Journal of Renewable Energy and Sustainable Development (RESD)      Volume 2, Issue 2, December 2016 - ISSN 2356-8569 
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ENVIRONMENTAL COMPENSATION FOR PORT 

EXTENSION: THE CASE OF ROTTERDAM HARBOUR AND 

NATURE COMPENSATION, POLICY AND PRACTICE 
F. VAN DER MEULEN 

 Frank van der Meulen Consultancy, De Ruytersingel 56, 2253 TX Voorschoten, The Netherlands 
frank.vandermeulen@hetnet.nl

 

Abstract - The paper focuses on two aspects often 

forgotten when dealing with smart ports: ecology and 

compensation of damage. The port of Rotterdam (The 

Netherlands) recently built a large extension, 

Maasvlakte 2. It was built in an area with valuable 

coastal ecosystems belonging to the EU Natura 2000 

network of European conservation areas. The 

construction and use of Maasvlakte 2 causes 

considerable damage to existing Natura 2000 sites. 

According to EU regulations, this damage should be 

compensated by creating new nature. In the case of 

Rotterdam, the compensation was twofold: a marine 

and a terrestrial part. The paper describes the design 

and the actual lay-out of the compensation works. It 

also reports on the monitoring that is ongoing to 

assess the damage to existing nature and the quality 

of the new (compensated) nature. 

 

Keywords - port extension, environmental damage 

and compensation, EU Natura 2000, building with 

nature. 

 

I. INTRODUCTION 

 

The Dutch government decided in 2003 to develop a 

policy which enabled a new harbour extension (called 

Maasvlakte 2), in order to receive and handle the 

world's largest containerships, starting from 2015. 

Maasvlakte 2 (net 1000 ha, which is 20% of the 

already existing harbour area) was build between 

2008 and 2014 by reclaiming part of the North Sea 

with foreshore nourishment (365 Mm3). It is expected 

that the new harbour will be in full operation by 2030. 

 

Maasvlakte 2 extends in the middle of an 

environment with valuable coastal and marine 

ecosystems. They are under protection of the EU-

Natura 2000 network. In such a case, EU-regulations 

state that construction is only allowed when there are 

imperative reasons of overriding public interest to 

carry out the plan, when there is no alternative, and 

when the submitter of the plan commits himself to 

compensate for the damage it causes. It concerns the 

environmental damage to Natura 2000 sites that will 

be caused by the new harbour and its activities.  

 

It is important to understand that the compensation 

activities should start at the same time and parallel 

with the activities for the new harbour, and not, if at 

all, afterwards. 

To convince possible opponents it was decided by 

the EU-permits to start with the compensation 

measures before or at least at the moment of 

beginning the extension. 

Compensation is realized at other locations nearby 

the port extension (Figure 1). It involves marine 

ecosystems (fish, sea bottom fauna and bird 

communities) as well as land ecosystems (beach and 

dune ecosystems). 

 

Marine compensation is necessary because the new 

harbour was reclaimed from the sea, causing loss of 

habitats and foraging areas. Beach and dune 

compensation was necessary because the EIA 

predicted that important existing dune ecosystems 

nearby will be damaged by the use of the new 

harbour (extra air pollution by more harbour traffic). In 

order to assess whether the predicted environmental 

damage indeed will occur and whether, in the future, 

the quality of the new nature indeed will compensate 

for this damage, an extensive monitoring program is 

running.  

 

The case of Rotterdam is of importance to mirror with 

harbour development worldwide to achieve innovative 

smart solutions in a more sustainable way. Key 

concepts are compensation of irreversible damage to 

nature and building with nature. 

 

 

 

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Fig .1. The Netherlands (inset) and part of the south western Delta 

coast of the North Sea. In the middle the new harbour extension 

(Maasvlakte 2) in outline. The dunes of Voorne's Duin, 

Kapittelduinen and Solleveld are nearby Natura 2000 areas that will 

suffer expected environmental damage.  Spanjaards Duin, in the 

north, is the new dune and beach compensation area. In the south 

in the Voordelta (a shallow sea in front of the coast, also a Natura 

2000 area) is the area where marine compensation measures are 

taking place (yellow boundary). Image: Google Earth.. 

 

II. METHODOLOGY 
 

Monitoring of the compensation was done using the 

latest techniques. In the case of dune compensation: 

terrain morphology (GPS transects and laser 

altimetry), groundwater (piezometers and chemical 

analyses), vegetation (vegetation samples and 

individual species records) and in the case of marine 

compensation: sea bottom fauna, hyperbenthos and 

fish, countings of indicator sea birds, countings of 

trawl activities, and countings of water recreation 

activities.  
 

For both compensation activities a special monitoring 

scheme was developed. This contains main 

evaluation questions with factsheets per question. 

Each factsheet contains sub questions, the kind of 

information required to answer the sub question and 

the strategy needed to acquire this information 8  
 

 EU Natura 2000 
 

Natura 2000 is a network of specially protected 

areas, both on land and sea, in the 28 member states 

of the EU, meeting the requirements of the EU-

Habitat Directive. It is the largest coordinated network 

of protected areas in the world. 
 

When Natura 2000 sites are predicted to be damaged 

by construction of a project, and the project is of 

outstanding national economic importance 

("imperative reason of overriding public interest, 

without a proper alternative"), the damage needs to 

be compensated (article 6.3 and 6.4 of the EU-

Habitat Directive)(ec.europe.eu/environment/nature2000). 
 

III. DUNE COMPENSATION 
 

(project being carried out with dr Bert van der Valk, 

Deltares, Delft, The Netherlands) 

 

 Damage to existing dunes and compensation 

targets 
 

The EIA1 for the extension of Maasvlakte 2 predicted 

that the use of the new harbour would damage 

important dune ecosystems in the nearby existing 

dunes. These ecosystems belong to the EU Natura 

2000 network and, under European Habitat Directive 

regulations, have to be compensated. They are: H 

2190 (nutrient poor calcareous moist dune valleys, 

or dune slacks) and H 2130 (nutrient poor, more or 

less calcareous dry dunes, so-called "Grey dunes") 2 
 

In the European context, The Netherlands have a 

special requirement when it comes to maintaining 

the surface and improving the quality of these 

nutrient poor (N, P) dune environments. The 

predicted damage in existing dunes and the 

compensation targets in the new dunes are given in 

Table 1. 
 

Table 1. Dune Compensation Targets in New Constructed Dunes of 

Spanjaards Duin in Relation to Predicted Losses in Existing Natura 2000 

Dunes. See also Figure 2. 
 

Dune compensation 
targets 

loss (ha) 
compensate  

(ha) 

Moist dune valley (H 2190) 1,3 6,5     (x5) 

Grey dune (H2130) 4,2 9,6     (x2) 

Species: Fen orchid Liparis 
loeselii 

1 
population 

1 population 

Loss of nutrient poor 
habitats 

 
Compensate 
nutrient poor 

habitats 

 

The damage to these ecosystems occurs because 

the use of the new harbour will cause an increase in 

traffic and industrial activities. This will raise the level 

of NOx emissions. The extra airborne N-load will 

affect the nutrient household of the nutrient poor 

dune ecosystems. The higher nutrient level will 

cause some common plant species to encroach and 

take over the space of several rare plants that are 



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characteristic of H2190 and H2130. 

 

 Dune compensation and nourishment 
 

In order to compensate for this loss, a new dune 

and beach area was constructed by beach and 

foreshore nourishment. The work was done in 2008 

in combination with a larger regular nourishment 

works along the Dutch Delfland coast. The new 

area covers 35ha and involves 6,5 x 10million  m3 

of sand. 
 

The nourishment was done by dredging the sand 

some 19km offshore and piping it onshore from a 

close-by connection point (Figure 1). Subsequent 

shovel work formed the basic shape according to its 

design (Fig 2): an elevated (5-7m above MSL) dry 

and undulating ridge, the new frontal dune, and a flat 

depression (ca. 2.5m above MSL) or dune valley, 

later to become moist due to rising fresh 

groundwater level. Because of sand mobility (see 

paragraph below), part of the nourished material had 

to have a specific grain size (180-250μ), which is 

slightly smaller than the average sea bottom 

sediment in front of the coast. However, earlier 

surveys showed that there was enough material 

present in the neighbourhood. 
 

 

 

 

 

Fig .2. Top left: construction of the compensation area in front of the existing coastal fore dunes (at right) by 

beach and foreshore nourishment. The contours of the designed elongated moist dune valley, a flat 

depression, are already visible in the middle (photograph courtesy Nico Bootsma, Rijkswaterstaat). Top right: 

design of the new dune area in front of the Delfland coast. Grey=existing dune, yellow=new beach, 

orange=new dry dune, green=new moist dune valley. From Veeken et al.3 Bottom: compensation targets grey 

dune (left) and moist dune valley (right). The Fen orchid occurs in the latter. 
 

 

 Dune compensation and building with nature 

 

Building with nature is a technique that is being used 

more and more when constructing, restoring or 

reshaping landscapes, also at the coast. Applying 

this technique means that the characteristics and 

spontaneous forces, materials and elements of the 

local environment are used as much as possible 4. 

For example, to strengthen a sandy coast with sand 

nourishment and not with hard materials like 

concrete or basalt, can be considered building with 

nature. In the case of the compensation area, 

building with nature was applied 4, 5. 

 

 Phases of new dune development 
 

The ecosystems that have to be compensated take 

time to develop. Grey dunes take 15-20 years. A 

moist dune valley about five years (partly because 

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of settlement of the appropriate groundwater 

dynamics and quality).  The development of the 

area was foreseen in four phases (Table 2) and 

started from the design (Figure 2).  Some phases 

run successively, like the development of the  

abiotic habitat conditions first, followed by the biotic 

elements.  
 

First the basic foundation was laid out by sand 

nourishment. After this basic foundation, free 

movement of sand and spontaneous sand transport 

(erosion and accumulation by wind) were allowed 

to take place. This causes some remodelling of the 

basic shape and also the formation of appropriate 

Aeolian initial dune soils, the appropriate condition 

for colonisation and growth of vegetation. During 

this phase, the salt/brackish sand material has 

gradually been desalinated by precipitation; and 

consequently a fresh groundwater lens will develop 

in the subsoil, also fed by infiltration of freshwater 

from the (thin row of) mainland dunes (Fig 2, right).  

After some time (expected 4-6 years in this case), 

the phreatic level of this lens will rise up to the 

valley floor, creating habitat requirements for a 

moist dune valley, and, eventually, moist dune 

slack vegetation (H2190).  Because of sand 

mobility, part of the nourished material had to have 

a specific grain size (180-250μ), which is slightly 

smaller than the average sea bottom sediment in 

front of the coast. 
 

Table 2. Phases of Dune Development and Building with Nature 
 

Phases of 
development 

 

Natural elements 
and  processes involved 

Construct basic 
foundation 

Sand that is characteristic of 
the region 

Remodelling of sand 
by wind transport 

Development of 
appropriate 

groundwater dynamics 
and quality 

Building of natural dunes and 
valleys by erosion and 

accumulation 

Desalinisation of sand by 
precipitation 

Successive 
colonisation of plants 
and development of 
plant (and animal) 

communities 

Allow spontaneous, natural 
colonisation, no active, deliberate 

planting of dune species 

Management to steer if 
needed 

Aim at compensation targets 

 

 

 Monitoring 
 

In order to assess whether the dune area develops in 

the right direction of the target habitats, a monitoring 

program was established. It concerns dune 

geomorphology, groundwater and vegetation. Also, 

there are monitoring activities in the existing dunes 

especially concerning their nutrient (N,P) status.  

 

 Overall results 
 

About seven years after construction, the area is still 

very dynamic (Figure 3). Vegetation is scarce. 

However, the abiotic conditions for the development 

of the compensation targets, the nutrient poor dune 

grasslands, are nearly in place. Signs of the 

development towards grey dunes can be seen. The 

area functions in a number of ways: for coastal 

defence, nature conservation and also recreation. In 

the densely populated environs of Rotterdam harbour 

in the Dutch Delta, this is regarded as a very positive 

situation. To ensure that nature development can 

take place, free access is not allowed. The new area 

is already under Natura 2000 protection.  

 

 
 

Fig .3. The new area development of Spanjaards Duin (2013). 

Wind activity is clearly visible. Former (existing) coastal fore 

dunes are to the left. New embryo dunes formed by wind and 

sand captured by Marram grass are  in the middle. Prospective 

wet dune valley and new fore dune ridge are to the right. Harbour 

of Rotterdam (Maasvlakte 1) is in background. North Sea is (just 

visible) to the right. 

 

IV. MARINE COMPENSATION 
 

 Damage and compensation targets 
 

Maasvlakte 2 was reclaimed from the sea, in this case 

the Voordelta, a shallow marine environment of high 

nature value, belonging to the EU Natura 2000 

network (H1110, shallow seas with sand flats 

permanently inundated and tidal inundations). 



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 Maasvlakte 2 has taken away 2,000ha of sea. Rather 

than creating more new sea, it was decided to 

improve the quality of existing waters nearby in the 

Voordelta with ca 10%. Besides the loss of sea 

environment and sea (bottom) fauna (fish, benthos), 

there was also an expected damage to resting and 

foraging areas of seabirds (common scoter, sandwich 

tern, and common tern). These birds are most 

sensitive to disturbance in their habitats. In time after 

the construction of Maasvlakte 2, it was expected that 

currents will create a sea bottom pit (near the sea 

defense wall surrounding the harbour) of 500 ha, 

which also needs to be compensated. 

 

The following marine compensation targets were set: 

(i) create a marine protection area of 2,500x10 = 

25,000ha in the Voordelta and within the protected 

area, and (ii) establish resting places for the three 

most sensitive seabird species, common scoter, 

sandwich tern and common tern (Figure 4) (Table 3). 

 

 

 

 

     

Fig .4 Top: Marine compensation in the Voordelta (orange boundaries) and the marine protection area (red) and the resting areas for 

seabirds (yellow). Bottom: from left to right common scoter, sandwich tern and common tern. 
 

Table 3. Marine Damage and Compensation Targets. See Figure 4. 
 

Damage Compensation target 

2,500ha sea(bottom) lost  
Establish 25,000ha marine protection area to restore sea bottom 
(communities) and fish. 

Resting and foraging places for seabirds lost 
Create new resting places within protection area to restore sea bird 
populations 

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 Compensation measures and monitoring 6 ,7 
 

In the protection area bottom trawling with vessels 

>260 hp were stopped. It was expected that this 

would improve the numbers of fish and of sea bottom 

fauna. And that this would favor the bird numbers 

because of an increase in food source. In the resting 

areas all human activity was banned. 

 

Monitoring was set up to see whether the predicted 

damage could be sufficiently compensated. The 

monitoring concentrated on (i) benthos (sea bottom 

fauna), (ii) birds, (iii) fish, (iv) abiotics and (iv) human 

use of the area. The first phase (T1) of the monitoring 

period was from 2009-2013. Before this, a T0 period 

was monitored between 2004 and 2007. During T1 the 

reference area was the Voordelta area outside the 

protection area. 

 

 Monitoring results 
 

The following results have been obtained after four 

years of measuring. (i). It was not possible to find a 

significant correlation between the stopping of 

fisheries activities and trends in the sea bottom. One 

possible reason for this is that already in 2004 

fisheries activities were reduced by 80%. (ii) It was not 

possible to find a significant correlation between 

numbers of the three bird species (and their spatial 

distribution) and the establishment of new resting 

places. These results are valid for comparison of the 

compensation areas both with the reference area and 

with the T0.  
 

As a consequence, at the moment a clear sign that 

the damage to the marine environment is sufficiently 

compensated cannot yet be seen. 
 

 

V. DISCUSSION 
 

There are several factors that can play a role to 

explain the results in the Voordelta. Since the closing 

of the large sea inlets in this Delta area (1960-70ies) 

as part of the Dutch Delta Plan, this area has not yet 

reached its new equilibrium. Because of this and by 

the nature of the environment itself, the area has a 

high degree of hydrodynamics. There are great 

autonomous spatial and temporal changes in abiotic 

conditions of water and soil. These may cause 

differences in benthos and fish per time lap, which are 

larger than the consecutive monitoring differences. 

 

Also, the data on numbers of birds and their spatial 

distribution show large differences between the years, 

larger than those between the compensation and the 

reference. In this case, also the monitoring period 

(four years) is too short to detect significant effects.  

 

Another important factor is that birds and fish do not 

stay in the same protected area and reference area. 

They move to other areas and (may) come back. So, 

their population dynamics is influenced, not only by 

ecosystem changes in the area itself, but also in other 

areas (far away). Thus, it is difficult to attribute 

changes only to the compensation measures in the 

marine protected area. 

 

Finally, monitoring is being done not only to assess 

whether the compensation is going to be sufficient, 

but also to understand more about the relationship 

between the various elements (birds, fish, benthos, 

nutrients, and water conditions) in this marine 

ecosystem.   
 

 The monitoring will continue for at least another 4-

year period. This will give more insight in the 

ecosystems itself (life strategies, carrying capacity, 

food chains, and resilience). It is expected that new 

answers can be given to evaluate the compensation 

efforts. 
 

VI. CONCLUSIONS 

 

Large-scale technical activities for harbour extension 

always damage coastal nature. The EU compensation 

principle can contribute to restoration and new nature 

development and to more sustainable overall coastal 

solutions. Key concepts are compensation and 

building with nature. 

 

Success of a project like this depends on a 

multidisciplinary cooperation and patience. Close 

cooperation between civil engineers, policy makers 

and ecologists is necessary. 

 

Time should be given to nature to develop itself. This 

time is often longer that politicians can wait. Area 

protection is necessary to allow for undisturbed 

developments of new nature. 

 

The case of Rotterdam harbour is of importance to 

mirror with harbour development worldwide. It is a 

case that considers, at the same time and right from 

the beginning, economic development and ecological 

quality. 

 



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VII. ACKNOWLEDGEMENTS 

 

Mr Gerard van der Kolff and Mr Theo Prins (Deltares, 

Delft, The Netherlands), project leaders of the Marine 

compensation project, supplied literature and data on 

their project. This help is kindly acknowledged.  

 

REFERENCES 
 

 

[1] Roal Haskoning Nederland.  Milieu-

effectrapportage (EIA) en strategische 

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opdracht van Projectorganisatie Maasvlakte 2. 

Port of Rotterdam. In Dutch. 

 

[2] F. Meulen,  B. van der,  van der Valk, K., 

Vertegaal and M. Van Eerden. "Building with 

nature' at the Dutch dune coast: compensation 

target management in Spanjaards Duin at EU 

and regional policy levels." J Coast Conserv., 

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[3] L. Veeken, J. ter Hoeven  and J. Fiselier . 

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