Over 15 years of ocean science and conservation online
#SciFund, a month long initiative to raise funds for a variety of scientific research projects, is once again upon us. Project leaders post a project description and an appeal for funds, and members of the public are invited to make small donations to projects that they deem worthy. Donations come with rewards such as access to … Read More “#SciFund Returns – Muddy waters: coral health after storm events” »
#SciFund, a month long initiative to raise funds for a variety of scientific research projects, is once again upon us. Project leaders post a project description and an appeal for funds, and members of the public are invited to make small donations to projects that they deem worthy. Donations come with rewards such as access to … Read More “#SciFund Returns: Seahorse Adventures” »
We tend towards waste. As a nation, as a community, and in our personal lives, waste is ubiquitous and often imperceptible. That we can afford to discard is an unfortunate side effect of having a high quality of life. Waste is not always a bad thing, either. We’re comforted by the fact that our doctors use disposable needles, that food can be packaged and preserved, that soiled diapers can be discarded. Disposability is freedom from the tedious chores of our grandparents and great-grandparents. It is access to time that can be spent with our loved ones or engaged in more fruitful pursuits. But there is still plenty of unnecessary waste that exists purely for convenience.
Those of us who consider ourselves environmentalist, good stewards of the earth, are often just as guilty of waste, myself included. Over the next several months, I will be exploring ways to reduce my own waste production. Each month I will identify some aspect of my personal life that generates unnecessary waste and explore solutions. Plastic is my major target, but I will also be looking for other resources drains that could be made more efficient (or, if possible, eliminated).
Read More “Towards a personal stewardship ethic – monthly sustainability challenge” »
I’m a bit late to the party, but last week, several news outlets reported that the Diablo Canyon Nuclear Power Plant was taken offline by “jellyfish-like creatures” that clogged several cooling intakes. While most sources were careful to point out that these were “jellyfish-like” organisms, some secondary sources truncated the description and announced that “Nuclear Power Plant Knocked Offline By Tiny Jellyfish, The Invasion Has Begun”. Unfortunately, these organisms are salps, not jellyfish, and you’d be more correct to describe them as human-like rather than jellyfish-like.
Salps are free-swimming pelagic tunicates, one of the most basal members of the chordate phylum. While they superficially resemble jellies to the untrained eye, they are far more derived, possessing three tissue layers (compared to the jelly’s two), a primitive, larval notochord, a perforated pharynx, and the rudimentary beginnings of a centralized nervous system. They form large, clonal colonies that are able to take advantage of plankton blooms by rapidly producing more clones to capitalize on an unpredicatable food source. Although I don’t have first hand reports, this is likely what happened in Diablo Canyon, as warm water discharges from nuclear power plants can trigger massive plankton blooms. Far from a “jellyfish invasion”, this was probably the natural response of a predator to increased food availability.
Read More “#TaxonomyFail: Salps, Jellyfish, and the Diablo Canyon Nuclear Power Plant” »
Jordan Nikoloyuk is the Sustainable Fisheries Coordinator of the Ecology Action Centre, a membership-based community environmental organization based in Nova Scotia, Canada. The Marine Issues Committee of the EAC was founded in 1995 after the collapse of the Atlantic Canadian groundfish stocks and works towards conserving and protecting marine ecosystems and maintaining sustainable fisheries and vibrant coastal communities.
As part of its sustainable seafood work and through its Friends of Hector campaign – www.friendsofhector.org – the EAC has participated in many Marine Stewardship Council assessments for Atlantic Canadian fisheries and encouraged retailers to support certified fisheries. Jordan has written this guest post to share his recent experiences with a certification that has left the EAC and other conservation organizations wondering whether seafood certification can contribute to sustainable fisheries management in the long term, or if the conflict between keeping an eco-label rigorous on the one hand and expanding its market appeal on the other is just too difficult to manage. What do you think?
The best way to buy seafood responsibly is to read a sustainable seafood guide and ask your retailer the two big questions: where is this from and how was it caught? When getting these answers is tough, many people turn to eco-certifications and labelling. Despite some increasingly controversial certifications, the Marine Stewardship Council (MSC) is considered to be the most trusted and reliable label, but how many unsustainable fishery certifications will it take to ruin this credibility?
Last week, after lengthy and widespread opposition, the MSC approved certification of the Atlantic Canadian longline swordfish fishery, which catches 100,000 sharks and 1,400 endangered sea turtles every year. The Ecology Action Centre spent almost two years working to oppose this greenwashing. Now we are left asking: how can we promote sustainable fisheries with organizations the size of the MSC working against us? When a definition of sustainability is so weak that it lets the status quo continue, can this be seen as an effective ‘market-driven solution’?
Read More “Swordfish, certifications, and sustainable seafood” »
We caught up with 11 marine scientists (including one honorary marine scientist, paleoblogger Brian Switek) at this year’s Ocean Sciences meeting in Salt Lake City and asked them the following question – What is your favorite marine organism and why? Their responses ranged from the classic (dolphins and sharks) to the bizarre (deep-sea shrimp and snails) to the exceptionally … Read More “The Ocean Question: What is your favorite marine organism and why?” »
Fossil fuels, photovoltaics, clean coal, wind turbines, hydroelectic dams, nuclear reactors, hydraulic fracturing. For all the discussions of energy independence, sustainable energy, renewable fuels, one word is often painfully absent: grid. America’s electrical grid has evolved from Edison electric generators and a few, uninsulated, wires in New York and Wisconsin to a massive, and massively inefficient, network of power lines, control stations, and generators that crisscross the country in three power blocks. This mycelial behemoth serves one function–to keep the electrons flowing. In Before the Lights Go Out: Conquering the Energy Crisis Before It Conquers Us, Maggie Koerth-Baker strips the wires of the United State’s electrical grid bare, revealing how it works, how it doesn’t work, and what we can do to make it work better, increasing efficiency, decreasing atmospheric carbon dioxide production, and securing America’s energy infrastructure.
Before the Lights Go Out begins with a bold and inspired move by Koerth-Baker. By choosing to focus on the development of our energy infrastructure and the challenges inherent in the current model, she bypasses the common stumbling block of “energy crisis” arguments in the United States–the unwillingness of some groups to accept the uncontroversial recognition of anthropogenic climate change. Improving the efficiency of the grid, incorporating alternative energy sources into our infrastructure, reducing waste which cost energy producers and consumer real capital, these are not goals that require an a priori understanding of climate change to make sound economic, social, and political sense. Koerth-Baker deftly skirts around the quagmire of one of our most baffling political debates and dives straight into solutions.
Read More “Before the Lights Go Out – Alternative Energy and America’s Grid” »
John Shepherd once said that counting fish is like counting trees, except that fish move and you can’t see them because they’re underwater. This is true with sharks as well. It’s basically impossible to know how many sharks there are. Fortunately, a variety of methods exist that can be used to determine population trends. In other words, even if we can’t know how many sharks there are, we can tell if there are more or less than there used to be. Presented here are brief descriptions of some of these methods and the conclusions of major shark conservation studies that used them. Though no one method is perfect, the fact that so many different methods have such similar conclusions is quite telling.
Read More “How severe are shark population decreases, and how do we know?” »
Megumi Shimizu is a graduate student aboard the RVIB Nathaniel B. Palmer to collect sediment samples near Antarctic Peninsula as a part of the LARISSA project. She is interested in microorganisms and biogeochemistry of marine sediments; how the metabolism of microorganisms interact with the surrounding environment and the chemical components in sediments. See her first update here.
Are you playing with mud on the research vessel?
Some people on the ship joked when they saw me processing my sediment core. Yes, I’m playing with mud in Antarctica. Sampling sediments can tell us a lot, not only what happened across geologic time scales, but also what kind of organisms are living in the sediment, microbiology, and the geochemical conditions. We are serious about collecting mud and playing with mud.
Nathaniel B. Palmer has three pieces of equipment to collect sediment; the megacore, kasten core, and jumbo piston core. The length you can reach below seafloor is different, 40cm, 1.5 to 6m and 24m respectively. Megacore is more suitable for biological studies since it preserves the sediment-water interface better than kasten core and jumbo piston core. Geological studies prefer Kasten core and jumbo piston core so that they can get older data from the sediment.
For my microbial lipid biomarker study, I’m taking samples from the megacore and kasten core. Along with microbial lipid and DNA, our team is collecting sediment and porewater (the water in pore spaces of sediments) to analyze geochemical properties of sediments, such as methane, sulfate, sulfide, and dissolved inorganic carbon. To maintain the condition of the sediments as close as the real environment, the sediment cores are processed under the condition of cold (~0C degree) and anoxic (no oxygen). How to make that condition? We have a special room called “The Little Antarctica”, on the ship, which is a big refrigerator containing glove box. A glove box is the transparent container with two pairs of gloves. The inside of the box is kept practically anoxic (less than 1% of oxygen. Atmospheric oxygen is ~20%).
As a marine biologists just beginning my deep-sea education, conservation as a priority was an alien concept. The deep sea was the last true wilderness, distant and alien, impossibly difficult to access. We knew that exploitation was coming, companies had been exploring the potential of deep-sea mining for decades, but they always seemed to be generation away. Conservation was a question for my scientific descendants. For my peers and me, we still had a few good decades left in the golden age of exploration that began in the 1970’s with the first discovery of deep-sea hydrothermal vents. That age is about to end.
The reality of deep-sea exploitation is imminent. The first hydrothermal vent mining lease has been issued in the territorial waters of Papua New Guinea. The International Seabed Authority, which regulates seafloor extraction in international waters, has approved the first two mining exploration permits for seafloor massive sulfides in international waters. Manganese nodule extraction, once quashed by a global decline in metal prices, has recently reappeared. Crustal metal deposits are fast becoming a viable resource. The isolation of rare earth elements from the seafloor, a newcomer in deep-sea exploitation, could open up new, massive deposit for critical electronic components. All of these are likely to occur within the next few decades.
Read More “VentBase – securing the conservation of deep-sea hydrothermal vent ecosystems” »
