Endangered tigers remain on the prowl in Jambi, Indonesia

Jon Afrizal, The Jakarta Post 6 Mar 09;

Tigers have struck once again in the district of Jambi on Wednesday, with an unidentified resident being mauled to death by a wild animal.

This incident brings the total number of attacks in the border area between Jambi and South Sumatra to 10, with only one victim surviving their severe injuries.

The Jambi Natural Resources Conservation Center (BKSDA) and the Muarojambi Police said they will soon place traps to catch the tigers as the situation had gone far enough and caused too much death already.

Muarojambi Police chief Adj. Sr. Comr. Tedjo Dwikora said his office had coordinated with Jambi BKSDA head Didy Wurdjanto to seek a way out to solve the problem and they mutually agreed to re-install traps.

Unlike last time, the traps will be placed outside the forest area because they are not allowed to place them in areas deemed natural habitats for the tigers.

The Muarojambi regency administration said it had made efforts to address this problem, but the Jambi BKSDA had rejected its proposal to hunt the tigers because it was against the law.

"The regent has taken the moves and coordinated with the local police chief, but they obstructed the law," said Muarojambi regency secretary Syaifuddin Anang.

The administration has also urged residents to stay on alert and avoid clearing forest areas because they are the natural habitat of tigers.

Head of the BKSDA team assigned to trace the tigers, Nurazman, said he had not yet figured out the tigers' movement. The team had been unable to venture any further into the forest since they evacuated the two victims previously attacked by the tigers.

"We are also restricted by our number of personnel," he said.

So far there have been no new reports of tigers actually wandering into plantation areas or villagers, but patrol teams are still conducting observations in the area.

"We have not yet received any new reports. We are urging residents to be more alert and for team members to remain on standby there," said Nurazman.

Jambi Governor Zulkifli Nurdin called for illegal logging activities in Petaling village, Sungai Gelam district to cease and vowed to continue working with police to solve the issue.

"I will speak with the Jambi police chief to stop illegal logging in the area and prevent loggers from entering the area," he said.

He said the latest case was different from those which had occurred in Kumpeh, as in Petaling the victims were illegal loggers.

"Until recently we had not encountered problems with tigers, but now they are furious because their habitats are being destroyed," said Zulkifli.

Meanwhile Forestry Minister M.S. Kaban said illegal logging had driven tigers into plantation areas and human settlements in search of food.

"We cannot blame the tigers alone. They would not leave their habitat if food was readily available there. They would also naturally be distraught if their homes were disturbed," said Kaban recently.


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Best of our wild blogs: 8 Mar 09


Butterflies of the Singapore Botanic Gardens
on the Butterflies of Singapore blog

Oriental Dwarf Kingfisher: Fright moult?
on the Bird Ecology Study Group blog

Hummingbird hawkmoth
New paper on Nature in Singapore on the Raffles Museum of Biodiversity Research website. Download PDF.

Mangroves in the city
on the wild shores of singapore blog

More on going coastal works in Singapore
'small rocks' to be laid near Cyrene Reefs and landslide protection on St. John's Island on the wild shores of singapore blog.

Why was fish 'manhandled' in Botanic Gardens?
on the Lazy Lizard's Tales blog


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Puffer fish almost kills sushi chef in Singapore

He samples fish imported from Japan which was supposed to be toxin-free
Hedy Khoo, The New Paper 8 Mar 09;

HE is a sushi chef who tasted death - well, almost.

Mr Anson Lim, 28, came within a sliver of being the first person here to die of puffer fish poisoning when he tasted the deadly Japanese delicacy as part of his job.

A few slices of puffer fish, known as fugu in Japanese, were enough to cause temporary paralysis to his face.

Doctors at Gleneagles Hospital later told him that they had never come across a case of puffer fish poisoning here before.

The incident, which took place in late 2007, came to light when The New Paper was alerted to it recently.

Mr Lim, who has 10 years of experience, was then the head sushi chef at a restaurant near the city.

'I thought I was going to die for sure,' he said in Mandarin.

He had bought two fugu fish for $150 each from a seafood supplier.

'I was slicing the first fugu fillet and my three assistant cooks were watching me,' he said.

'As a sushi chef, it is my responsibility to taste the fugu first to ensure it is safe before serving it.'

Mr Lim, who was trained by a Japanese master chef in 2003, ate a slice.

'I was watching the clock and it was 7pm then,' he recalled.

He then offered his assistants the opportunity to taste the fugu.

'I was confident it was safe because the imported fugu we bought had been prepared in Japan with the toxins removed before export,' explained Mr Lim.

It is not known how the poisonous fillet got into Singapore, but Mr Lim's 'taste test' probably saved the lives of his customers.

The Agri-Food and Veterinary Authority would only say that the import of puffer fish into Singapore is allowed.

As with the import of all other seafood, the importer in Singapore must be licensed by AVA and an import permit is required for each consignment.

Said Mr Lim: 'My three assistants asked me how long it would take before I know if I have been poisoned. I told them half an hour.

'One decided to try it on the spot, but the other two replied that they would only taste it half an hour later if I was still alright,' he recalled with a smile.

Mr Lim himself ate two more slices and some of the fugu skin as he continued to slice and prepare the fish for serving later.

It took only 20 minutes for the poison to kick in.

'I remember reaching out my hand for a glass of water when I suddenly experienced a momentary black-out,' he said.

'It was like a lightning flash, then I felt my mouth and lower jaw go numb. I knew I had been poisoned.'

Mr Lim then turned to his assistants and told them he had been poisoned.

'It was difficult for me to speak as I was losing control of my tongue and stuttering. Nobody believed me. They thought I was joking,' recalled Mr Lim, who said he frequently joked with his colleagues.

They were convinced only when he insisted they call the manager.

'I told the manager that I must get to the hospital within half an hour. I got into his car, then remembered my assistant had eaten the fugu too,' Mr Lim said.

'I was very frightened and anxious at that time, but I tried to think.'

Mr Lim ran back to the restaurant, got his assistant to join them and told the kitchen staff not to serve the fugu.

They then rushed to the emergency department of the Gleneagles Hospital.

'My heart sank when I asked the nurse if there was any injection they could give me to neutralise the poison and she said no,' he recalled.

Mr Lim was told to wait for a doctor.

'It was the longest and most agonising five minutes of my life. I kept thinking of my fiance and worried about what would happen to her if I died,' he said.

'I didn't want to die so young when I have yet to fulfil my ambitions.'

Mr Lim then had his stomach pumped.

'It was the worst experience of my life because I was conscious throughout the procedure,' he recalled.

'It was very painful as they had to put a pipe down my nose and I could see the water travelling up and down the pipe.'

He then saw the slivers of fugu being sucked out from his stomach.

'That was when I felt I had a chance to live,' he said.

Midway through the procedure, Mr Lim vomited blood.

Immediate relief

'It was horrible. The blanket over my lap was soaked with my blood. But as soon as I vomited out the toxins, I felt the sensation coming back to my mouth and jaw,' he remembered.

After a gruelling two hours, Mr Lim was sent to the intensive care unit.

'As I was being wheeled in, I called my mentor chef on my handphone and told him I just had my stomach pumped after eating poisonous fugu,' he said.

But his mentor told him he was not yet out of danger.

'He told me I had to wait another two to three hours before I knew for sure if I was going to live, as the poison can take up to six hours to kill a person.

'I told myself to just get past midnight.'

It was 9pm then.

All through the three hours, Mr Lim had his eyes glued to the clock.

'Even after midnight, I didn't dare sleep. I was afraid I would never wake again.'

But at 2am, Mr Lim's condition remained stable and his anxiety turned to elation.

'I couldn't sleep after that because I was so happy,' said Mr Lim, the memory putting a big grin on his face even now.

His assistant cook did not have his stomach pumped, but was given charcoal water.

Mr Lim was discharged after two days.

'I never regretted tasting the fugu because it was part of my duty as a chef,' he said.

His Japanese master chef trainer had a condition: he would impart his skills only to trainees who dared to eat fugu themselves.

But Mr Lim said he would never eat fugu in Singapore again.

Mr Lim, who now works at a Japanese bar and restaurant called Chiharu at Bukit Timah, said he also tells friends and customers not to eat fugu here.

'The fugu itself is tasteless. Fugu is eaten only for the thrill of gambling with death, so you can boast to your friends that you are brave enough to eat it,' he said.

'But most people don't understand this fish.

'Japan has very strict regulations on fugu. Not only must the chefs be licensed, the restaurants must also be certified.

'I'll still eat fugu, but only in Japan.'

FISHY FACTS

1 The puffer fish contains a poison, tetrodotoxin, which has no antidote. It causes paralysis and eventually death. In Japan, only licensed chefs are allowed to prepare the fish. They remove the toxins before serving. Cooking does not destroy the poison.

2 Each prefectural local government in Japan has its own qualifying system for chefs, who are not allowed to serve fugu in other prefectures, said Mr Hiroshi Abe, First Secretary of the Economic Section of the Embassy of Japan in Singapore. The certification is not valid here.

3 It was reported in 2007 that in Thailand - where the puffer fish has been banned since 2002 - some vendors sold it by dyeing the meat and passing it off as salmon. Between 2004 and 2007, more than 15 people in Thailand died and 115 were hospitalised after eating fugu.

4 Last year, two Malaysians died from eating the fish, known locally as ikan buntal. The sale of the fish is banned in Malaysia, but a black market for it was reported in Pontian, Johor.

5 The National Environment Agency said there have been no other reported cases of poisoning from fugu in Singapore.

More links
Don't eat toxic fish balls on the wild shores of singapore blog.


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Tonnes of elephant tusks smuggled into Vietnam: reports

Yahoo News 7 Mar 09;

HANOI (AFP) – Vietnam customs officials have uncovered up to five tonnes of elephant tusks smuggled in from Tanzania, state media said Saturday.

The tusks were found Friday hidden in around 114 boxes of plastic waste after being transported from Africa through Malaysia to Vietnam's northern Hai Phong port, said the Tuoi Tre newspaper.

The Thanh Nien newspaper quoted Dang Tat The, a national wild animal expert, as saying the tusks were from African elephants.

It was not yet clear if the tusks were for selling in Vietnam or if they were smuggled in for onward movement, the papers said, but officials were chasing the owner of the goods.

Ivory and ivory-based products sell well in Vietnam, with the main buyers including Chinese, Thai and local and overseas Vietnamese, wildlife trade monitoring organisation Traffic said last month.

According to a Traffic survey, ivory prices in Vietnam could be the world's highest, with tusks reportedly selling for up to 1,500 dollars per kilogram and small, cut pieces selling for up to 1,863 dollars per kilogram.

The trend has put elephants in Indochina under increasing threat, it said, adding that wild elephant numbers in Vietnam, Laos and Cambodia dropped from an estimated 6,250 in the late 1980s to 1,510 in 2000.

Vietnam outlawed the ivory trade in 1992 but shops can still sell ivory dating from before the ban. This allows some to restock illegally with recently-made carved items, the organisation said.


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Scientists to issue stark warning over dramatic new sea level figures

Rising sea levels pose a far bigger eco threat than previously thought. This week's climate change conference in Copenhagen will sound an alarm over new floodings - enough to swamp Bangladesh, Florida, the Norfolk Broads and the Thames estuary
Robin McKie, The Observer 8 Mar 09;

Scientists will warn this week that rising sea levels, triggered by global warming, pose a far greater danger to the planet than previously estimated. There is now a major risk that many coastal areas around the world will be inundated by the end of the century because Antarctic and Greenland ice sheets are melting faster than previously estimated.

Low-lying areas including Bangladesh, Florida, the Maldives and the Netherlands face catastrophic flooding, while, in Britain, large areas of the Norfolk Broads and the Thames estuary are likely to disappear by 2100. In addition, cities including London, Hull and Portsmouth will need new flood defences.

"It is now clear that there are going to be massive flooding disasters around the globe," said Dr David Vaughan, of the British Antarctic Survey. "Populations are shifting to the coast, which means that more and more people are going to be threatened by sea-level rises."

The issue is set to dominate the opening sessions of the international climate change conference in Copenhagen this week, when scientists will outline their latest findings on a host of issues concerning global warming. The meeting has been organised to set the agenda for this December's international climate talks (also to be held in Copenhagen), which will draw up a treaty to replace the current Kyoto protocol for limiting carbon dioxide emissions.

And key to these deliberations will be the issue of ice-sheet melting. The International Panel on Climate Change (IPCC) - when it presented its most up-to-date report on the likely impact of global warming in 2007 - concluded that sea-level rises of between 20 and 60 centimetres would occur by 2100. These figures were derived from estimates of how much the sea will increase in volume as it heats up, a process called thermal expansion, and from projected increases in run-off water from melting glaciers in the Himalayas and other mountain ranges.

But the report contained an important caveat: that its sea-level rise estimate contained very little input from melting ice sheets in Antarctica and Greenland. The IPCC forecast therefore tended to underestimate forthcoming changes.

"The IPCC felt the whole dynamics of polar ice-sheet melting were too poorly understood," added Vaughan. "However, we are now getting a much better idea of what is going on in Greenland and Antarctica and can make much more accurate forecasts about ice-sheet melting and its contribution to sea-level rises."

From studying satellite images, scientists have watched the sea ice that hugs the Greenland and Antarctic shores dwindle and disappear. Sea-ice melting on its own does not cause ocean levels to rise, but its disappearance has a major impact on land ice sheets. Without sea ice to prop them up, the land sheets tip into the water and disintegrate at increasing rates, a phenomenon that is now being studied in detail by researchers.

"It is becoming increasingly apparent from our studies of Greenland and Antarctica that changes to sea ice are being transmitted into the hearts of the land-ice sheets in a remarkably short time," added Vaughan. As a result, those land sheets are breaking up faster and far more melt water is being added to the oceans than was previously expected.

These revisions suggest sea-level rises could easily top a metre by 2100 - a figure that is backed by the US Geological Survey, which this year warned that they could reach as much as 1.5 metres.

In addition, in September, a team led by Tad Pfeffer at the University of Colorado at Boulder published calculations using conservative, medium and extreme glaciological assumptions for sea-level rise expected from Greenland, Antarctica and the world's smaller glaciers and ice caps. They concluded that the most plausible scenario, when factoring in thermal expansion due to warming waters, will lead to a total sea level rise of one to two metres by 2100.

Similarly, a commission of 20 international experts, called on by the Dutch government to help plan its coastal defences, recently gave a range of 55cm to 1.1 metres for sea-level rises by 2100. "Equally important, this commission has highlighted the fact that sea-level rise will not stop in the year 2100," said Professor Stefan Rahmstorf of Potsdam Institute for Climate Impact Research. "By 2200, they estimate a rise of 1.5 to 3.5m unless we stop the warming. This would spell the end of many of our coastal cities."

This point was backed by Dr Jason Lowe of the Hadley Centre, the UK's foremost climate change research centre. "It is still not clear exactly how much the sea will rise by the end of this century, but it is certain that rises will continue for hundreds of years beyond that - even if we do manage to stabilise carbon dioxide emissions and halt the rise in atmospheric temperature. The sea will continue to heat up and expand. In addition, the Greenland ice sheets will continue to melt," he said.

This latter effect could, ultimately, have a particularly destructive impact. Scientists have calculated that if industrial emissions of carbon dioxide and other greenhouse gases eventually produce a global temperature increase of around 4C, there is a risk that Greenland's ice covering could melt completely. This could take several hundred years or it might require a couple of thousand. The end result is not in doubt, however. It would add around seven metres to the planet's sea levels. The consequence would be utter devastation.

Such a scenario is distant, but real, scientists insist. However, at present, the most important issue, they argue, is that of short-term sea-level rises: probably around one metre by 2100. When that occurs, the Maldives will be submerged, along with islands like the Sunderbans in the Bay of Bengal, and Kiribati and Tuvalu in the Pacific. The US - which has roughly 12,400 miles of coastline and more than 19,900 square miles of coastal wetlands - would face a bill of around $156bn to protect this land. Cities such as London would require massive investments to provide defences against the rising waters. Others, such as Alexandria, in Egypt, would simply be inundated.

Rising oceans will also contaminate both surface and underground fresh water supplies, worsening the world's existing fresh-water shortage. Underground water sources in Thailand, Israel, China and Vietnam are already experiencing salt-water contamination.

Coastal farmland will be wiped out, triggering massive displacements of men, women and children. It is estimated that a one-metre sea-level rise could flood 17% of Bangladesh, one of the world's poorest countries, reducing its rice-farming land by 50% and leaving tens of millions without homes.

Such destruction would not be caused merely by rising sea levels, however. Other effects of global warming will also worsen the mayhem that lies ahead: in particular, the increase in major storms. "When we talk about the dangers of future sea-level rises, we are not talking about a problem akin to pouring water into a bath," added Dr Colin Brown, director of engineering at the Institution of Mechanical Engineering. "Climate-change research shows there will be significant increases in storms as global temperatures rise. These will produce more intense gales and hurricanes and these, in turn, will produce massive storm surges as they pass over the sea."

The result will be the appearance of the super-surge, a climatic double whammy that will savage low-lying regions that include Britain's south-eastern coastline, in particular East Anglia and the Thames Estuary, along with cities such as London, Portsmouth and Hull, which are rated as being particularly vulnerable to sea-level rise.

In addition to these hotspots, the country will also face massive disruption to its transport and energy systems unless it acts swiftly, according to a report - Climate Change, Adapting to the Inevitable - published last month by the Institution of Mechanical Engineers. Many rail lines run along river valleys that will be flooded with increased regularity while bridges carrying trains and lorries often cross shipping lanes and may have to be redesigned to accommodate rising water levels.

"Power supplies will also be affected," added Brown. "The Sizewell B nuclear plant has been built on the Suffolk coast, a site that has been earmarked for the construction of several more nuclear plants. However, Sizewell will certainly be affected by rising sea levels. Engineers say they can build concrete walls that will keep out the water throughout the working lives of these new plants. But that is not enough. Nuclear plants may operate for 50 years, but it could take hundreds of years to decommission them. By that time, who knows what sea-level rises and what kinds of inundations the country will be experiencing?"

Most scientists believe Britain remains relatively well placed to combat sea-level rises. "The government has been fairly far-sighted over this issue, with projects such as Thames Estuary 2100 being set up to prepare flooding defence projects," said Professor Robert Nicholls, of Southampton University.

This does not stop the controversy, however. In its report, the Institution of Mechanical Engineers warned that many areas would have to be abandoned because they are simply too expensive to protect. In particular, large areas of the Norfolk coastline would be left to be inundated, a massive loss of human habitat.

But this approach represents an abrogation of national duty to many people - particularly those whose homes will be destroyed, individuals such as Martin George, former chairman of the Broads Society. "A country that has the technological know-how to extract oil and coal from below the North Sea should surely be capable of finding a way to protect a concrete sea wall against the effects of climate change. We should do our damnedest to safeguard our heritage," he said.

• Additional research by Lisa Kjellsson
Why the sea is rising

• Thermal expansion. All bodies expand when they are heated, and that is true for the water that covers 70 per cent of the planet. The oceans are expanding - upwards. It is estimated this increase in volume will raise levels by 10-40 cms.

• Melting glaciers and mountain ice caps - outside Greenland and Antarctica - are also adding water to rivers that flow to the oceans. However, these remain a modest source of sea-level rise. Possibly around 10 cms.

• The Greenland and Antarctic ice sheets represent vast reserves of frozen fresh water. The former would add 7m to sea levels if melted completely; the latter would bring a further 60m rise to the levels of the world's oceans.


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The toxic sea: ocean acidification

Each one of us dumps a tonne of carbon dioxide into the oceans every year, turning them into acidified soups — and threatening to destroy most of what lives in them
Richard Girling, The Times Online 8 Mar 09;

They are calling it “the other CO2 problem”. Its victim is not the polar bear spectacularly marooned on a melting ice floe, or an eagle driven out of its range, nor even a French pensioner dying of heatstroke. What we have to mourn are tiny marine organisms dissolving in acidified water.

In fact we need to do rather more than just mourn them. We need to dive in and save them. Suffering plankton may not have quite the same cachet as a 700-kilo seal-eating mammal, but their message is no less apocalyptic. What they tell us is that the chemistry of the oceans is changing, and that, unless we act decisively, the limitless abundance of the sea within a very few decades will degrade into a useless tidal desert.

In every way — economically, environmentally, socially — the effects of ocean acidification are as dangerous as climate change, and even harder to resist. It has been a slow dawning. Until recently, marine scientists have had little luck in engaging the public or political mind. The species most directly at risk — plankton, corals, sea snails, barnacles and other stuff that most people have never heard of — seemed as remote from our lives as cosmic dust. But now at last “the other CO2 problem” may have found a mascot of its own — the tiny but colourful clownfish, winsome star of the Disney classic Finding Nemo. In the film, Nemo gets lost. Now it turns out that real clownfish might lose their way too.

In early February, the American academic journal Proceedings of the National Academy of Sciences (PNAS) carried a paper titled “Ocean acidification impairs olfactory discrimination and homing ability of a marine fish”. The sombre language concealed a stark message. What the researchers had found was that clownfish larvae in acidified water were unable to detect the odours from adult fish that led them to their breeding sites. The implications were obvious. If the fish don’t breed, the species will not survive, and what is true for one species must be true for others. In time, the world’s fishing fleets will be less a food resource than a disposal problem.

What’s happening is this: the oceans absorb carbon dioxide (CO2) from the atmosphere. As most climate scientists and governments now agree, human activity — most importantly, burning fossil fuels — has intensified CO2 in the atmosphere, causing long-term climate change. The good thing is that the seas have absorbed a lot of the gas and so have slowed the pace of atmospheric warming. The bad thing is that CO2 reacts with sea water to make carbonic acid.

Since 1800, humans have generated 240 billion tonnes of carbon dioxide, half of which has been absorbed by the sea. On average, each person on Earth contributes a tonne of carbon to the oceans every year. The result is a rapid rise in acidity — or a reduction in pH, as the scientists prefer to express it — which, as it intensifies, will mean that marine animals will be unable to grow shells, and that many sea plants will not survive. With these crucial links removed, and the ecological balance fatally disrupted, death could flow all the way up the food chain, through tuna and cod to marine mammals and Homo sapiens. As more than half the world’s population depends on food from the sea for its survival, this is no exaggeration.

This is why 155 marine scientists from 26 countries recently signed the Monaco Declaration, identifying the twin threats of global warming and ocean acidification as “the challenge of the century”. It is, nevertheless, a challenge they have taken up only recently.

“The whole scientific community was caught with its pants down,” says Jason Hall-Spencer, research lecturer at Plymouth University, who was one of the signatories. The term “ocean acidification” was coined only in 2003 — by odd coincidence the same year Finding Nemo was released and 35,000 people died in the European summer heat wave — though, unlike global warming, it has not had to face the opposition of truth-deniers. Verging on panic in 2005, the Royal Society published a 68-page report in which it calculated that acidification had increased by 30% in 200 years. If we went on as we were, it said, this would rise to 300% by 2100, making the seas more corrosive than they had been at any time for hundreds of millennia. In every practicable sense, the damage was irreversible. “It will take tens of thousands of years for ocean chemistry to return to a condition similar to that occurring at pre-industrial times,” the Royal Society said.

It is a truism that might have been minted for the Darwin bicentenary. A species once lost is gone for ever. You can’t rewind evolution, or reinvent fish. We are not talking about dispossessing our children, or even our grandchildren’s grandchildren. We are talking so many generations into the fog of geological time that we might not even be talking about the same species. We are certainly not talking about low-lying countries protected by coral reefs, such as the Maldives. In future they will not be studying the marine environment: they will be part of it.

Doomy stuff like this, of course, is nothing new. The “warmists”, as the deniers like to call them, have been telling us for years that our rate of consumption is unsustainable and that future generations will pay a terrible price for our carelessness. If you don’t want to believe in climate change, you can argue that forecasts created by computer modelling are “theoretical”. Or you can confuse the long-term graph of “climate” with the short-term spikes of “weather”. Look, there’s a snowflake! Global warming can’t be happening!

But acidification permits no such equivocation. It is demonstrable, visible and measurable, and there is nothing theoretical about how it is caused or what it does. All the same, until now there has been one significant shortcoming.

As with the clownfish, it has been easy enough under laboratory conditions to see how individual species respond to acidity. What is much less easy is to observe the effects on entire ecosystems.

This problem has now been cracked by a team from Plymouth led by Jason Hall-Spencer, who scanned the world for a location where the sea conditions expected in future were already happening naturally. They found it in the Bay of Naples, just off the holiday island of Ischia.

The sea bed here is chalk. Deep geological activity converts some of this into carbon dioxide and forces it up through volcanic vents into the water. In and around the neighbourhood of these vents, the result is a perfect “gradient” of pH levels from the normal 8.1 all the way down to 7.4 (remember: the lower the pH, the higher the acidity). To non-scientists, the giving or taking of a few decimal points can look undramatic. To experts they mark the difference between life and death. The 30% increase in acidity during the industrial age is reflected by a drop in pH of just 0.1. On current trends, it will plummet by another 0.4 points to hit an unprecedented low of 7.7 by 2100. By 2300 it could be down to 7.3.

Few species living in the sea have experienced conditions like these at any time throughout their entire life on Earth. With pH as low as this, it is at least questionable that land creatures emerging from the primal swamp could have evolved into the bony specimens that roam the Earth today. And it is certain that the pace of environmental change is far too fast for evolution to keep in step. As a recipe for life on Earth, it is about as efficacious as nuclear war. Experiments have shown that the tipping point at which shell growth ceases comes at a pH of 7.8. This is the level which, on current trends, will be the global norm before the end of the century, and it is the level at which the Plymouth team has focused its attention.

Given all the dire warnings, the first visual impression at Ischia is something of a surprise. There are plenty of fish. Is it, then, a false alarm? Could the world’s scientists have got their statistical knickers in a twist and jumped to a false conclusion? Will life just go on as normal? Alas, no. The acidified water is a small zone in a wider sea. There is no barrier. The fish are just visitors. They come to feed on the soft-bodied algae that survive in the altered conditions, then they swim away again. What they don’t do is breed — which is exactly what the Nemo research predicts.

“Fish breed naturally at a pH of 8.1,” says Hall-Spencer. He believes the sensory loss observed in clownfish is only one part of the story. “Losing the sense of smell,” he says, “is not likely to be the only effect. It’s much more likely to be one impairment among many. Eggs in these conditions cannot develop normally.”

Shelled creatures in the Ischian waters are visibly suffering. Sea urchins thin out and disappear as the acidity increases; so do corals, limpets and barnacles. Sea snails straying into the zone have thin, weak shells, and produce no young. There is another important absentee, too — the coralline algae (seaweed with a chalk skeleton) that glues coral reefs together. Without it, reefs become weakened and fall apart.

In just a few decades, if the output of carbon dioxide does not abate, this will be the condition of all the world’s oceans. Many if not all commercially fished species, including shellfish, will suffer. So, too, will coral reefs, whose disintegration will leave low-lying coasts in the tropics unprotected from the rising seas and fiercer storms that climate change will unleash. By some calculations reefs will have vanished by 2065, and nobody expects them to survive into the 22nd century.

Nature, however, will continue to abhor a vacuum. Species that disappear will be replaced by alien invaders. Shelled and vertebrate creatures will be replaced by the soft and the blobby. Celebrity chefs, if they survive as a species, will be teaching us how to stuff jellyfish. The plant species that thrive around the volcanic vents in the Bay of Naples are alien to the Mediterranean, laying the foundations of an entirely different ecosystem.

Already, says Hall-Spencer, similar changes are occurring along the southern coasts of England. Oyster farmers and ships discharging ballast water have accidentally introduced Japweed, Sargassum muticum, a fast-growing brown seaweed that clogs beaches and harbours. Originally a native of southeast Asia and Japan, it is unfazed by low pH and almost impossible to eradicate. As in the classic case of the grey squirrel ousting the red, the invasive alien expels and replaces the natives.

“It perturbs the ecosystem and drives out things that should live there,” says Hall-Spencer. Plants are the base of the food chain, so everything in the water depends on them directly or indirectly. With the professional caution of the scientist, he declines to speculate on which species will be the first to disappear, but acknowledges that many creatures have little hope of survival.

To reprise the old Star Trek mantra, there will be life here, but not life as we know it.

Various ideas have been put forward to mitigate the damage and downgrade the outcome from fatal catastrophe to expensive nuisance. It will take some doing. One idea is “ocean fertilisation”, which involves adding iron to the water to stimulate a plankton bloom. The plankton then absorb atmospheric CO2 before sinking into deep water and locking the poison away.

Another scheme from the top shelf of academic fantasy is “ocean sequestration”, which involves sinking waste carbon into the deep ocean where, at depths in excess of 3.5 kilometres, the gas will solidify into crystals. A possibly more viable option is “geological sequestration”, though it is one that will whiten environmentalists’ hair. It involves “capturing” gas from industrial plants and injecting it into exhausted aquifers or worked-out oilfields, where it can be stored in the rock. Capacity is not a problem — the North Sea alone could hold as much as 800 gigatonnes, which is approximately 1,600 times the UK’s entire annual output of industrial carbon dioxide. Neither is the idea merely theoretical. The Norwegian oil and gas company Statoil pumps a million tonnes a year into a saline aquifer.

But the risks quite literally are incalculable. What happens if there is a leak? Drilling and extraction in the oilfields may well have caused subsidence and cracking in the rock. The idea makes no sense unless storage is safe, secure and “permanent” — which, in the case of CO2, means somewhere between 5,000 and 10,000 years, or about the same as some nuclear waste.

There is, of course, a fourth option, the simplest and yet hardest of the lot — changing the way we live. Carbon-reduction targets need to be more than just green baubles on the faraway policy tree. Greed has driven us to a level of over-consumption that threatens our health, melts the economy and progressively poisons the planet. Unless we can get a grip on ourselves, constrain our appetites and halt the mismatch between consumption and resources, the future is an empty ship sailing upon an empty sea.

Richard Girling’s new book, Greed: Why We Can’t Help Ourselves (Doubleday, £12.99), is published on March 26. It is available at the BooksFirst price of £11.69, including p&p. Tel: 0870 165 8585


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Revenge of the rainforest

The Amazon has long been the lungs of the world. But now comes dramatic evidence that we cannot rely on it in the fight against climate change
Steve Connor, The Independent 6 Mar 09;

It covers an area 25 times bigger than Britain, is home to a bewildering concentration of flora and fauna and is often described as the "lungs of the world" for its ability to absorb vast amounts of carbon dioxide through its immense photosynthetic network of trees and leaves.

The Amazon rainforest is one of the biggest and most important living stores of carbon on the planet through its ability to convert atmospheric carbon dioxide into solid carbon, kept locked in the trunks of rainforest trees for centuries.

But this massive natural "sink" for carbon cannot be relied on to continue absorbing carbon dioxide in perpetuity, a study shows. Researchers have found that, for a period in 2005, the Amazon rainforest actually slipped into reverse gear and started to emit more carbon than it absorbed.

Four years ago, a sudden and intense drought in the Amazonian dry season created the sort of conditions that give climate scientists nightmares. Instead of being a net absorber of about two billion tons of carbon dioxide, the forest became a net producer of the greenhouse gas, to the tune of about three billion tons.

The additional quantity of carbon dioxide left in the atmosphere after the drought – some five billion tons – exceeded the annual man-made emissions of Europe and Japan combined. What happened in the dry season of 2005 was a stark reminder of how quickly the factors affecting global warming can change.

"For years, the Amazon forest has been helping to slow down climate change," said Professor Oliver Phillips, from the University of Leeds and the lead author of the study in the journal Science. "But relying on this subsidy from nature is extremely dangerous. The emission of five billion tons of carbon dioxide was huge. It meant that a major part of the biosphere had switched from one function to another, from a carbon sink to a carbon source.

"It shows what could happen if droughts become more frequent, and climate models suggest that Amazonia will get warmer and so put more water stress on vegetation. If the Earth's carbon sinks slow or go into reverse, as our results show is possible, carbon dioxide levels will rise even faster. Deeper cuts in emissions will be required to stabilise our climate."

The study, which involved nearly 70 scientists from 13 countries, examined more than 100,000 trees in 100 forest plots. The scientists had been monitoring changes to the girth of each tree over a period of between 20 and 30 years, so were able to calculate with some precision the effect of the 2005 drought on tree growth.

The drought itself was unusual. Normally, droughts in the Amazon are the result of changes caused by El Niño, the warm Pacific Ocean current, but the one in 2005 was a result of higher-than-average temperatures at the sea surface of the tropical North Atlantic.

"The pattern of the drought was shorter but sharper and more intense than usual," Professor Phillips said. "It affected the southern two-thirds of Amazonia and especially the south-west through reduced rainfall and higher-than-average temperatures. It was the kind of drought we expect to see in a globally warming world. On the ground, it was hard to see because you had to detect by measuring lots of trees over a larger area of land. There was not a massive die-off of trees."

The researchers found that the drought sharply reversed the decades-long growth of the trees. The normal die-off rate of the trees, about 1 per cent per year, doubled to 2 per cent, and the continued expansion of tree girths effectively stopped.

"Visually, most of the forest appeared little affected, but our records prove tree death rates accelerated," Professor Phillips went on. "Because the region is so vast, even small ecological effects can scale-up to a large impact on the planet's carbon cycle."

Humans worldwide are estimated emit about 32 billion tons of carbon dioxide each year but just less than half of this, about 15 billion tons, remains in the atmosphere. The rest is absorbed by natural carbon sinks in the ocean and on land.

Scientists have calculated that the world's tropical forests collectively absorb about 4.8 billion tons of carbon dioxide every year, with the Amazon being the single biggest rainforest sink. Amazonia alone is estimated to store about 100 billion tons of carbon locked up in its trees.

This is why the climate change negotiations in Copenhagen later this year will focus heavily on what can be done to save rainforests to ameliorate the effects of man-made emissions of carbon dioxide.

Lee White, the chief climate change scientist for the government of Gabon, said: "To get an idea of the value of the sink, the removal of nearly five billion tons of carbon dioxide from the atmosphere by intact tropical forests, based on realistic prices for a ton of carbon, should be valued at about £13bn a year. This is a compelling argument for conserving tropical forests." Dr White was a co-author of another study last month on the role played by African tropical forests in processing carbon dioxide.

Professor Phillips added. "It's surprising to see how sensitive the system appears to be. This is the first time anyone has tried to measure the impact of a big tropical drought on the ground. Now we've quantified it and, yes, there's a specificity there and it wouldn't take a huge change to shut down this thing and switch it to an overall source of carbon dioxide."

The Amazon: Facts and figures

* The Amazon rainforest covers an area of some 600 million hectares (2.3 million sq miles), an area of land 25 times bigger than Britain. It is the biggest rainforest on Earth, responsible for about 40 per cent of the world's rainforest absorption of carbon dioxide.

* Satellite surveys indicate that about 5,800 sq miles of the Amazon rainforest is burnt or cleared each year to make way for cattle ranching, farming or other kinds of development.

* More than half of the world's estimated 10 million species of plants, animals and insects live in tropical rainforests. One-fifth of the world's fresh water moves through the Amazon basin.

* Scientists estimate that there are at least 100 billion tons of carbon stored in the trees of the Amazon rainforest and each year the Amazon absorbs about 2 billion tons of carbon dioxide from the atmosphere.

* During the extreme drought of 2005, the Amazon became a net producer of carbon dioxide, releasing an estimated 3 billion tons of the greenhouse gas into the atmosphere – a net increase of 5 billion tons.


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Northern Australia Sea Rangers part of world turtle project

Torres News 8 Mar 09;

Indigenous Sea Rangers from northern Australia, including a contingent from the Torres Strait Islands, impressed international delegates at the 29th Sea Turtle Symposium held in Brisbane.

The Dugong and Marine Turtle Project is the first of its kind, striving to manage marine turtles on a regional scale that matches the animal’s large migratory range.

The project aims to conserve the species across northern Australia, one of the world’s few remaining strongholds for the animals; and is coordinated by the North Australian Indigenous Land and Sea Management Alliance - a partnership comprising the Kimberley Land Council, Northern Land Council, Carpentaria Land Council Aboriginal Corporation, Balkanu Cape York Development Corporation and the Torres Strait Regional Authority.

NAILSMA chief executive officer Joe Morrison said: "Indigenous land and sea managers across northern Australia are world-leaders in many regards; combining traditional knowledge with modern science to manage marine turtles in Australia."

Kaurareg traditional owner Pearson Wigness said the community-based management plans developed by Torres Strait Islanders had raised a lot of interest at the symposium.

"They were impressed by the way we have integrated traditional law with the needs of other stakeholders like the government and the scientific community, to manage turtle and dugong in our region. And they want to learn from our example."

TSRA Alternate Debuty Chair Kenny Bedford, who also attended the symposium, described the event as a valuable opportunity to share experiences and achievements with other indigenous people, conservationists and scientists from around Australia and the world.

"Through this process our people and community efforts in this management area are being recognised and praised internationally," he said.

"The importance of our region in the global management of sea turtles is also being acknowledged."

Attending the symposium were Mr Bedford, Charles David (Iama Project Officer) and Damian Miley (Land and Sea Management Unit, TSRA).


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