Case study:Upper River Nairn restoration project: Difference between revisions

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Three different design strategies were proposed in discrete sections of the site. Due to practical site constraints, the design in the upstream sections of the site could only involve the localised reprofiling of the river corridor (mainly the removal/ re-grading of existing embankments) while, in the downstream section, channel realignment and the reinstatement of ‘online’ wetlands were implemented. Almost 1 km of channel length was realigned into a more sinuous course through a lower elevation area. Importantly, this connected a series of three online wetland areas before tying back into the existing channel course downstream. Furthermore, to mitigate the lack of large wood (LW) processes through the site, riparian planting was conducted in conjunction with the installation of ‘bar apex’ LW structures at appropriate locations through the realigned channel.
Three different design strategies were proposed in discrete sections of the site. Due to practical site constraints, the design in the upstream sections of the site could only involve the localised reprofiling of the river corridor (mainly the removal/ re-grading of existing embankments) while, in the downstream section, channel realignment and the reinstatement of ‘online’ wetlands were implemented. Almost 1 km of channel length was realigned into a more sinuous course through a lower elevation area. Importantly, this connected a series of three online wetland areas before tying back into the existing channel course downstream. Furthermore, to mitigate the lack of large wood (LW) processes through the site, riparian planting was conducted in conjunction with the installation of ‘bar apex’ LW structures at appropriate locations through the realigned channel.


accumulation (and associated channel ‘perching’), flooding/ land drainage and reduced habitat quality, improving the WFD classification status of the River Nairn was also a key objective of the Project. Currently, the waterbody (River Farnack confluence to source in the River Nairn catchment, Waterbody 20306) has been classified by SEPA as being at poor status, primarily as a result of morphological and hydrogeomorpholocial pressures on the waterbody resulting from modifications to the bed and banks of the river. Through the River Basin Management Planning Strategy, SEPA has identified and prioritised water bodies where improvements are required to enable good ecological status to be met.  As part of the second cycle of the River Basin Management Planning Process, SEPA has identified the River Nairn as a priority catchment and as part of a national strategic plan, the URNRP will help national objectives to be met.
Whilst the primary objectives of the restoration project were to address the issues of excess sediment accumulation (and associated channel ‘perching’), flooding/ land drainage and reduced habitat quality, improving the WFD classification status of the River Nairn was also a key objective of the Project. Currently, the waterbody (River Farnack confluence to source in the River Nairn catchment, Waterbody 20306) has been classified by SEPA as being at poor status, primarily as a result of morphological and hydrogeomorpholocial pressures on the waterbody resulting from modifications to the bed and banks of the river. Through the River Basin Management Planning Strategy, SEPA has identified and prioritised water bodies where improvements are required to enable good ecological status to be met.  As part of the second cycle of the River Basin Management Planning Process, SEPA has identified the River Nairn as a priority catchment and as part of a national strategic plan, the URNRP will help national objectives to be met.
|Monitoring surveys and results=Post works monitoring is essential for evaluating the physical and ecological performance of the project.  Given the near unique scale of application of the ‘process-based’ restoration approach, the project provided an invaluable opportunity to monitor how the river environment responds to the various components of the implemented works, providing valuable insight and guidance for the application of this type of approach in other areas.
|Monitoring surveys and results=Post works monitoring is essential for evaluating the physical and ecological performance of the project.  Given the near unique scale of application of the ‘process-based’ restoration approach, the project provided an invaluable opportunity to monitor how the river environment responds to the various components of the implemented works, providing valuable insight and guidance for the application of this type of approach in other areas.


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|Caption=Aberarder Upper Wetland
|Caption=Aberarder - Upper Wetland
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|File name=Aberarder redd distributions 2017 and 2018.pdf
|File name=Aberarder redd distributions 2017 and 2018.pdf
|Description=Aberarder redd distributions 2017 and 2018
|Description=Location of salmonid redds surveyed in 2017 and 2018 spawning seasons
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|File name=Aberarder wetland enhancement.pdf
|File name=Aberarder wetland enhancement.pdf
|Description=Aberarder wetland enhancement
|Description=Aberarder wetland enhancement
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|File name=Aberarder study site & restoration overview.pdf
|Description=Aberarder study & restoration overview
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|File name=Aberarder redd counts.mp4
|Description=Location of salmonid redds
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Latest revision as of 10:39, 25 March 2019

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Location: 57° 18' 0.85" N, 4° 16' 53.02" W
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Project overview

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Status Complete
Project web site
Themes Environmental flows and water resources, Fisheries, Flood risk management, Habitat and biodiversity, Hydromorphology, Land use management - agriculture, Land use management - forestry, Monitoring
Country Scotland
Main contact forename Euan
Main contact surname Anderson
Main contact user ID User:Aberarder
Contact organisation Aberarder Estate
Contact organisation web site
Partner organisations
Parent multi-site project
This is a parent project
encompassing the following
projects
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Project summary

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The site is located on the upper River Nairn, just west of the settlement of Croachy. The study section is 4 km long, extending upstream to where the channel exits from its steep headwater zone. The gradient of the channel generally decreases as it transitions into a floodplain zone, currently managed for agriculture. Under natural conditions, the study site was a highly dynamic alluvial fan with multiple channels. However, because of historical engineering for land management, natural physical processes in this part of the upper Nairn were significantly altered. The channel had been straightened and constrained between embankments, becoming ‘perched’ above its floodplain due to aggradation of its bed. The river corridor lacked the physical features and associated habitats that would naturally occur, mainly through the lack of morphological variability but also limited tree cover and large wood material in the active channel. As a result, the water body was classified at poor ecological status under EU Water Framework Directive (WFD) classifications.

Following a ‘process-based’ approach, an ‘assisted recovery’ design strategy was adopted, permitting the river to self-adjust towards a quasi-stable ‘dynamic equilibrium’ morphological condition. The aim was to reinstate a greater potential for the development of lateral channel variability (through the evolution of alluvial bar forms and associated bank erosion processes) and connectivity with wetland/ floodplain environments. Initially a series of conceptual design were developed from which, after stakeholder engagement, a preferred option was identified. A detailed design phase then followed, supported by high-resolution 2D hydrodynamic and morphodynamic (i.e. sediment transport) modelling. An iterative modelling-design process determined the optimal restoration approach for the different river sections.

Three different design strategies were proposed in discrete sections of the site. Due to practical site constraints, the design in the upstream sections of the site could only involve the localised reprofiling of the river corridor (mainly the removal/ re-grading of existing embankments) while, in the downstream section, channel realignment and the reinstatement of ‘online’ wetlands were implemented. Almost 1 km of channel length was realigned into a more sinuous course through a lower elevation area. Importantly, this connected a series of three online wetland areas before tying back into the existing channel course downstream. Furthermore, to mitigate the lack of large wood (LW) processes through the site, riparian planting was conducted in conjunction with the installation of ‘bar apex’ LW structures at appropriate locations through the realigned channel.

Whilst the primary objectives of the restoration project were to address the issues of excess sediment accumulation (and associated channel ‘perching’), flooding/ land drainage and reduced habitat quality, improving the WFD classification status of the River Nairn was also a key objective of the Project. Currently, the waterbody (River Farnack confluence to source in the River Nairn catchment, Waterbody 20306) has been classified by SEPA as being at poor status, primarily as a result of morphological and hydrogeomorpholocial pressures on the waterbody resulting from modifications to the bed and banks of the river. Through the River Basin Management Planning Strategy, SEPA has identified and prioritised water bodies where improvements are required to enable good ecological status to be met. As part of the second cycle of the River Basin Management Planning Process, SEPA has identified the River Nairn as a priority catchment and as part of a national strategic plan, the URNRP will help national objectives to be met.

Monitoring surveys and results

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Post works monitoring is essential for evaluating the physical and ecological performance of the project. Given the near unique scale of application of the ‘process-based’ restoration approach, the project provided an invaluable opportunity to monitor how the river environment responds to the various components of the implemented works, providing valuable insight and guidance for the application of this type of approach in other areas.


Specific monitoring has included:

• Repeat topographic/ bathymetric surveys (immediately post-construction and subsequent to three high flow events flood events).

• Repeat sediment sampling (pre- and post- implementation)

• Repeat fixed-point photographs

• Repeat spawning surveys/ redd counts (including pre-works and the two spawning seasons post-construction)

• Repeat electro-fishing surveys (in both channel and wetland locations, pre- and post-works)


Immediately after construction, a detailed topographic and sedimentary resurvey were carried out. Further resurveys have been undertaken after significant flow events, determining rapid evolution of the site and in the trajectory intended (and predicted by modelling).

Given fish populations are a good indicator of habitat condition, repeat red counts and electro-fishing surveys have also been undertaken. Latest survey results show significant increases in spawning and juvenile salmon and trout compared to pre-restoration conditions, providing an ‘ecological validation’ the works implemented.

Lessons learnt

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The work has resulted in rapid evolution of the site to a condition of improved physical heterogeneity (in-channel and wetland areas), with associated ecological responses. This has also resulted in a general aesthetic improvement, from a very simple canalised, embanked and perched channel to one that is much more physically variable, natural-looking and connected with standing water features (i.e. wetlands). The planting of trees in the riparian zone also benefits the site in this regard.

A practical benefit of the works was the improved protection of key areas of farming land from local flood risk. This was achieved through the removal of embankments on river right, permitting greater floodplain connectivity (with associated physical/ ecological benefits) to the east/ south of the channel while reducing pressure on the opposite bank. Furthermore, the implemented works greatly improved agricultural drainage; the bed of the restored channel was over 1 m lower than the previously perched condition, meaning that field drains could flow freely where they had previously been backed-up. Although not a primary objective of the project, considering these design objectives was essential to achieving buy-in by the local farmer.

There are also more general Natural Flood Management (NFM) benefits of the project. With greater floodplain/ wetland connectivity, there is greater inundation of areas adjacent to the channel under certain flood magnitudes. The storage of water in such areas will provide an increased level of protection to downstream areas. Furthermore, the re-establishment of native woodland will also contribute to NFM, adding roughness to the floodplain (slowing flows and increasing water storage times) and increasing the interception of water (surface flow and rainfall) through slowing flows and water absorption. Through such processes, the works will provide greater resilience to the effects of climate change. This is also the case for drought conditions; the previously homogenous condition of the channel has been replaced with a much more diverse morphology (particularly considering the wetland areas) that provides far greater potential for biotic refugia. The work has generally improved the understanding of the benefits of such projects and the appropriate methods of their delivery. This has been a key case study for this type of work for SEPA and, with monitoring ongoing, dissemination of information will provide an invaluable resource to the wider river restoration community.

Given the explicit development of an integrated steering group and the associated project management approach, challenges during the project were minimised. Also, experience from previous construction projects by the design/ build team meant that many potential issues were avoided. There was careful planning of the construction phase of the project such that the most intrusive works (i.e. construction of the realigned channel and large wood implementation) were conducted ‘offline’, minimising the risk of high flow events impacting the works and fine sediment pollution. Such ‘assisted recovery’ designs explicitly require a degree of ‘field fitting’, allowing for unexpected issues encountered to be managed through appropriate short notice design variations. This was the case in the furthest downstream section of the site where, due to wet ground, it was not safe for construction machinery to excavate the initially proposed realigned channel in this area. It was therefore decided that the proposed design be modified such that the third (furthest downstream) wetland feature would be instated through this ~200 m long section, subsequently proving to be an appropriate revision. Such a short notice adjustment was only possible due to the close and established working relationship between the designer, regulator (i.e. SEPA) and contractor.


Image gallery


Aberarder - New Lower Channel
Aberarder - Upper Wetland
Aberarder - Large Wood structure
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Catchment and subcatchment



Site

Name
WFD water body codes
WFD (national) typology
WFD water body name
Pre-project morphology
Reference morphology
Desired post project morphology
Heavily modified water body
National/international site designation
Local/regional site designations
Protected species present
Invasive species present
Species of interest
Dominant hydrology
Dominant substrate
River corridor land use
Average bankfull channel width category
Average bankfull channel width (m)
Average bankfull channel depth category
Average bankfull channel depth (m)
Mean discharge category
Mean annual discharge (m3/s)
Average channel gradient category
Average channel gradient
Average unit stream power (W/m2)


Project background

Reach length directly affected (m) 24002,400 m <br />2.4 km <br />240,000 cm <br />
Project started 2014/11/20
Works started 2017/08/01
Works completed 2017/09/30
Project completed 2018/04/01
Total cost category
Total cost (k€)
Benefit to cost ratio
Funding sources Scottish Water Environment Fund (WEF)

Cost for project phases

Phase cost category cost exact (k€) Lead organisation Contact forename Contact surname
Investigation and design cbec eco-engineering UK Ltd Hamish Moir
Stakeholder engagement and communication
Works and works supervision Salix - McGowan
Post-project management and maintenance Aberarder Estate Euan Anderson
Monitoring cbec eco-engineering UK Ltd Hamish Moir



Reasons for river restoration

Mitigation of a pressure Flood risk/ channelisation, embankments
Hydromorphology Realignment, large wood, wetland reinstatement
Biology Macroinvertebrates, fish
Physico-chemical Carbon storage, nutrient storage
Other reasons for the project To restore a heavily modified section of the Upper River Nairn back to a more natural state whilst also reducing the risk of flooding to protect agricultural interests


Measures

Structural measures
Bank/bed modifications Channel realignment, embankment removal, channel reprofiling, installation of large wood structures
Floodplain / River corridor Channel realignment, channel reprofiling, reinstatement of three wetlands
Planform / Channel pattern Changing from a canalised straightened channel to a meandering/ wondering channel
Other
Non-structural measures
Management interventions Riparian tree planting, fencing
Social measures (incl. engagement)
Other


Monitoring

Hydromorphological quality elements

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative

Biological quality elements

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative

Physico-chemical quality elements

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative

Any other monitoring, e.g. social, economic

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative


Monitoring documents



Additional documents and videos


Additional links and references

Link Description

Supplementary Information

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