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Lyme Bay Reefs.

Sunset corals,Leptopsammia pruvoti, growing on the Saw-tooth Ledges Reef, Lyme Bay, Southwest England. Colin Munro Photography. www.colinmunrophotography.com

This blog post about the marine life and importance of Lyme Bay Reefs has moved to my marine biology website: Marine-bio-images.com. You can read it here at:

https://www.marine-bio-images.com/blog/lyme-bay-marine-ecology/lyme-bay-reefs/

Lyme Bay, Lane’s Ground Reef: sponge species recovery and opportunities lost

Lane's Ground Reef, a circalittoral boulder reef rich in sponges and ascidians, within Lyme Bay Closed Area, Lyme Bay, southwest England. Colin Munro Photography

This blog post has now moved to my Marine Biology website, Marine-bio-images.com. It can be read at:

Lyme Bay, Lane’s Ground Reef: sponge species recovery and opportunities lost

https://www.marine-bio-images.com/blog/lyme-bay-marine-ecology/lyme-bay-lanes-ground-reef-sponge-species-recovery-and-opportunities-lost/

New gallery: Lyme Bay Reefs and Lyme Bay Seabed stock images

Along the tide-swept crest of a low limestone ledge larger filter-feeding organisms flourish. Lyme Bay Reefs, Southwest England. (C) Colin Munro Photography.

New gallery uploaded – Lyme Bay Seabed Images and Lyme Bay Reefs

A rich epifaunal turf forms on the tide-swept edge of a rocky reef, Saw-tooth ledges Reef, Lyme bay, Southwest England. Colin Munro Photography

A rich epifaunal turf forms on the tide-swept edge of a rocky reef, Saw-tooth ledges Reef, Lyme bay, Southwest England. Image No. MBI001163

I’ve started creating a dedicated gallery of stock images documenting the seabed habitats and species of Lyme Bay. This gallery will include Lyme bay Reefs, for which the Lyme Bay Closed Area was set up to protect, and will catalogue the diversity of these reefs, but will also document some of the interesting sedimentary habitats which usually fail to receive the attention they merit.  These and more Lyme Bay images can be seen here.

A sediment covered limestone boulder reef in Lyme Bay, Southwest England. The bright yellow tassled sponge Iophon hyndmani or Iophonopsis nigricans (the two species  cannot be positively differentiated underwater) can be seen in the centre of the image; (C) Colin Munro Photography

A sediment covered limestone boulder reef in Lyme Bay, Southwest England. The bright yellow tassled sponge Iophon hyndmani or Iophonopsis nigricans (the two species cannot be positively differentiated underwater) can be seen in the centre of the image. Image No. MBI001162

Along the tide-swept crest of a low limestone ledge larger filter-feeding organisms flourish.  Lyme Bay Reefs, Southwest England. (C) Colin Munro Photography.

Along the tide-swept crest of a low limestone ledge larger filter-feeding organisms flourish. Lyme Bay Reefs, Southwest England. Image No. MBI001156

A scallop, Pecten maximus, swim away from a perceived threat. Gravel waves, Lyme Bay, Southwest England. (C) Colin Munro Photography

A scallop, Pecten maximus, swim away from a perceived threat. Gravel waves, Lyme Bay, Southwest England. Image No. MBI001173

All the images in this blog are available to license. To view a gallery (license images or purchase prints of) these, and more of my Lyme Bay seabed images go here. Alternatively you can search all my online stock images at my www.colinmunro.photoshelter.com site through the search box (top right) here or on my main website here. Lyme Bay Reefs images, Lyme Bay seabed images, stock images.

 

Lyme Bay, what makes it special?

Lyme Bay, what makes it special?

I’ve published about Lyme Bay marine biological monitoring on my marine-bio-images blog   here and earlier on this blog here, looking at the monitoring of Lyme Bay Closed Area, a Marine protected Area success? Parts 1 and 2 describe the impacts mobile fishing gear, in particular scallop dredging, had been having on the reefs since at least the late 1980s. I describe the impacts of scallop dredging in detail here. I will look soon at the actual monitoring that has taken place since the closed area came in to being in 2008, but before doing so it is probably worth devoting a couple of blogs to describe why Lyme Bay is important and worth protecting; just what makes it special.

What Lyme Bay is not

In seeking to justify protection for the reefs and ‘sell’ the area to the wider public, the concepts of ‘coral gardens’ and ‘charismatic species’ has often been pushed.  Such poetic language may well raise the area’s profile and engender support in the short term, but it has lead to some fairly profound misunderstandings – including within NGOs and Government Agencies – about the bay and the reasons the reefs within are important.

A sediment covered limestone reef in Lyme Bay, Southwest England showing the profusion of sediment tolerant species that grow on such reefs. Colin Munro Photography.

A sediment covered limestone reef in Lyme Bay, Southwest England showing the profusion of sediment tolerant species that grow on such reefs. Image No. MBI001261.

Most of Lyme bay is not visually spectacular, there are few dramatic underwater rock cliffs painted with a riot of colour; nor is it beautiful clear water offering panoramic vistas across the seabed.  The reefs in Lyme bay are mostly low lying and the waters tend to be fairly gloomy and turbid.  As this is essentially a large, open, sandy bay exposed to the prevailing winds, then significant amounts of suspended sediment (at least near-shore, close to the seabed) are the norm.  Whilst winds may ease in summer, it is also prone to strong plankton blooms during May and June, with a second less pronounced bloom in late summer.  Thus underwater visibility rarely exceeds 10 metres (30ft) and frequently may be less than 3 metres (10ft).  The reefs in the bay, though numerous in the centre and east, are mostly discontinuous, forming a patchwork of low rocky outcrops surrounded by sediment.  This means that they tend to be covered by thin veneers of sediment as tide and wave action lifts and sweeps saltating sand across them.  The amount of sand will vary, depending on the size of the reef area, how high the reef rises above the surrounding sediment plain, the strength of tidal streams in that part of the bay and how strong the wind has been recently (and thus how big the waves).  This makes it a rather challenging environment both the underwater photographer and scientist attempting to record visual data.  Low light levels and high levels of suspended sediment producing lots of backscatter from lights making for tricky problems in producing good images.

An area of sediment covered boulder reef, Lyme Bay. The large white sea squirt Phallusia mammillata, and the blue-grey colonial sea squirt Diplosoma spongiforme, both characteristic of Lyme Bay, can be seen in this image. Image No. MBI001264. Colin Munro Photography

An area of sediment covered boulder reef, Lyme Bay. The large white sea squirt Phallusia mammillata, and the blue-grey colonial sea squirt Diplosoma spongiforme, both characteristic of Lyme Bay, can be seen in this image. Image No. MBI001264.

The species that make Lyme Bay different and the effects of the Closed Area

The flip side of this is that the communities on these reefs tend to be rather different from those inhabiting areas with perhaps more visually spectacular ‘clean’ reefs further west.  Species that tolerate a degree of sand and silt cover do well here.  A good example of this is the sponge Adreus fascicularis, a species found almost exclusively on silt-covered horizontal bedrock  Considered rare in UK waters, it is relatively common  on the reefs of Lyme Bay.  Similarly the large solitary sea squirt Phallusia mamillata.  A very distinctive species, the largest sea squirt found around British coasts its striking white colour stands out against the dull sediment.  More associated with silty, sheltered harbours and estuaries it is uncommon or rare on open coasts along the rest of its UK range, but quite abundant within Lyme Bay.  So the factors that make this a difficult environment in which to capture appealing images or gather data on the marine life in quite a significant contribute to Lyme Bay being an interesting and unusual environment. There are other species common here that we simply do not known enough about their ecology to say why they are more abundant in Lyme bay than elsewhere; a good example of this is the colonial sea squirt Diplosoma spongiforme. Though not rare elsewhere, it is abundant in Lyme Bay, forming mats, growing over rocks, seafans and other sponges. Similarly the tassled yellow sponge Iophon hyndmani/Iophonopsis nigricans (the two species are grouped together as very difficult to tell apart underwater) is particularly abundant in Lyme Bay. Indeed the sponge assemblages are frequently very rich and diverse on Lyme Bay reefs; for some reefs such as the boulder reefs (for example Lane’s Ground Reef in the central part of Lyme Bay) they are probably the most obvious characteristic of the reef and may well be the most diverse groups within the reef community there. Unfortunately they are still very poorly described (in part because sponge taxonomy is a difficult subject with field characteristics often not being sufficient for positive identification) and so are certainly under-reported and thus frequently undervalued in terms of the Bay’s conservation value. Yet sponges, being soft tissued and quite often slow-growing species, are amongst the most vulnerable to damage and eradication from areas of reef by mobile fishing gear. Indeed the sharp decline in sponge species occurring on Lane’s Ground Reef between 1995 and 2008 (clearly visible for video footage and still images taken by myself during this time period) was one of the most obvious and disturbing changes in the years before statutory protection from bottom-towed mobile fishing was established for central Lyme Bay.

Boulder reef, Lyme Bay.  The amount of suspended sediment in the water can be clearly seen.  The yellow tassled sponge Iophon hyndmani or Iophonopsis nigricans can be seen in the centre of the image, however the lack of sponges (and other attached life) compared to previous years is clear. Image No. MBI001267

Boulder reef, Lyme Bay. The amount of suspended sediment in the water can be clearly seen. The yellow tassled sponge Iophon hyndmani or Iophonopsis nigricans can be seen in the centre of the image, however it can be seen that many of the boulders are now (2010) bare of sponges and other attached life. Image No. MBI001267

Has there been a recovery of sponge species since the Closed Area was established in 2008? Our study (running from 2008-2010, when funding from Natural England ended) suggested that sponge recovery was beginning. Three years is too short a time in which to expect marked changes in such communities. It would also be foolish to read much in this data, three annual surveys (i.e. data being collected once a year for three years) represent only three data points. There will obviously be good years and bad years, plus a degree of error in any data collected, so a line drawn from three data points must come with huge caveats. Nevertheless, this slight improvement was noticeable. We are hopeful that we will be able to re-start our monitoring programme, albeit in a slightly reduced form, on a voluntary basis in 2013. It will be exciting to see what effects the Closed Area has had on the reef communities after five years.

More information about Lyme Bay, in particular the impacts of scallop dredging and the protected Closed Area, can be found on my marine biology blog www.marine-bio-images.com/blog, and on the marine-bio-images website where numerous reports on the research we have conducted here can be found.

All text and images in this blog copyright Colin Munro 2012.  All images are available to license.    Alternatively you can search all my online stock images at my www.colinmunroimages.com  site through the search box (top right) or on my main website here.

Lyme Bay Marine Protected Area: How effective is it? update

Lyme Bay Marine Protected Area: How effective is it? update

Five days ago the skipper/owner of a Brixham based trawler/scallop dredger, the Kelly Marina II (BM454) was convicted and fined for using towed bottom-fishing gear (apparently scallop dredges) within Lyme Bay Closed Area, a 60 nautical mile exclusion zone for such gear.  This Closed Area was established for conservation reasons (the first and so far only one established for such reasons in U.K. waters), specifically the rocky reefs that occur in the Bay and their associated fauna.  So, given the high profile of this recently established protected area, (widely regarded as a flagship protect and a test area for such marine pretected areas in UK waters), and given the long and protracted process (18 years between concerns being years and statutory protection finally arriving) of establishing this Closed Area, then no doubt the authorities would be keen to show that this is not just the ‘same old routine’.  One imagines they would be keen to show that this was a step change and that they were no serious about conservation.  Given also that it is quite impossible to adequately police such an area then one images that stiff punative fines would be the order of the day to send out a clear message concerning the risks if you get caught breaking the rules.  The difficulty in policing was clearly demonstrated by the fact the evidence of this vessel’s transgression was captured by a Dorset Police helicopter seconded from the Air Surveillence Unit.  One immediately wonders how often this happens when police helicopters are not around.  So, given these factors there would obviously have been a very stiff fine….er no.  The fine was £1000, plus £3000 costs and £15 victim surcharge (what?).  So a grand total of £4015; that’s just a few good days earnings for such a vessel.  now imagine a house burglar stealing televisions.  Let’s say each is worth £150 resale value.  He only does this occasionally, so manages to nick five a month on average; not bad:£750 easily earned.  Then he get’s caught, Damn! But not to worry, his fine is only 350 quid, he’s still £400 in pocket.  Not much of a deterrent is it?  Nor does it send a great message to the majority of fishermen who are abiding by the rules and incurring greater costs by having to steam further to fish outside the Closed Area (thus greater fuel costs, longer steaming time and so shorter fishing times).  The fine was imposed by Weymouth Magistrate’s Court.  You can read further details on the marine management website here.

Lyme Bay Closed Area, a Marine Protected Area success? Part 2.

Lyme Bay Closed Area, a Marine Protected Area success? Part 2.

This post follows on from Lyme Bay Closed Area, a Marine Protected Area success? Part 1, which described the damage first noted on rocky reefs in Lyme bay, Southwest England, from scallop dredging during the 1990s. This post describes the voluntary agreements set up and the ongoing problems.
As described in Part 1, the condition of the reefs in Lyme Bay had begun to deteriorate markedly by the early 1990s, and this deterioration continued more or less unchecked over the next 12 or 13 years. It would however, be wrong to suggest that all reefs were suffering equally or that nothing was happening to change this situation. Some reefs were simply too rugged for any sort of mobile fishing gear to ever be towed across them, however even they suffered from degradation around the edges. Others that were more easily worked were devastated.

The Devon Wildlife Trust had been working hard with local fishermen since the early 1990s, and voluntary agreements had been set up voluntary agreements whereby trawlers and scallop dredgers would not work in the most fragile reef habitats. The first such agreement extended voluntary protection to two reefs (known locally as Lane’s Ground, a boulder reef rich in sponges, and The Saw-Tooth Ledges, a series of limestone ledges supporting abundant seafans, soft corals and sponges). Two additional reefs were added to this agreement in 2006, The East Tennants Reef, a boulder reef supporting high densities of large seafans, and Beer Home Ground, a reef of ledges and rocky promentories composed of softer mudtstone and sandstone amongst harder limestone that had suffered quite badly from reef erosion through the action of scallop dredges. However problems remained. The first was that however sincere most local fishermen were, there was always the problem that some from further afield would see no need to abide by this agreement and, it has to be said, not all local fishermen agreed with the closure. It only took one vessel operating within the voluntary closures, maybe late at night or early morning when they were unlikley to be spotted, to cause damage that would last for years. The second problem was that the four voluntary areas were small and in no way enclosed all of even the most vulnerable reefs. An example of this is the West Tennants Reef. This is an very extensive reef in Lyme Bay terms. It is a low limestone ledge, or series of ledges, that runs parallel to the shore, about 4 miles offshore and roughly 29 metres below sea level. Although only around 10-30 metres wide over much of its length, it runs east-west for over two miles. The ledge is fairly level and free of rocky protrusions, and drops less than a metre to the surrounding seabed, thus it was very easily worked from the top of the ledge, dredges running along, parallel to the edge before eventually dropping of the edge. Strong currents sweep along this ledge, and in the early 1990s a dense band of very large seafans grew along this ledge, along with significant numbers of large axinellid sponges.

Large Axinellid sponge (Axinella dissimilis) and seafans. Most of the West Tennants Reef used to look like this.

The band was not wide, perhaps no more than 8-10 metres across, but extended for nearly two miles East-West. Although the East Tennants Reef nearby had higher densities of seafans but, simply due to its size, the west Tennants Reef supported more large seafans than any other reef in Lyme Bay. Indeed it was one of the most extensive continuous beds of large seafans in UK waters. Unfortunately, by 2007 most of these large seafans (and large sponges) had gone. As part of a wider study, I conducted a remote video survey along the reef in the summer of 2007. Instead of a dense continuous bed of seafans we found isolated patches and extensive areas of bare reef. We also saw many recently detached large seafans lying flat on the seabed and scallop dredgers working nearby. We returned a couple of days later to dive the reef and capture some better video. This can be seen here: West Tennants Reef, 2007.

 

It was clear that the situation in Lyme bay was continuing to deteriorate. Fortunately major changes to rectify this were also happening. Following a lengthy consultation process, with proposals submitted by the Natural England, Conservation NGOs (in particular the Wildlife Trusts) and the fishing industry, DEFRA announced that an area of some 60 square nautical miles in the central part of Lyme Bay was to be closed to mobile fishing gear by Statutory Order. There have undoubtedly been a few vessels that continued to work inside the closed area at night, especially during the first couple of years. However it’s fair to say that by and large this has been a success, in terms of maintaining an area free from the impacts of mobile bottom fishing gear. So how has that been reflected in changes, or recovery, of the fauna of the reefs within the closed area. In order to assess this two parallel studies were set up, one by Plymouth University using remote video, and one conducted by ourselves (that is my consultancy Marine Bio-images) with divers recording life at fixed stations. Data was collected over three summers; 2008, 2009 and 2010, and the findings of these studies have now been analysed and are about to be published. The next part of this blog will look in more detail at what we found and what seems to have changed since the closed area was established.

Update 10th July 2012, New blog: Lyme Bay, what makes it special?
All images and text (C) Colin Munro Photography.

Lyme Bay Closed Area, a Marine Protected Area success? Part 1.

Lyme Bay Closed Area, a Marine Protected Area success? Part 1.

Dense beds of mature pink seafans (Eunicella verrucosa), some almost a metre across, growing on pristine reef in Lyme Bay.

In 2008, the UK Government Department for Environment, Food and Rural Affairs (DEFRA) closed an area of Lyme Bay, some 60 square miles in extent, roughly 10 per cent of the bay, to mobile benthic fishing gear. By mobile benthic fishing gear I mean gear that is towed across the seabed, i.e. bottom fishing trawl nets and scallop dredges. This closure was brought in to protect fragile seabed habitats and the associated marine life, in particular the subtidal rocky reefs and boulder and cobble reefs, known to occur in the central and eastern part of the bay. We’ve known for a long time, at least the late 1980s, that such heavy gear could be highly destructive to some reef species, especially fragile or soft tissued attached species such as sponges and soft corals. Of greatest concern was the increase in scallop dredging. Changes in the quota system, markets and fish prices had lead to the number of boats working with scallop dredges increasing dramatically in the late 1980s. The number of boats operating solely as scallop dredgers had also increased (vessels will often switch gear thoughout the year as fish species migrate and quotas change); thus the overall intensity of scalloping had rocketed. As far back as 1991, I conducted dive surveys for the Devon Wildlife Trust; we had heard reports from recreational divers of swathes of destruction on previously pristine reef areas. What we found was even more disturbing, not only were areas of reef being scraped clean of attached life, the very stucture of the reef was changing.

Scallop dredger in Lyme Bay. A scallop dredger hauling dredges (4 each side) to emtpy catch.

Amongst the more interesting reef areas in Lyme Bay are the boulder and cobble reefs and the mudstone ledge reefs. Boulder and cobble reefs are basically level boulder fields, most of the boulders are small, roughly football-sized and so the heavy scallop dredges can bounce and rattle across these boulders without getting damaged themselves, picking up the occasional scallop as they go. What also happens though is that the boulders are lifted out of the sediment, rolled along and banged together. As this happens the sponges and soft corals growing on the boulders are ripped off or ground to shreds. The steel teeth of the dredges rake into the sediment as the dredge travels, stirring up clouds of sediment which then subsequently settles on top of the boulders. The attached species that managed to survive intact are then smothered in a layer of sediment, blocking their delicate filter-feeding organs.

 

Mudstone reefs are composed of blue lias clay. This is the same hard, slate-like clay that can be seen in the fossil-rich cliffs that line much of the coast of Lyme Bay. As this clay can easily be shattered by a fossil hunters hammer, the effects of half a ton of toothed dredges being hauled across such ledges by a powerful fishing boat are quite devastating. The ledges simply crumble. Now as any good marine biologist knows, most of the larger attached fauna on reefs are filter feeding organisms – sponges, hydroids, soft corals, bryozoans etc., and as every hydrographer (and diver) knows, currents accelerate around the edges of ledges and promentories due to entrainment. So of course all the life clusters around the edges of ledges where the rich feeding currents are. Grind away the edges and you remove maybe 80% of the attached fauna and – most importantly – virtually all the large colonies. The large colonies are the structure-forming ones that provide new niches for other species, they are often the slow-growing species that can take years to re-establish (where possible), and they are also the ones with the largest reproductive potential: for example, a big seafan colony that’s maybe 15 or 20 years old is going to release many time more eggs or larvae than a little one about 5 years old thats only just reached reporductive maturity. So when the big colonies are removed this alone may drastically affect the ability of a species to maintain or re-establish its population in an area.

Reef badly damaged by scallop dredgers. Lyme Bay. Colin Munro Photography.

Reef badly damaged by scallop dredgers

So to put it mildly, the situation was not good, and was rapidly deteriorating. It only took one boat working across a reef to remove so much life that it would take years for recovery to occur. Six months of boats intensively working an area could (and did) irreversably change the structure of some reefs. As scallop stocks declined on the so-called ‘clean ground’ (areas of sandy seabed) boast began to work closer to the edges of reefs, nibbling away at the edges. Fish finders and echo sounders improved in quality, so skippers could see exactly which way ledges rose up, enabling them to work close around the most rugged ledges and pinnacles. DECCA became standard for position fixing, then was replaced by GPS, allowing every more accurate positioning of where the roughest points to be avoided were, so boats could work into reefs where previously they dare not enter. The power of vessels also increased, so when dredges did become stuck fast on a rocky ledge or large boulder the solution was often to turn on the power and pull free, often with devastating consequences for the reef. I personally witnessed this many times over the years. Boats would dredge right up the the edge of a reef, gradually extending further and further in to it through the day as the edges were ground down or boulders rolled away. Occasionally a dredger would come fast. You could see it stop dead in the water and list over to one side where the dredges on that side were caught. Watching from a couple of hundred metres away you would hear the engine rev, see the vessel sink deeper on the caught side, then suddenly lurch free to carry on around again.

Scallop dredger heeling over as the dredges on one side catch fast on the seabed. Lyme Bay. Colin Munro Photography.

Scallop dredger heeling over as the dredges on one side catch fast on the seabed.

On one occasion (whilst conducting dive surveys on a reef composed of large limestone boulders) we watched twelve dredgers work around in tight circles clipping in to the reef again and again for over six hours. We took position fixes and returned at dusk with stills and video cameras. It was about forty minutes steaming time to reach this offshore reef and the sun was disappearing as we descended to the reef and swum on a bearing towards where we had seen the boats working. It was quite black without lights when we hit the bottom at around 28 metres, visibility was very poor as the water was still full of suspended sediment from the dredgers working earlier. Even so the transition from pristine to ‘worked’ reef was clear cut and the devastating effects of that one day’s dredging were unmistakable. The entire seabed was carpeted in a layer of fine sediment, detached soft corals drifted loosely across the reef, detached seafans lay flat partially buried in sediment, fragments of the plates of ross coral (a bryozoan) littered the reef. Large boulders lay overturned with still attached seafans protruding from underneath. Only isolated patched of undisturbed reef remained where the dredgers had been working. Video footage taken during this dive, showing pristine reef from the start of the dive and damaged reef encountered later in the dive, can be downloaded from the link below (48Mb, plays in Windows Media Player or Quicktime Player).
East Tennants Reef following scallop dredging 2002

 

Thus began a long road to the establishment of protection for the reefs. An 18 year long campaign driven by the Devon Wildlife Trust finally lead to stautory protection for the reefs in 2008. So what has this acheived? I’ll address this in Part 2 of this blog.

Update 10th July 2012, New blog: Lyme Bay, what makes it special?
All images and text (C) Colin Munro Photography.