Subsidence Due to Peat Decomposition in the Netherlands Kinematic Observations from Radar Interferometry

Subsidence due to peat decomposition in the Netherlands kinematic observations from radar interferometry

Miguel Caro Cuenca, Ramon Hanssen, Freek van Leijen.

Fringe 2007, Frascati, Italy Netherlands, Area Overview

Amsterdam

Utrecht The Hague

Rotterdam ‘Randstad’: a near-circular series of towns

Haarlem Amsterdam

Leiden

The Hague Utrecht

Rotterdam

The ‘GREEN HEART’ • Typical Dutch landscape: peat grassland polders (west NL) • fen-meadows, drained peat soils, natural and artificial lakes, ditches, reed swamps and quaking fens. • To keep land suitable for agricultural use, peat area has to be drained • Drainage resulted in subsidence !polders with fen-meadows are now 1-2 m below sea level. • In between the fen-meadows, deep polders with a clay soil are found. These deep polders used to be large lakes, which have been reclaimed in the 17th century for agricultural use. Presently, these polders are 2-6 m below sea level (Best and Bakker, 1993). • The most characteristic cultural landscape of the Netherlands: peat grassland polders (west NL) • fen-meadows consisting of wet pasture lands with drained peat soils alternated by natural and artificial lakes, ditches, reed swamps and quaking fens. • current fen meadows have originated from the drainage of a large peat system dating back from 1800 B.C. To keep the land suitable for agricultural use, the peat area has been drained deeper in recent decades. This drainage has resulted in a subsidence of the soil and as a result the polders with fen-meadows are now 1-2 m below sea level. In between the fen-meadows, deep polders with a clay soil are found. These deep polders used to be large lakes, which have been reclaimed in the 17th century for agricultural use. Presently, these polders are 2-6 m below sea level (Best and Bakker, 1993). As in other parts of the country, water tables in Noord- Hollands Midden are controlled to facilitate agriculture, building of housing, infrastructure and other land-uses and to avoid damage and inconveniences caused by water. However, problems with water surpluses as well as water deficiencies have had large economical consequences in the area recently. Based on predictions from climate change scenarios, the problems in the area are expected to increase in the future • Modern fen-meadow: this is the current situation with ‘‘counter-natural’’ water management. Waterlevels are higher in summer (40 cm below ground level) than in winter (70 cm below ground level). Thearea can be used for (extensive) agricultural practices and is suitable for meadow birds. However, because of the relatively low water levels year round, the peat will oxidise and the soil will subside. • Historical fen-meadow: a more historical situation with management aimed at a more natural water level fluctuation: the groundwater level varies between 40 cm below soil surface in summer and 20 cm below soil surface in winter. Agriculture is still possible, however, less intensive than in the modern peat pasture scenario. The area is still suitable for meadow birds. Soil subsidence will still occur, but less rapidly than in the modern fen-meadow scenario. • Dynamic mire: water levels will fluctuate between 40 cm above soil surface in winter and more or less at the soil surface in summer. The area is not suitable for agriculture any more and as a result the meadow birds will largely disappear. The area will consist of reed beds, carrs, quaking fens and open water. Nature values belonging to these habitats will develop. The area will be suitable for storage of water in periods of heavy precipitation.

Where’s the peat?

• 300.000 core drillings of Holocene layer over Netherlands (Van der Linden et al. 2000) • Large part of these drillings in the fen-meadow areas • 4 samples Different core drills Surface

Water table -40 cm

Water table -80 cm

Legend Sand Peat Clay No subsidence No subsidence Subsidence if water>-40 cm Estimation of expected subsidence based on interpolated drillings

Peat compaction 250 m (=subsidence) for a water table of -40 cm b.s. [MM/Y] grid cell

No subsidence

Reclaimed lakes: peat removed: No subsidence

National land subsidence prognosis

>8 cm/y

3-7 cm/y

0-1 cm/y

Land subsidence scenario until 2100

>8 cm/y 0-0.2 cm/y 6-8 cm/y 0 cm/y

Uplift 0.2 cm/y 3-4 cm/y Uplift >0.2 cm/y

1-2 cm/y

0.2-0.5 cm/y

• Peat thickness increases towards center of Green Heart: max. 7 meters. • The terrain subsides due to peat oxidation, ~1cm/yr. • The ground water level is high to control the subsidence due to peat oxidation. Peat oxidation process

- Peat is composed of organic material. - Peat oxides when it is in contact with the air, i.e. reduces in volume producing the consequent subsidence - Then ground water level get closer to the surface. - The water is pumped out to have a dry ground.

Ground water table Peat Peat Ditch The ‘Green Heart’

• Most of the soil contains peat. • Peat thickness increases towards the center of the area: max. 7 meters. • Terrain subsides due to peat oxidation, expected ~1cm/yr. • Only vadose zone (above groundwater table) • ! ground water table kept high to control subsidence

(in the year 2700: all peat is gone !! ! Land is 7 m lower ! Main question: can we observe this proces from space? • Hypothesis 1: focus on linear compaction rate (complication: are PS representative for shallow subsurface)?

Sp e c u la r D ih e d ra l Instable Compaction foundation Stable layer

A B C Compaction D Main question: can we observe this proces from space?

• Hypothesis 1: focus on linear compaction rate (complication: are PS representative for shallow subsurface)?

• Hypothesis 2: if proces is peat-related, then there should be strong seasonal signal due to ground water changes Radar (PSI) analysis

Linear deformation , Results

Center of Green Hart subsides at Amsterdam a rate of 1.7mm mm/yr with respect to The Hague

The Hague

Utrecht

Rotterdam After adding the seasonal effects to the model the linear deformation is less PS results: Linear Deformationvis icbleo. ntribution, The center of the Groene Hart subsides [mm/yr] 0.9 mm /yr respect to The Hague

Amsterdam Amsterdam

The Hague The Hague Utrecht

Utrecht

Rotterdam Rotterdam PS results: Linear Deformation contribution, [mm/yr] Amsterdam Center of the Groene Hart subsides ~2 mm /yr relative to The Hague

-3 mm/y The Hague Utrecht

Rotterdam 0 mm/y Confirmation through study of the seasonal effects. Ground water level variation in Green Heart (…or, is the green heart beating? …or dead?) winter

summer

I. Hoving, EUROPEAT 2006. Deformation model, linear + seasonal

• A is the amplitude, • T the period 1 year fixed,

• t0 time offset relative to master image, (August)

t0>0 t0<0 Values of the amplitudes and time offsets dependent of reference point!

… winter spring summer autumn winter…

August PS results: Seasonal contribution, results

Amplitude, A Time offset, t0

The histogram of the time offset reveals 3 different deformation regimes

Sqeezing t0 histogram may lead to optimal reference point! Seasonal contribution, Amplitude [mm].

There is correlation of the amplitudes of the scatterers located in the peat areas.

0.0

mm 1.5

3.0 Seasonal contribution, time series

An area of radius 500 m was chosen to study the time-series. The noise was reduced by averaging the results of the PS located inside the area. The reference, also an area and not a single point, was at The Hague.

Ref. at The Hague

Time [yr] respect master(23/08/1995) (Deliberate offset) Conclusions

• Something seems to be happening… • Probably effects related to shallow subsurface; peat? • Linear effect: peat compaction? • Seasonal effect: groundwater level changes?