Showing posts with label CSIRO. Show all posts
Showing posts with label CSIRO. Show all posts

Monday, May 4, 2009

Clathrate Stable through Younger Dryas

This work is the sort of news that perhaps a few would understand. We have unbelievable amounts of methane sequestered in the form of clathrates. This is a methane water ice combination that shows up in permafrost and deep enough in the ocean, usually on the continental shelf. It represents methane accumulation that encompasses millions of years and the volumes are naturally mind boggling. It is the ultimate reserve of fossil fuels.

It turns out to be difficult to recover and this article confirms nicely that Mother Nature has problems getting it out also. It may not be as safely sequestered as granite but it is doing a good imitation.

Rather importantly, this work has shown that during a period of unusual methane concentration and violent climate change, that the methane did not originate from the clathrates. They are still there but they are not now anyone’s first suspect.
Like most, I had assumed that the sharp increase in atmospheric methane was likely forced by the release of this particular form of trapped methane.
This work has removed that source from consideration and leaves us with the ample supply been produced by wetlands. The excess methane may have been associated with an excessive increase in boreal forest wetlands been created as the ice rapidly retreated. It obviously takes a long time for a freshly started muskeg to stabalize to the conditions that are now present and it is reasonable to conjecture that this process is methane producing.

Greenland Methane Danger Far Less Than Feared

by Staff Writers
Canberra, Australia (SPX) Apr 28, 2009

http://www.terradaily.com/reports/Greenland_Methane_Danger_Far_Less_Than_Feared_999.html

Ice core research has revealed that a vast, potential source of the potent greenhouse gas, methane, is more stable in a warming world than previously thought. Based on international research published in Science, the finding includes Australian contributions from CSIRO and the Australian Nuclear Science and Technology Organisation (ANSTO)

Wetlands in the tropics and emerging from under receding Northern Hemisphere glaciers have been considered the primary source of rising atmospheric methane in a warming world. But scientists have known of another potential source.

Massive quantities of methane are locked away in permafrost and in the ocean floors as methane clathrate - an ice-like material which can return to gas if temperatures increase or pressures drop. Just a 10 per cent release of methane would have the equivalent impact on global warming of a ten-fold increase in carbon dioxide concentration.

So began a US, New Zealand and Australian research project to understand ice core records spanning hundreds of thousands of years, profiling periods of high-methane increase and focusing on the Younger Dryas period. The cause of the large increase in methane 12,000 years ago as the Earth warmed and the Younger Dryas ended has been a source of much debate among scientists.

"The result is a good news outcome for climate scientists monitoring greenhouse gases and investigating the likely sources of methane in a warming world," says CSIRO's Dr David Etheridge, from the Centre for Australian Weather and Climate Research who helped show how the air could be extracted from polar ice to measure past methane changes and identify their causes.

"There are vast stores of methane clathrates beneath the ocean and in permafrost and there is evidence that millions of years ago release from these storages caused significant climate change, although none in more recent times.

"The objective of the research was to determine how stable the clathrate methane stores were as the Earth warmed rapidly from its last glacial state and whether clathrates might be a source of future climate change as global temperatures rise."

Dr Andrew Smith, from ANSTO, studied the source of methane by using a technique called accelerator mass spectrometry to detect individual radiocarbon atoms from ancient atmospheric methane samples over the Younger Dryas period.

"Radiocarbon provided the key insight to decide whether the extra methane was derived from clathrates or from wetlands," Dr Smith says.

"A multi-disciplinary team of scientists from the US Scripps Institution of Oceanography, New Zealand's National Institute of Water and Atmosphere, and from Australia's ANSTO and CSIRO combined their resources to tackle this challenging project."

The project involved years of field-work in West Greenland where scientists accessed samples located in 'outcropping' ice, a cross-section of ice formed over tens of thousands of years that is exposed at the surface. A tonne of ice was excavated to provide sufficient air from trapped bubbles for each measurement of the methane carbon isotopes.
Extremely sensitive analysis was required because of the low concentration of methane in air and because only about one trillionth of that methane contains radiocarbon - the carbon-14 isotope that is the key indicator of clathrate emissions. The analysis was undertaken at ANSTO in southern Sydney.

The methane isotope change accompanying the jump in concentration confirmed that the emission was not from clathrates, but from ecological sources such as wetlands.

"We know that emissions of methane are increasing now and that some sources might emit even more with warming, causing a positive climate feedback, or amplification. But this finding suggests that the clathrate source is less susceptible than recently feared," Dr Smith says.

Tuesday, February 3, 2009

Australia Advancing Biochar

From this distant perspective, Australia is well ahead of everyone in learning how to use and apply biochar. The results been reported are significant and emphatic and hold up of every soil tested, although I am sure someone went out and failed the impossible somewhere.

A few notes here that I would like to add.

Firstly, Australian soils are famously poor at holding nutrients and have troubled Australian agriculture from the beginning. This is the one country in the world that is highly aware of soil fertility and deficiencies. It is thus no surprise whatsoever that they will lead the pack on this.

Secondly, a few technical misperceptions linger. Additional water retention is a result of increased soil biomass encouraged by the presence of elemental carbon.

Everyone sees a forest as a visible source of carbon. That is wrong. It produces carbon in a very inconvenient form for agricultural use and usually quite slowly, or at least no faster than corn or tobacco.

The Wollongbar test used maize because it is ideal for agricultural biochar production. It produced a huge tonnage per acre, perhaps sufficient to deliver one to three tons of biochar per acre. More critically, after the corn harvest, it also dries out as standing.

Most other plant waste has to be dried, or it will simply rot in the field. Corn is infamous for resisting rotting in the field which is one reason it has to be gathered and burned anyway.

Conversations regarding cost concerns are misplaced. A simple sheet metal kiln will easily replicate the conditions of an earthen kiln used by the Indians and quickly produce biochar from any and all dry plant waste.

Of course it you insist in operating a tightly controlled modern kiln to produce so called syngas along with your completely reduced biomass, it will be much more costly. The yield is naturally as expensive and possibly less satisfactory as a soil additive.

A lower temperature biochar will still be mostly elemental carbon but will also have a lot of remaining complex organic matter that will degrade slowly.

Why biochar?

29/01/2009 10:34:00 PM

Tim Flannery loves it, Malcolm Turnbull wants it on the political agenda, and ancient Amazonian cultures used it to make soil that is still fertile after hundreds of years. Why aren't we knee-deep in biochar?

Biochar is the charcoal created by burning organic waste without oxygen—a charring process that also delivers a biofuel, syngas—to produce a very stable form of carbon that can persist, unchanged, for hundreds or thousands of years.

The technology's fans point out that unlike the end-product of the still-theoretical "carbon capture" technology being proposed for coal power stations, biochar both stabilizes carbon and enhances the biological cycle that humanity depends on.

Studies around the world, including in Australia, have shown that adding the char to agricultural soils can boost water and nutrient retention and crop yields, and lower nitrous oxide emissions from fertilizer by 50-80pc.

The history of biochar explains what it is and its benefits.

Hundreds, sometimes thousands of years after they were created by people living in the Amazon basin of South America, the black soils known as 'terra preta‚' are still fertile to the point that some‚ 'like the Magic Pudding‚' regenerate after being harvested for potting mix.

Part of terra preta's secret, researchers believe, is the big quantities of slow-burned charcoal that people from ancient cultures dug into these soils.

Science is trying to recreate terra preta soils, so far unsuccessfully. But it seems that some of terra preta's qualities can be recaptured using biochar.

Biochar contains valuable nutrients that help plant growth, but its primary long-term benefit lies in its complex structure that holds big quantities of nutrients, moisture and microbes in a way that is still accessible to plants.

Biochar trials on maize at NSW Department of Agriculture's Wollongbar facility found that when applied at 10 tonnes per hectare, the char tripled the biomass of wheat and doubled that of soybean, while lifting soil pH and calcium levels and reducing aluminum toxicity.

There was more soil biology in the soil containing biochar, better water retention, and less carbon dioxide and nitrous oxide emissions.

However, CSIRO soil nutrient researcher Dr Evelyn Krull warns against treating biochar as a magic bullet for either carbon sequestration or agricultural productivity.

"Malcolm Turnbull is jumping the gun here a little bit, by saying that we need to do it now. I say there is potential, but let's get the fundamentals right," he said.

The qualities of biochar differ depending on its parent material, Dr Krull said, and the effects of biochar in different soil types is still to be established.

Nor has it been established that biochar can be produced cost-effectively enough to be attractive to farmers.

On Monday's edition of the ABC’s 7.30 report, climate change campaigner and chairman of the Copenhagen Climate Council, Professor Tim Flannery, questioned why the Federal government was throwing $600 million at developing coal carbon capture technology, yet failed to recognize biochar.

"You can quantify (biochar) to the nearest kilogram, you can put it in the soil and know it will stay there for thousands of years, we know it's safe and it's good for agriculture—why wouldn't we recognize that when we're happy to recognize a technology that isn't in existence yet?" Professor Flannery said.

Ironically, biochar development seems to have suffered in Australia because it has been closely associated with agriculture.

"Because we were lumped in with the agricultural sector, biochar hasn't been included in the Carbon Pollution Reduction Scheme (CPRS)," said Adriana Downie, technical manager with BEST Energies at Somersby, NSW.

"At the moment there's no motivation and no funding for anyone to research the true greenhouse accounting balance of this technology."

Using home-grown technology, BEST have developed a pilot plant that demonstrates the feasibility of biochar’s mass production from organic waste as diverse as poultry litter, nut shells and woody weeds.

Adding biochar to farm soils is ideal because it creates additional production benefits, Ms Downie said, but the product could equally be put in a hole in the ground: the primary benefit of biochar is that it creates highly stable carbon from organic matter that would otherwise decompose and return carbon dioxide to the atmosphere.

"If you can grow a forest, stabilize that forest carbon into biochar, and then regrow that forest, that’s a way to really bank those stocks of carbon," Ms Downie said.

"The fact that we were lumped in with agriculture (outside the CPRS) really isn’t fair. We want to see it go into farm soils, but the policy makers have got caught up in that and are missing the big picture."

BEST will continue to develop its home-grown biochar technology, but outcomes will be “perverted” in favour of syngas, the biofuel produced during biochar production, because that part of the technology can secure carbon credits to fund ongoing research.