aiming to construct an efficient, self-sustaining community capable of maximizing land productivity. Exceptions were granted to displaced farmers from following the 1953 flood, bypassing standard criteria to expedite repopulation. This structured approach enabled the establishment of planned farmsteads, infrastructure, and villages like Emmeloord, transforming the into a model of agricultural innovation and economic recovery by the late and .

Flevolands: Eastern and Southern Divisions

The Eastern polder, the largest in the Zuiderzee Works at approximately 540 km², involved dike that began in the early and culminated in closure on September 13, 1956, with drainage commencing immediately via pumping stations. Full drainage was achieved by 1959, transforming the former basin into characterized by larger farm plots averaging 45 hectares to support mechanized . This polder's design incorporated peripheral lakes to manage levels and prevent impacts on adjacent areas. Adjacent to Eastern Flevoland, the Southern Flevoland polder, covering about 430 km², followed with dike works starting post-1957 and closure around 1963, followed by drainage completion in 1968. Engineering techniques mirrored those of prior polders, employing sand suppletion for dike foundations and extensive pumping infrastructure to remove over 10 billion cubic meters of water across the Flevolands combined. The division into eastern and southern sections preserved navigable waters like the Vossemeer (formed 1956) and Nijkerkernauw (1967), facilitating maritime access while enabling phased reclamation. Together, these polders formed the bulk of what became province in 1986, prioritizing and urban deconcentration from the , with initial settlements focused on efficient land allocation for housing and industry. post-drainage required years of ripening, during which clay-heavy sediments underwent consolidation to support , yielding crops suited to the freshwater environment. The reclamations added over 970 km² of land, bolstering national amid postwar recovery.

Markerwaard: Planned but Unrealized Scope

The Markerwaard polder was conceived as the final major reclamation in the Zuiderzee Works, targeting approximately 410 km² within the Markermeer basin to expand agricultural land, accommodate urban development for up to 250,000 residents, and bolster flood defenses by further enclosing the former Zuiderzee. Initial plans, outlined under the 1918 Zuiderzee Act, anticipated completion by the mid-20th century, with the polder envisioned to include arable fields, residential zones, and infrastructure such as potential airports or power stations, financed partly through land sales. By the 1970s, designs had evolved to incorporate bordering lakes for ecological buffering, reducing the core polder area from earlier proposals of around 500 km². Key preparatory infrastructure included the 26 km , constructed between 1957 and 1975 to link in to in the , effectively isolating the from the and setting the stage for drainage. Supporting elements encompassed the earlier Oostvaardersdijk (completed in the 1940s) and a dike connecting to (1958), which would have preserved the latter as a rather than an . Construction faced interruptions, including a halt in 1957 due to funding shortages and a 1973 pause prompted by environmental , reflecting emerging tensions over the project's viability. Opposition intensified in the , driven by environmental groups such as Natuurmonumenten and the Association for the Preservation of the IJssel Lake, which highlighted risks to habitats, wetlands, and , including potential sludge accumulation and algal blooms in residual lakes. Public consultations, including a 1980-1982 process garnering 20,000 responses and a with 15,500 signatures against reclamation, underscored societal resistance, contrasted by only 2,700 in favor. Political divisions emerged, with parties like D'66 opposing as early as 1971 and the Spatial Planning Council issuing a split recommendation in 1982 (13 for proceeding, others advocating postponement or rejection). Economic rationales, centered on alleviating Randstad overcrowding and sustaining agricultural output, waned amid declining land demand and rising costs, compounded by stricter environmental criteria in the 1980s. The project was indefinitely postponed in the 1980s before formal abandonment in November 1990 by Minister Maij-Weggen, citing insufficient societal support and failure to meet multifunctional objectives like balanced ecological and developmental benefits. This decision preserved the Markermeer as a freshwater , averting further hydrological alterations while redirecting efforts toward alternative uses, such as later restoration initiatives.

Environmental Transformations

Hydrological Shifts from Salt to Fresh Water

The enclosure of the by the , completed on 28 August 1932, eliminated tidal exchange with the , marking the onset of a profound hydrological transition from a brackish-water inlet to the freshwater basin. Prior to closure, the Zuiderzee functioned as a partially mixed with a pronounced gradient: surface salinities averaged around 30‰ near the northern inlets, declining to approximately 8‰ in the central areas owing to substantial freshwater discharges from rivers including the IJssel, a contributing low-salinity inflows of roughly 300 cubic meters per second on average. Post-closure, the shifted to a lake-dominated regime sustained by riverine freshwater inputs exceeding 9 km³ annually, primarily from the IJssel, which diluted the enclosed saline volume of approximately 17 km³ through advective flushing and minimal outflow via the Afsluitdijk's sluices during episodic high-water events. This natural dilution process, unassisted by mechanical pumping at the basin scale, followed an pattern, with the e-folding time constant for reduction estimated at 1.8 years based on the ratio of lake volume to net freshwater throughput. dropped rapidly from initial post-closure levels of 10-20‰ basin-wide average to near-freshwater conditions (<1‰) within five years, rendering the effectively oligohaline by 1937 and enabling subsequent drainages without prohibitive soil salinization risks. The regime change extinguished currents and associated mixing, previously driving semi-diurnal oscillations with ranges of 20-50 cm in the inner , supplanting them with wind-forced circulation and density-driven flows from river plumes. Water level dynamics evolved from tidally influenced variability to anthropogenic regulation through the Afsluitdijk's 17 discharge sluices, maintaining summer lows at -0.40 m for evaporation and irrigation support, rising to -0.20 m in winter to buffer against storms and facilitate pumping. This stabilization reduced flood risks but introduced new challenges in sediment resuspension and nutrient retention, as the basin's mean depth of 5.5 m and fetch-induced became primary erosive agents absent prior tidal scour.

Impacts on Marine Life, Fisheries, and Biodiversity

The closure of the Zuiderzee by the on May 28, 1932, transformed the mesohaline estuary ( 9-10‰) into the oligohaline , a nearly freshwater lake, causing the rapid die-off of saltwater-adapted (e.g., Acartia spp.) and benthic (e.g., Corophium and ), which were replaced by freshwater species such as Cyclops and Hydrobia jenkinsi. This shift eliminated habitats for brackish-water species, leading to a as the diverse estuarine was supplanted by a less varied freshwater one. Saltwater fish stocks collapsed due to intolerance of low salinity and loss of spawning grounds; herring (Clupea harengus) catches fell from 8,987,000 kg in 1925 to zero by 1934, anchovy (Engraulis encrasicolus) from 3,326,000 kg in 1926 to zero by 1933, and flounder (Platichthys flesus) from 3,647,000 kg in 1930 to 25,000 kg in 1938. Migratory species like eel (Anguilla anguilla), salmon, and sea trout were severely impacted by the barrier to seasonal movements between freshwater and marine environments, preventing reproduction and juvenile recruitment. While some freshwater species proliferated—e.g., eel catches rose from 756,000 kg in 1925 to 2,588,000 kg in 1938, and pike-perch (Sander lucioperca) from 111 kg in 1933 to 125,082 kg in 1938—the overall fishery value declined by approximately 60%, from an average of 3,241,000 guilders annually (1925-1931) to 1,383,000 guilders (1932-1938), affecting around 2,000 fishing vessels. Subsequent polder reclamations further contracted the IJsselmeer’s surface area, exacerbating habitat loss for remaining fish populations and contributing to overexploitation of lake stocks, as seen in the post-1932 declines of smelt (Osmerus eperlanus) from 1,478,000 kg in 1925 to 209,000 kg in 1938. The estuarine biodiversity hotspot, once supporting productive fisheries for oysters (Ostrea edulis) and other marine resources, was irreplaceably altered, with no full recovery of pre-closure species assemblages despite later interventions like the Fish Migration River.

Long-Term Ecosystem Adaptations and Monitoring

The closure of the in 1932 initiated a rapid ecological transition in the former , with levels dropping from brackish to freshwater conditions within about 15 years, causing the decline of marine-tolerant , , and fish species while enabling the expansion of freshwater taxa such as (Perca fluviatilis) and (Esox lucius). This shift disrupted the original brackish food web, leading to initial crashes in populations of species like (Clupea harengus) and (Pleuronectes platessa), which could no longer access spawning grounds or tolerate the changing chemistry. Over decades, the stabilized into a new equilibrium dominated by freshwater dynamics, though with persistent low overall due to the lake's shallow depth (average 5.5 meters) and artificial water level controls that limit natural variability. Submerged aquatic vegetation, including species like and , gradually recolonized suitable areas, providing habitats for and supporting secondary consumers, but resuspension of fine sediments by wind continues to hinder light penetration and in much of . Avian and benthic communities exhibited notable long-term adaptations, with migratory birds such as smew (Mergellus albellus) and greylag geese (Anser anser) increasingly utilizing the shallow, nutrient-enriched shallows for winter foraging, while breeding waders benefited from emergent vegetation in polder edges and restored wetlands. Diadromous fish like European eel (Anguilla anguilla) faced ongoing barriers to migration, resulting in recruitment declines of up to 90% in some estimates post-closure, though selective breeding and habitat enhancements have supported partial recovery in connected rivers. Vegetation adaptations included the invasion of exotic macrophytes in eutrophic zones, contributing to localized biodiversity hotspots but also exacerbating algal blooms during high phosphorus inputs from agricultural runoff; these dynamics reflect causal feedbacks where reduced tidal flushing amplified nutrient trapping, altering carbon cycling and oxygen levels. In Lake Markermeer, a remnant of the original basin, wind-driven turbidity has suppressed phytoplankton diversity, but experimental artificial islands introduced since the 1980s have boosted bird nesting success by 20-30% for species like common terns (Sterna hirundo). Monitoring of these adaptations is conducted through integrated programs by and , employing annual surveys of (e.g., chlorophyll-a levels averaging 10-20 µg/L), biomass via and trawls, and bird counts under the EU Birds Directive, with data revealing stable but simplified trophic structures since the 1950s. The area, designated as a site, undergoes mandatory assessments under the , tracking metrics like ecological status indices (often rated moderate due to altered hydromorphology) and incursions, such as zebra mussels (Dreissena polymorpha) which filter water but alter benthic communities. Recent initiatives, including DNA metabarcoding for rapid assessment by the Netherlands Institute of Ecology, enable detection of subtle shifts, informing interventions like gradual land-water transition restorations that have increased primary productivity by enhancing light availability and reducing resuspension. Long-term data indicate resilience to fluctuations but vulnerability to climate-driven warming, with projections for increased cyanobacterial dominance if nutrient loads persist above 100 mg/m³ total .

Socioeconomic Outcomes

Agricultural Productivity and Land Use Changes

The Zuiderzee Works transformed approximately 165,000 hectares of former into across four major : (20,000 ha, drained 1930), (48,000 ha, drained 1942), Eastern Flevoland (54,000 ha, drained 1957), and Southern Flevoland (43,000 ha, drained 1967). This reclamation shifted from a saline marine environment, previously unsuitable for , to freshwater-controlled optimized for through diking, , and processes that took 7-9 months per polder followed by ongoing management. The marine clay , once desalinized, proved highly fertile, supporting mechanized operations on consolidated plots with average farm sizes of 20-55 hectares in early polders like and , designed for "rational " emphasizing efficiency and scale. Agricultural productivity surged due to the flat terrain, precise water management via pumps and canals, and nutrient-rich sediments, enabling yields that often surpassed national averages. In long-term experiments on former sea-bottom soils in the , potential maximum yields under non-limiting water and minerals reached 95,862 kg/ for potatoes, 76,590 kg/ for sugar beets, and 11,254 kg/ for (fresh weight basis, adjusted for 25% ). Actual outputs in polders approximated these potentials, with yields hitting 80,000 kg/, facilitated by practices like early canopy closure for enhanced light interception. Early polders prioritized arable crops (potatoes, beets, ) and grasslands for , with state-managed estates employing heavy machinery—such as 140 crawler tractors and 200 wheeled tractors across 20,000 —to cultivate and level land annually. Land use evolved from near-total agricultural allocation in and (over 90% farmland) to mixed purposes in later polders, where about 50% remained for crops, , and livestock amid urban expansion, yet sustaining high-output farming on heavy (50%) and light (39%) clay soils. This added roughly 10% to the ' cultivated land, bolstering post-World War II through diversified production including oilseed rape, vegetables, and , though subsidence and drainage needs required continuous investment. Overall, the polders' engineered minimized flood risks while maximizing , yielding undisputed gains in output that contributed to the ' status as a top agricultural exporter.

Population Settlement and Urban Growth

The initial settlements in the reclaimed polders of the Zuiderzee Works emphasized rural agricultural colonization, drawing farmers from across the through selective programs aimed at establishing productive farming communities. In the polder, drained between 1927 and 1930, settlement focused on internal colonization, with parcels allocated to qualified farmers to cultivate the 20,000-hectare area for intensive agriculture; villages such as Wieringerwerf emerged as service centers for these operations, maintaining a predominantly rural with limited urban expansion. The , reclaimed by 1942 and resettled after wartime flooding, followed a similar model, prioritizing division into farmsteads radiating from central villages; Emmeloord developed as the administrative and commercial hub, supporting a oriented toward farming and related industries rather than large-scale . policies reinforced this rural focus, with schemes distributing land to colonists selected for their expertise in modern techniques, fostering steady but modest tied to agricultural viability. Urban growth accelerated in the polders, where postwar housing shortages prompted a shift from pure agrarian use to mixed development, including planned cities to accommodate urban spillover from the region. , founded in East Flevoland polder after its 1957 enclosure, was designated as the provincial capital with an initial target population of around 100,000, evolving into a multifunctional center with residential, commercial, and administrative roles. , in South Flevoland polder enclosed in 1967, was explicitly planned in the 1970s as a commuter-oriented new town to house overflow from congested western cities, rapidly expanding through modular housing and infrastructure to support high-density living; by the late , such developments had transformed the polders from experimental farmlands into significant population hubs. Overall, the polders' population swelled from near-zero at reclamation to approximately 400,000 by 2018, representing about 2.3% of the Netherlands' total, with urban concentrations in Almere and Lelystad driving much of the increase while earlier polders like Wieringermeer and Noordoostpolder retained agrarian demographics. This growth reflected adaptive planning, transitioning from colonization for food security to addressing demographic pressures, though it necessitated ongoing investments in infrastructure to sustain viability on subsiding reclaimed soil.

Establishment and Development of Flevoland Province

The province of Flevoland was formally established on 1 January 1986 as the twelfth province of the Netherlands, encompassing the reclaimed lands of the Noordoostpolder, Oostelijk Flevoland polder, and Zuidelijk Flevoland polder. These areas, previously part of the Zuiderzee, had been transformed through the Zuiderzee Works into arable land, with the Noordoostpolder drained and settled starting in 1942 under the temporary administration of Overijssel province. Oostelijk Flevoland followed with dike construction beginning in 1950 and drainage completed by 1957, while Zuidelijk Flevoland's works spanned 1959 to 1968. Prior to provincial status, the newer polders operated under provisional governance structures managed by the national Zuiderzee Works directorate to facilitate land allocation, infrastructure development, and initial settlement. Development of Flevoland emphasized balanced growth between agriculture and urban expansion to alleviate population pressures in the conurbation. Lelystad, designated as the provincial capital and named after Zuiderzee Works engineer Cornelis Lely, saw its first residents arrive in 1967, with formal municipal status granted in 1980. , planned as a high-density commuter hub, began construction in the early 1970s and rapidly expanded to become the province's largest city, housing over 200,000 inhabitants by incorporating overspill from and . Agricultural zones, particularly in the , featured consolidated large-scale farms on heavy clay soils, focusing on cash crops like potatoes, beets, and cereals, supported by modern drainage and irrigation systems. Since its inception, has experienced sustained population increase driven by targeted migration incentives and infrastructure investments, including rail links to and high-speed roadways. From an initial post-reclamation base of scattered farming communities, the province's demographics shifted toward urban-suburban patterns, with economic diversification into logistics, , and services complementing its agrarian roots. This structured approach to provincial formation and growth exemplified Dutch postwar planning, integrating reclaimed territories into the national fabric while prioritizing self-sufficiency in food production and housing.

Controversies and Critiques

Fishermen's Opposition and Livelihood Losses

The Zuiderzee, a brackish teeming with species like , anchovies, and , supported a vibrant that employed thousands, particularly in ports such as , , and . Fishermen vehemently opposed the Zuiderzee Works, arguing that damming the would eradicate their primary fishing grounds and terminate the brackish-water fishery, rendering traditional methods obsolete. This resistance was compounded by longstanding internal conflicts among fishermen over gear and territories, but unified against the reclamation plans proposed by Cornelis Lely since 1891. Protests intensified in the early as legislative momentum built. In , B. Demmer's General Committee of Fisheries demanded 14 million in compensation, far exceeding the government's initial 4.5 million proposal for pensions and relocation aid for those over 55. By , a meeting drew over 600 fishermen from eastern and western provinces, highlighting fears of economic ruin without adequate redress. The Support Act provided only short-term allowances of 3-5 years, deemed insufficient by opponents, leading to a demonstration attended by over 1,400 participants, including fishermen, industry representatives, and members of parliament, who decried the measures as failing to address long-term livelihood displacement. The Afsluitdijk's completion on August 28, 1932, severed the from the , rapidly transforming it into the freshwater and precipitating a collapse in saltwater-dependent fisheries. Marine species migrations halted, with brackish-water stocks like declining sharply as salinity dropped, forcing a shift to less lucrative freshwater species such as smelt and perch; the overall commercial fishery in the former Zuiderzee dwindled, compelling many to relocate to or operations. Communities like adapted by pivoting to offshore , but the transition exacted heavy tolls, including loan denials for vessel upgrades post-1918 and persistent economic hardship, underscoring the works' prioritization of over coastal fishing heritage.

Environmentalist Challenges and Cost Overruns

Opponents of the Works raised concerns about the ecological consequences of enclosing the saline , anticipating disruptions to the estuarine that supported diverse and migratory birds. The proposed was expected to eliminate tidal influences, converting the inlet into a stagnant freshwater lake and potentially diminishing habitats for species adapted to brackish conditions, including and fish stocks central to the regional . Coastal communities along the adjacent voiced apprehensions that the dam would amplify tidal ranges and storm surges in their areas by redirecting water flows, with modeling and observations later confirming an approximate 50% increase in tidal amplitude due to the altered . Although modern environmental advocacy was nascent during the planning phases in the early , these hydrological and risks were cited by critics as threats to the natural balance of the inlet system, prompting debates over irreversible loss of dynamic coastal wetlands. The project's execution encountered substantial cost overruns, as actual expenditures significantly surpassed initial estimates derived from Cornelis Lely's 1891 plan and subsequent Zuiderzee Society projections. While early budgets allocated around 190 million Dutch guilders for the overall works, the construction alone consumed 126 million guilders between 1927 and 1932, driven by material demands, labor mobilization amid economic pressures, and unforeseen geotechnical challenges in the soft seabed. Cumulative costs for the full Zuiderzee Works, including reclamations and drainage, escalated to approximately 1.5 billion guilders by mid-century, reflecting inflation, extended timelines from flood events like the , and iterative engineering adaptations not fully anticipated in pre-war assessments. These overruns strained national finances during the , contributing to political scrutiny despite the long-term benefits in flood mitigation and land gain.

Debates on Nature Preservation vs. Human Expansion

The initial implementation of the Zuiderzee Works from 1918 to 1957 elicited limited explicit arguments for nature preservation, as contemporary opposition centered on economic disruptions to fisheries rather than broader ecological concerns. Flood events, such as the 1916 storm that killed 13 people and inundated polders, underscored the imperative for enclosure to mitigate and storm surges, prioritizing human safety and over unaltered coastal ecosystems. Proponents, including engineer Cornelis Lely, emphasized causal benefits like converting 1,650 km² of shallow sea into arable freshwater polders, yielding 410 km² of initially drained land by 1968 that supported for a growing population exceeding 13 million by 1960. Debates escalated in the 1970s over the unfinished polder, planned to reclaim 410 km² from the but deferred indefinitely by 1986 amid rising environmental awareness. Advocates for expansion invoked first-principles needs for housing and farmland amid demographic pressures—Dutch reached 450 persons per km² by 1980—arguing that managed freshwater systems could sustain higher productivity than preserved marine inlets prone to silting and erosion. Opponents, including nascent conservation groups, countered that further drainage would exacerbate already caused by the , reducing migratory bird foraging areas and freshwater plankton diversity while forgoing recreational water uses valued at millions in annual by the 1980s. This tension highlighted causal trade-offs: reclamation enhanced human but irreversibly shifted a brackish to oligotrophic freshwater, with post-closure studies documenting a 90% decline in certain fish species like due to loss. The abandonment of reflected a policy pivot toward ecological integration, influenced by cost overruns exceeding initial estimates by 200% and public referenda favoring preservation. Critics of expansion, drawing on emerging data from monitoring, noted compensatory gains in bird populations—such as breeding waders increasing 50% in edges—but argued these paled against lost tidal dynamics akin to the adjacent site. Recent adaptations, like the 2016 Marker Wadden project creating 1,800 hectares of artificial islands from dredged silt, demonstrate retrospective efforts to balance expansion legacies with restoration, boosting invertebrate biomass tenfold in test areas to support piscivorous birds. Empirical assessments affirm that while human expansion via the Works averted flood damages estimated at billions in present value, preservation advocates succeeded in halting further incursions, preserving 340 km² of as a buffered freshwater amid sea-level rise projections of 0.5–1 meter by 2100.

Technical Legacy and Modern Relevance

Innovations in Dike Building and Water Management

The construction of the , central to the Zuiderzee Works, represented a culmination of refined dike-building practices applied at unprecedented scale, spanning 32 kilometers from 1927 to 1932. Traditional techniques involved layering a core of for stability, reinforced on the inland side with heavy stone and protected on the seaward side by brushwood mattresses—woven branches laid flat to prevent scour—topped with boulders for wave resistance. This method, evolved from medieval earthworks, was mechanized with dredgers and barges to deposit materials rapidly, enabling completion despite challenging tidal currents and storms. The final closure on May 28, 1932, utilized a specialized "mat-breaking" process, where mats (bundled branches) were sunk across the remaining gap, filled with clay and stones to halt seawater inflow, marking a precise adaptation for large-scale enclosure. Subsequent enclosing dikes for polders, such as the 27-kilometer dike completed in 1929, incorporated similar clay cores but integrated revetments and sheet piling for enhanced durability against and wave action. These structures averaged 7-10 meters in height, with slopes designed at 1:6 ratios to withstand gales, reflecting empirical optimizations from prior flood data rather than untested designs. Innovations extended to modular construction, using prefabricated elements for gates and pump housings, reducing on-site labor amid the era's economic constraints. In water management, the Zuiderzee Works pioneered large-scale control by transforming the enclosed into the freshwater through deliberate flushing: complexes at Den Oever (five outlets, each 150 meters wide) and Kornwerderzand allowed discharge of excess water while permitting inflow of and IJssel river freshets to dilute saltwater, achieving potable levels by 1936 after two years of operation. This passive-active hybrid system minimized pumping costs initially, with capacities handling up to 300 cubic meters per second per during storms. Polder drainage shifted from wind-powered screws to diesel and electric centrifugal pumps, as in Wieringermeer where 42 pumps removed 165 billion liters of water in 1930 over six weeks, enabling faster reclamation than historical windmill-dependent methods limited to 1-2 meters lift. Later like (1942) featured integrated canal networks with automated level controls, precursors to modern hydrometric monitoring, sustaining groundwater tables at -4 to -6 meters below for . These techniques emphasized redundancy, with dikes overbuilt to 5.5 meters above mean and water levels regulated via 19th-century empirical rules updated with gauging stations, ensuring without reliance on speculative models. The legacy influenced global standards, prioritizing layered defenses over singular barriers.

Influence on Delta Works and Global Engineering

The completion of the in 1932 as the centerpiece of the Zuiderzee Works demonstrated scalable techniques for constructing extended sea barriers under dynamic conditions, including layered revetments of clay, sand, and stone to achieve watertightness over 32 kilometers. This hands-on experience in managing open-water construction logistics, material sourcing, and salinity transitions directly informed the , launched in 1958 following the 1953 flood that inundated 9% of the ' farmland and caused 2,500 square kilometers of flooding. Engineers applied similar core-wall designs and phased dike-raising methods, adapting them to the Delta's compartmentalized closures, which shortened the coastline by 700 kilometers while incorporating sluices for flushing—lessons refined from the Zuiderzee's full enclosure. The Works' success in transforming saline inlets into freshwater reservoirs via controlled drainage and pumping also shaped hydrology, emphasizing adaptive water level management to prevent peat subsidence and salinization in reclaimed zones. By 1997, the program's 13 major structures, including movable storm surge barriers like the , had elevated flood protection standards to withstand a 10,000-year , building on precedents to integrate ecological considerations such as partial openness for . This progression underscored causal linkages between empirical trial-and-error in early 20th-century diking and the probabilistic risk modeling that defined later defenses. Globally, the Zuiderzee Works established hydraulic expertise as a benchmark for coastal enclosure and reclamation, influencing projects in vulnerable deltas by showcasing viable paths to land gain amid sea-level pressures—reclaiming 1,484 square kilometers of polders from to 1986. Techniques for shallow-water diking and wetland conversion informed international efforts, such as U.S. consultations for protections and plans, where Dutch firms exported knowledge on resilient barrier systems. The project's enduring legacy, recognized alongside the as a modern engineering wonder, has promoted adaptive strategies in regions like Vietnam's , prioritizing empirical data on sediment dynamics over unproven alternatives.

Recent Adaptations and Resilience Enhancements

The reinforcement of the , a core component of the Zuiderzee Works completed in , has been a primary focus of recent enhancements to address heightened risks from and storm surges. Launched in 2018 as a public-private , the upgrades the 32-kilometer-long dike to meet contemporary standards, including raising its crest by up to 2 meters in vulnerable sections and strengthening the structure against overtopping waves. By mid-2025, major works such as dike body reinforcement and crest elevation were largely completed, with ongoing refinements to ensure the structure withstands a 1-in-10,000-year event, far exceeding original design criteria from the early 20th century. These adaptations incorporate innovative designs, such as optimized usage reducing material needs by integrating and soil reinforcements, while maintaining the dike's multifunctional role in water regulation. Ecological enhancements integrated into the project bolster long-term resilience by restoring connectivity between the and . In September 2025, a 1.6-kilometer-long River was completed, featuring a constructed with natural gradients and substrates to enable upstream migration of diadromous fish species like and , countering losses from the original enclosure. Complementary upgrades include new pumping stations and reinforced sluices at Den Oever and Kornwerderzand, increasing discharge capacity to 500 cubic meters per second during high lake levels, which mitigates salinization risks and supports freshwater retention amid variable precipitation patterns. In the IJsselmeer basin, adaptations emphasize adaptive water level management and natural buffers to enhance resilience against both flooding and drought under projected climate scenarios. The Dutch Delta Programme, ongoing since 2010, guides these efforts, with measures like the Friesland IJsselmeer coast natural climate buffer project creating vegetated foreshores to dissipate wave energy and reduce erosion, allowing controlled elevation of lake water levels by up to 20-40 centimeters during dry periods to secure freshwater supplies for and urban use. A 2026 study under the programme will evaluate further interventions, such as dynamic dike reinforcements and salinization barriers, to balance flood protection for surrounding polders with ecological functions, informed by models predicting up to 1 meter of relative by 2100. These enhancements, part of the broader Freshwater Delta Programme, integrate real-time monitoring and flexible gating to prevent intrusion of saltwater during events, preserving the system's role in national .

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