File list
This special page shows all uploaded files.
| Date | Name | Thumbnail | Size | Description | Versions |
|---|---|---|---|---|---|
| 19:41, 19 March 2020 | FallingApron.jpg (file) |  |
158 KB | Principle of the falling apron. | 1 |
| 19:41, 19 March 2020 | ConcreteArmorUnits.jpg (file) |  |
93 KB | Examples of concrete armor units. | 1 |
| 19:40, 19 March 2020 | SlipFailure.jpg (file) |  |
131 KB | Slip failure of the breakwater core. | 1 |
| 19:39, 19 March 2020 | SeabedLiquefaction.jpg (file) |  |
140 KB | Collapse of the armor layer due to seabed liquefaction under the toe of the breakwater. | 1 |
| 19:38, 19 March 2020 | CrownElement.jpg (file) |  |
54 KB | Breakwater with crown element. | 1 |
| 19:37, 19 March 2020 | RearSideFailure.jpg (file) |  |
134 KB | Erosion of the rear side of the breakwater due to overtopping waves. | 1 |
| 19:36, 19 March 2020 | OffshoreBreakwaterShoreRevetment.jpg (file) |  |
135 KB | Left panel: Offshore rubble-mound breakwater. Right panel: Rubble-mound revetment protecting the backshore. | 1 |
| 12:49, 29 February 2020 | Figure6 3 COLOR.png (file) |  |
493 KB | Global map of the amplitude of quarterdiurnal tide M4. | 1 |
| 12:46, 29 February 2020 | Figure5 2 COLOR.png (file) |  |
491 KB | Global map of the luni-solar declinational diurnal component K1. | 1 |
| 12:44, 29 February 2020 | Figure5 1 COLOR.png (file) |  |
608 KB | Global map of the principal lunar semidiurnal component. | 1 |
| 12:44, 29 February 2020 | Figure1 3 COLOR.png (file) |  |
93 KB | Global distribution of the tidal range. | 1 |
| 12:43, 29 February 2020 | Figure1 2 COLOR.png (file) |  |
105 KB | Global distribution of semidiurnal, diurnal and mixed tides. | 1 |
| 13:43, 22 February 2020 | DamBreakFlowDerivation.jpg (file) |  |
311 KB | Derivation of the solution for frictionless dam break flow. | 1 |
| 13:40, 22 February 2020 | Dijkdoorbraak1953.jpg (file) |  |
314 KB | Sea dikes protecting low-lying polders in the Netherlands were breached during the extreme storm surge of 31 January 1953. | 1 |
| 16:46, 21 February 2020 | AccraCloggedDrainageCanals.jpg (file) |  |
167 KB | Clogged drainage canals in Accra (Ghana). Photo credit TU Delft. | 1 |
| 11:40, 19 February 2020 | FreshMakerSystem.jpg (file) |  |
55 KB | Creation of a fresh water lens by fresh water infiltration after artificial lowering of the salt water interface. | 1 |
| 11:39, 19 February 2020 | PaleochannelInfiltration.jpg (file) |  |
43 KB | Schematic representation of the underground fresh water reservoir created by fresh water infiltration in a sandy paleochannel deposit protruding above the mean land level. | 1 |
| 11:38, 19 February 2020 | HydraulicBarrier.jpg (file) |  |
103 KB | Schematic representation of a hydraulic barrier at the seaward entrance of an aquifer. | 1 |
| 11:37, 19 February 2020 | SeepageMechanisms.jpg (file) |  |
183 KB | Illustration of different seepage processes. | 1 |
| 11:36, 19 February 2020 | GroundwaterManagementAspects.jpg (file) |  |
173 KB | Factors that influence the groundwater system. | 1 |
| 11:34, 19 February 2020 | SeepageUpconing.jpg (file) |  |
37 KB | Salt water upconing under a seepage hotspot. | 1 |
| 11:34, 19 February 2020 | AbstractionUpconing.jpg (file) |  |
92 KB | Salt water upconing under an abstraction well. | 1 |
| 11:33, 19 February 2020 | SeawaterIntrusionScheme2.jpg (file) |  |
206 KB | Schematic representation of seawater intrusion into a coastal aquifer with confining top layer. | 1 |
| 11:32, 19 February 2020 | SeawaterIntrusionScheme1.jpg (file) |  |
85 KB | Schematic representation of seawater intrusion into a homogeneous coastal aquifer. | 1 |
| 22:53, 9 February 2020 | LoireOxygen.jpg (file) |  |
159 KB | Dissolved oxygen concentration in the Loire estuary at Cordemais for the years 2007-2011. | 1 |
| 22:52, 9 February 2020 | DischargeLoireGirondeTurbidityMax.jpg (file) |  |
197 KB | Position of the turbidity maximum in the Loire and Gironde estuaries for different fluvial discharges. | 1 |
| 22:52, 9 February 2020 | LandVanSaeftinghe.jpg (file) |  |
157 KB | View of the Land van Saeftinghe. Photo credit Anita Eijlers | 1 |
| 22:50, 9 February 2020 | FluidMudLoireEstuary.jpg (file) |  |
233 KB | Fluid mud in the Loire estuary during neap tide and low fluvial discharge. | 1 |
| 22:50, 9 February 2020 | TurbidityMaximumLoireEstuary.jpg (file) |  |
206 KB | Turbidity maximum in the Loire estuary at low fluvial discharge. | 1 |
| 16:56, 5 February 2020 | WaterAssessmentAmsterdam.jpg (file) |  |
153 KB | Assessment of policy objectives related to urban water management for the city of Amsterdam. | 1 |
| 16:34, 5 February 2020 | RoomForWaterCoastalCities.jpg (file) |  |
445 KB | Examples of room for water in Dutch cities. | 1 |
| 16:31, 5 February 2020 | KatwijkCoastalProtection.jpg (file) |  |
24 KB | The coastal village Katwijk (Netherlands) has been protected by an artificial dune built in front of the seashore boulevard with sand extracted far offshore. | 1 |
| 18:25, 1 February 2020 | ExpansionCoastalCities.jpg (file) |  |
100 KB | Schematic representation of the characteristic geographical setting of coastal towns that were built in delta plains, close to estuaries or lagoons. | 1 |
| 17:34, 1 February 2020 | SlumsMonrovia.jpg (file) |  |
268 KB | Slums on a sandspit at the coast of Monrovia (Liberia). | 1 |
| 17:33, 1 February 2020 | SubsidenceCoastalCities.jpg (file) |  |
106 KB | Subsidence in a few coastal megacities. | 1 |
| 17:28, 1 February 2020 | PopulationCoastalCities.jpg (file) |  |
209 KB | Population of coastal cities around 1950 and in 2020. | 1 |
| 21:29, 19 January 2020 | ChaoticDispersion.jpg (file) |  |
137 KB | Stretching of an initially rectangular patch of dye, according to a 2D numerical hydrodynamic model of the central part of the Western Wadden Sea. | 1 |
| 15:06, 19 January 2020 | DeadZoneDispersion.JPG (file) |  |
123 KB | Dispersion by an intertidal "dead zone" along a tidal channel. | 2 |
| 19:27, 13 January 2020 | TsunamiScheme.jpg (file) |  |
74 KB | Schematization of the shoreface and beach used in the tsunami runup model of Madsen and Schäfer (2010). | 1 |
| 19:25, 13 January 2020 | TsunamiMonitoringNetwork.jpg (file) |  |
243 KB | The global tsunami monitoring network. | 1 |
| 19:24, 13 January 2020 | TsunamiWarningDARTsystem.png (file) |  |
807 KB | The DART monitoring system. Image NOAA. | 1 |
| 19:23, 13 January 2020 | Tsunami Japan 2011 S.Yoshida.jpg (file) |  |
220 KB | Destruction at the Honshu coast, Japan, by the tsunami of March 11, 2011. Image Y. Yoshida, Flickr creative commons. | 1 |
| 19:23, 13 January 2020 | Tsunami Japan 2011 Flickr J.Teramoto.jpg (file) |  |
207 KB | Destruction at the Honshu coast, Japan, by the tsunami of March 11, 2011. Image J. Teramoto, Flickr creative commons. | 1 |
| 19:22, 13 January 2020 | Tsunami Phuket 2004 S.Kennedy.jpg (file) |  |
183 KB | Impact of the Indian Ocean tsunami of December 26, 2004 at Phuket, Thailand. Image S. Kennedy, Flickr creative commons. | 1 |
| 19:20, 13 January 2020 | Tsunami Phuket 2004.png (file) |  |
114 KB | The Indian Ocean tsunami of December 26, 2004, invading the coast at Phuket Thailand as a breaking bore. | 1 |
| 19:18, 13 January 2020 | RingofFireUSGS.jpg (file) |  |
135 KB | Ring of fire around the Pacific. | 1 |
| 15:22, 29 December 2019 | SouthForkDamFailure1889.jpg (file) |  |
182 KB | Breach of the earth-filled South Fork Dam on Lake Conemaugh (Pennsylvania, US) in 1889. | 1 |
| 15:18, 29 December 2019 | DamBreakWaveProfiles.jpg (file) |  |
78 KB | Wave profile after dam break. Red line: frictionless solution. Blue band: experimental lab data. | 1 |
| 15:17, 29 December 2019 | DamBreakFlowPrinciple.jpg (file) |  |
74 KB | Left panel: Schematic representation of water retention behind a dam. Right panel: Positive downstream and negative upstream surges following instantaneous dam removal. | 1 |
| 17:58, 14 December 2019 | WaveHeightDirectionalSpreading.jpg (file) |  |
114 KB | Wave height directional distribution, a so-called wave rose. | 1 |
