The objectives of this review were to:

• Review the ecosystem effects of common cord-grass
• Map the distribution and extent of common cord-grass in Ireland
• Review the options for the control and management of common cord-grass
• Develop a common cord grass control action plan that can be applied to coastal sites in Ireland

Literature review suggested that the perceived impacts of common cord-grass are often speculative. There was evidence of an impact on macrobenthos diversity, which may explain reported impacts on wading birds that feed on these organisms. There is also evidence that it can impact eelgrass Zostera beds. However, few other reported impacts had strong support and there were suggestions that common cord-grass might facilitate other species. There are also uncertainties about the relationship of sediment regimes and common cord-grass, and the potential impact of management and dieback.

Data analysis was undertaken in PostGIS. The extent of common cord-grass was determined based on the two Saltmarsh Monitoring Projects and the SAMFHIRES project. These provided excellent and up to date coverage, suggesting that the extent of common cord-grass was in the range 688 to 1,223 ha. These data combined with presence based records of the species showed that common cord-grass was widely distributed in Ireland, with records intersecting 167 out of 214 coastal sites.

The threat posed by common cord-grass to Annex I habitats was assessed. It was found to pose a substantial threat to three Annex I habitats, with particular concern for the rarest habitat considered (H1420).

Based on the literature review, a mixture of cutting, smothering, excavation and herbicide application could be used to control common cord-grass. However, this came with caveats, as some techniques, such as cutting, are unlikely to be effective on their own, and all techniques risk impacting other species and habitats in the vicinity. We therefore developed a management decision tool to help guide managers though the analysis required to determine the amount of survey and management action required for a site. This was provisionally implemented on the 167 coastal sites with records of common cord-grass to estimate the extent and costs of actions required.

Note that common cord-grass is currently subject to a degree of nomenclatural uncertainty. Formerly known as Spartina anglica, it is now considered to be a member of the genus Sporobolus, as Sporobolus anglicus. However, this change has not been universally accepted.

Further information from Claire Lush.

The aim of the project was to establish the suitability of aerial imagery taken from Unmanned Aerial Vehicles (UAV) to investigate the spatial and temporal extent of bait digging at selected sites in Wales.

Sites were flown at low tides and ortho-rectified seamless mosaics produced. Shore survey and ground truthing was also undertaken, and control holes dug to investigate the persistence of bait digging evidence on different shores. The shores were revisited to assess whether the control holes were still visible, to give an indication of the persistence of damage. The ortho-rectified imagery was used to create bait digging intensity maps on a variety of shore types.

Further information from Crispin Flower.

This project developed the iMarDIS Portal - a single point of access to data and associated metadata derived from the collaborative research carried out between MRE industries and Bangor University at Marine Centre Wales. It is a single page application (SPA) that offers a pleasant and responsive user interface on top of the wide range of data services provided by the iMarDIS Web API.

From the portal, it is straightforward to search for datasets using keywords, an intuitive query builder and geographic filtering via the map. You can visualise the results on the map, view detailed metadata and create dynamic charts to help assess the suitability of a dataset for purpose. Both raw and derived datasets can be directly downloaded in the browser. The system also supports multiple languages and includes notifications, comprehensive help, articles, and a feedback mechanism.

For more information contact Andy Brewer.

The project outputs consisted of a web interface for configuring the mapper, a modern and feature-rich web application for displaying maps, and consultancy services to JNCC in managing their database and web mapping services.

The project drew on our knowledge of managing large spatial datasets, optimising web mapping services, familiarity with marine habitat classification systems, and expertise in creating interactive web mapping applications.

The new system is currently used to display marine protected area boundaries (MPAs) in UK waters by JNCC. It is also used for a diverse set of habitat and environmental variable datasets as part of the European Marine Observation and Data Network (EMODnet).

The mapper can be configured by JNCC staff, who decide which layers should be available, which are displayed by default, and how they may be filtered. It is not restricted to marine mapping and could be configured to display any tiled web mapping services.

Users of the map can search and browse layers, view information about specific habitats by clicking on the map, zoom to areas of interest using a gazetteer, change base maps, and filter layers for specific habitats for species. A permalink system allows users to save their current view of the map and share it with others via a URL.

The mapper is easily deployed and can run as a standalone application or it can be displayed within a content management system to maintain corporate identity. The styling of the mapper itself is customisable so that it can also be themed to meet the style guidelines of the hosting organisation.

This mapper has been one of several marine mapping web applications we have created over the last few years including the United Kingdom Directory of Marine Observing Systems (UKDMOS) ArcGIS desktop application and the Integrated Marine Data and Information System (iMarDIS) https://portal.imardis.org/.

Further information from Andy Brewer.

NRW contracted Exegesis to establish a vegetation monitoring programme that would allow the development of the saltmarsh to be assessed and better understood. This involved:

• Collection of high-resolution aerial photography using out fixed-wing drone.
• The generation of an accurate height model.
• Capture of vegetation communities based on species dominance from the aerial photography and data collected in the field. The resolution of the aerial photography made sub-metre precision mapping possible.
• The selection of three transects across the main site.
• Detailed survey of a series of randomly located 2×2 metre quadrats along the transects, located using a high precision GPS.
• Photographs of transects, quadrats and features of interest.
• A full technical report detailing the methodology and results.

The report recommended repeat monitoring surveys following the same methodology and using the same quadrat locations, so that future vegetation change could be quantified and characterised.

Further information from Crispin Flower.

• Update the underlying technology, to ensure long-term viability of the website.
• Refresh the design, aligning it with the new GiGL design standards and ensuring a seamless transition from their main site (in WordPress) to the mapping site (in mojoPortal).
• Simplify the mapping interface, making it accessible to a greater number of potential users.
• Have multiple versions of the web map, each displaying different suites of data.

We started the project with a discovery phase involving ESDM managers, developers and technical architects working alongside GiGL staff. The discovery phase explored the requirements and potential solutions, culminating in the development of approved interactive mock-ups that demonstrated the new design.

The new Discover London website was developed using Agile methods and followed the mock-ups and GiGL design standards. Significant difference between the old and new websites included:

• Radical simplication of the map controls, which decluttered the map and met modern expectations for online mapping.
• Use of expandable menus to hide more complex controls and information when not in use.
• Combined place name, postcode and grid reference search functionality that was previously separate.
• Grouping data into switchable themes, providing a much simpler view on related map data. We also ensured that it was possible to link directly to or embed individual themes.
• Removing the ability to turn individual layers on and off. Instead everything can be achieved by switching between themes, which ensures no overlapping data.
• Use of a different map projection, allowing GiGL to benefit from existing mapping services such as OpenStreetMap and Bing.
• Fully responsive design, allowing interaction with the online map via mobile devices.

Exegesis are continuing to support, maintain and develop the Discover London website for GiGL.

Further information from Crispin Flower.

The dataset was based upon Ordnance Survey MasterMap data, filtered to remove features that were unlikely to be hedges and excluding built up areas as garden hedges were not being targeted. These were then reviewed on the aerial imagery and assigned to one of the following types:

• Not a hedge
• Intensively managed
• Trimmed & dense
• Overgrown
• Line of trees
• Defunct
• Newly planted
• Recently coppiced
• Recently laid
• Woodland
• Uncertain

Hedges not included in the MasterMap data were also added, leading to a dataset of 22,370 features of which 17,013 were thought to be hedges. This was all undertaken in an incredibly short timescale, with data attribution starting on the 15th and finishing on the 27th December 2016.

Further information from Crispin Flower.

Exegesis, working in partnership with NatureBureau, were contracted to undertake an EU LIFE+ supported review of S. anglica as part of Natural England's Improvement Programme for England’s Natura 2000 Sites.

S. anglica has been implicated in a number of impacts on saltmarsh habitats, including increased accretion rates, changed to erosion patterns, reductions in eelgrass Zostera beds and glasswort Salicornia communities, and reduction of areas suitable for bird feeding. We conducted a review of these impacts, which led us to conclude that the overall impact of S. anglica could not clearly be regarded as either positive or negative, as it is hard to separate the impacts caused by S. anglica from those resulting from other processes. For example, causal links between S. anglica and reduction in bird feeding areas were not identified. There is also evidence of S. anglica co-dominating with Salicornia in mixed communities where only S. anglica was known previously, possibly due to a decrease in accretion rates.

We collated recent survey data and species records to assess the extent and distribution of S. anglica. Unfortunately, due the limited coverage of recent survey data very few areas of S. anglica dominated communities could be identified, so the estimate of extent was considered to be a gross underestimate. Recommendations were made to gain a more complete knowledge of the extent of S. anglica using remote sensing and field survey. In contrast, data showing the distribution of S. anglica were more readily available than previously, allowing detailed distribution maps to be created. These showed that the distribution of S. anglica appears to have been relatively stable, having changed little since 1970.

We developed a S. anglica monitoring protocol that aimed to collect information that could be used to determine the extent of S. anglica and to help decide whether management was required. Draft survey forms were tested on sites in the Severn Estuary, Essex coast and North Northumberland Coast, following which improvements were made.

A review of S. anglica control techniques was undertaken, covering physical removal, cutting, grazing, smothering, rotoburying, treatment with herbicides and biological control. This allowed the most effective methods of controlling S. anglica to be identified, but it was noted that any control should be undertaken cautiously and based upon sound evidence, as its removal was likely to result in sediment discharge and potential impacts on designated features. A management decision flow chart was created that aims to help managers of Natura 2000 sites decide where management is most appropriate.

Read the report.

We subsequently undertook a similar review of common cord-grass in Ireland.

Further information from Claire Lush.

In order to create the indicative map we combined all relevant datasets into a single ArcGIS personal geodatabase containing over 1.8 million polygons. This geodatabase was linked to an Access database application that assessed the likely habitat based upon the reliability of each source dataset and suggested the most likely habitat for each input polygon. The assessment was made based upon an agreed rule base. Using this assessment the application generated a new personal geodatabase that incorporated the classification of each polygon by likely habitat and an indication of the reliability of the assessment. In this way we were able to incorporate all available data in the assessment of each polygon, rather than prioritising the data contained in certain datasets over others.

Click on the map to the right for a larger image.

Further information from Crispin Flower.

We were asked to produce the web mapping for this project using open source Mapserver software. There was also considerable consultancy on data handling and preparation.

The website and webmap was rebranded in September 2014 to form part of the EMODnet Seabed Habitats project.