Biochar Refresher

As my older readers know, I stumbled into the biochar enterprise a month after I started into this blog. At the time there was scholarly effort underway and a modest level of activity on a forum as well as a couple of popular science articles about. At the time I intro’d the forum to a popular science oriented site and this gave both the forum and my modest blog a good boot in traffic. Or at least as far as this observer was able to reasonably discern. I followed that up with a several posts that reconstructed the possible production methodology available to the Amazonians. The proposed method was to use dried out maize stalks to form robust earthen kilns from the large mass of corn stover, otherwise burned. This has continued to stand the test of time as understanding improves.

Most commentators have been trapped into idea that the biochar was formed from the manufacture of charcoal. I suspect that this is completely wrong. Wood charcoal is less attractive for soil work than you might imagine because the majority is in the form of difficult to pulverize chunks. Using such chunks as cooking fuel is a way more likely outcome. The feedstock was any form of non woody plant material that could be packed easily. Biochar is low temperature carbonization of non woody plant material. And corn is still the most convenient feedstock today. The expanding crowd of enthusiasts is now visibly catching up to this position.

We have learned from Amazon reports that there were two field practices indicated. The first called terra preta was concentrated in the household garden and was clearly an ongoing practice that caught everything going out the back door and all garden waste. I suspect that this led to the perfection of the earthen kiln method. A lot of pottery occurs reflecting the centuries of occupation and the lousy quality of the pottery. The fact that it was a way of reducing the family waste explains why so much was actually produced. It is actually a wonderful solution for human waste in particular that could be applied in India today.

The second was the exploitation of larger community fields in which occasional biochar was introduced to sustain fertility and this is known as terra mulatto. No pottery is observed, eliminating the need to explain its presence at all. It is not hard to reconstruct a crop rotation system that would exploit corn and earthen kilns to make this happen.

What I am saying is, that once you quit thinking wood, it becomes an easy system to apply with even no tools except dirt baskets since corn brings its own dirt pad. And recently, we discovered that in the Cameroon natives cut and bury long windrows of elephant grass which they then cover with dirt. Likely by digging a trench first and then throwing the soil back on top of the baled grass. They then ignite one end and let it all burn through, collapsing the dirt on top of the biochar as it is produced.

The other large plus in using a natural earthen kiln is that the design allows creation of a burn front that burns out all the volatiles eliminating most problems with pollution by reduction to CO2. That certainly is the result the elephant grass kiln. Thus we have a natural system that consumes the volatiles safely while converting the rest into low reactive carbon and carbon compounds much of which sequesters for centuries.

SPECIAL REPORT

'Biochar' might help ease global warming

Posted: 17 Mar 2009

http://www.peopleandplanet.net/doc.php?id=3522

As multibillion-dollar projects intended to sequester carbon dioxide (CO2) in deep geologic storage continue to seek financial support, the fertile black soils in the Amazon basin suggest a cheaper, lower-tech route toward the same destination. Here David J. Tenenbaum looks at the potential of charcoal, in the form of 'biochar', to help soak up climate-changing gas in the atmosphere.

Scattered patches of dark, charcoal-rich soil known as terra preta (Portuguese for "black earth") are the inspiration for an international effort to explore how burying biomass-derived charcoal, or "biochar," could boost soil fertility and transfer a sizeable amount of CO2 from the atmosphere into safe storage in topsoil.

Although burial of biochar is just beginning to be tested in long-term, field-scale trials, studies of Amazonian terra preta show that charcoal can lock up carbon in the soil for centuries and improve soil fertility.

Charcoal is made by heating wood or other organic material with a limited supply of oxygen (a process termed 'pyrolysis'). The products of the pyrolysis process vary by the raw material used, burning time, and temperature, but in principle, volatile hydrocarbons and most of the oxygen and hydrogen in the biomass are burned or driven off, leaving carbon-enriched black solids with a structure that resists chemical and microbial degradation.

Christoph Steiner, a research scientist at the University of Georgia, says the difference between charcoal and biochar lies primarily in the end use. "Charcoal is a fuel, and biochar has a nonfuel use that makes carbon sequestration feasible," he explains. "Otherwise there is no difference between charcoal carbon and biochar carbon."

Charcoal is traditionally made by burning wood in pits or temporary structures, but modern pyrolysis equipment greatly reduces the air pollution associated with this practice. Gases emitted from pyrolysis can be captured to generate valuable products instead of being released as smoke. Some of the by-products can be condensed into "bio-oil," a liquid that can be upgraded to fuels including biodiesel and synthesis gas. A portion of the noncondensable fraction is burned to heat the pyrolysis chamber, and the rest can provide heat or fuel an electric generator.

Pyrolysis equipment now being developed at several public and private institutions typically operate at 350–700°C. In Golden, Colorado, Biochar Engineering Corporation is building portable $50,000 pyrolyzers that researchers will use to produce 1–2 tons of biochar per week. Company CEO Jim Fournier says the firm is planning larger units that could be trucked into position. Biomass is expensive to transport, he says, so pyrolysis units located near the source of the biomass are preferable to larger, centrally located facilities, even when the units reach commercial scale.

Better soil

Spanish conquistador Francisco de Orellana reported seeing large cities on the Amazon River in 1541, but how had such large populations raised their food on the poor Amazonian soils? Low in organic matter and poor at retaining plant nutrients — which makes fertilization inefficient — these soils are quickly depleted by annual cropping. The answer lay in the incorporation of charcoal into soils, a custom still practiced by millions of people worldwide, according to Steiner. This practice allowed continuous cultivation of the same Amazonian fields and thereby supported the establishment of cities.

Researchers who have tested the impact of biochar on soil fertility say that much of the benefit may derive from biochar’s vast surface area and complex pore structure, which is hospitable to the bacteria and fungi that plants need to absorb nutrients from the soil. Steiner says, "We believe that the structure of charcoal provides a secure habitat for microbiota, which is very important for crop production." Steiner and coauthors noted in the 2003 book Amazonian Dark Earths that the charcoal-mediated enhancement of soil caused a 280–400 per cent increase in plant uptake of nitrogen.

The contrast between charcoal-enriched soil and typical Amazonian soil is still obvious, says Clark Erickson, a professor of anthropology at the University of Pennsylvania. Terra preta stands out, he says, because the surrounding soils in general are poor, red, oxidized, and so rich in iron and aluminum that they sometimes are actually toxic to plants. Today, patches of terra preta are often used as gardens, he adds.

Anna Roosevelt, a professor of anthropology at the University of Illinois at Chicago, believes terra preta was created accidentally through the accumulation of garbage. The dark soil, she says, is full of human cultural traces such as house foundations, hearths, cemeteries, food remains, and artifacts, along with charcoal. In contrast, Erickson says he’s sure the Amazonian peoples knew exactly what they were doing when they developed this rich soil. As evidence, he says, "All humans produce and toss out garbage, but the terra preta phenomenon is limited to a few world regions."

Recent studies show that, although biochar alone does not boost crop productivity, biochar plus compost or conventional fertilizers makes a big difference. In the February 2007 issue of Plant and Soil, Steiner, along with Cornell University soil scientist Johannes Lehmann and colleagues, demonstrated that use of biochar plus chemical amendments (nitrogen–phosphorus–potassium fertilizer and lime) on average doubled grain yield over four harvests compared with the use of fertilizer alone.

Banking Carbon

Reseachers have come to realize the use of biochar also has phenomenal potential for sequestering carbon in a warming world. The soil already holds 3.3 times as much carbon as the atmosphere, according to a proposal Steiner wrote for submission to the recent UN climate conference in Poznan, Poland. However, Steiner wrote, many soils have the capacity to hold probably several hundred billions of tons more.

Plants remove CO2 from the atmosphere through photosynthesis, then store the carbon in their tissues. CO2 is released back into the atmosphere after plant tissues decay or are burned or consumed, and the CO2 is then mineralized. If plant materials are transformed into charcoal, however, the carbon is permanently fixed in a solid form — evidence from Amazonia, where terra preta remains black and productive after several thousand years, suggests that biochar is highly stable.

Carbon can also be stored in soil as crop residues or humus (a more stable material formed in soil from decaying organic matter). But soil chemist Jim Amonette of the Department of Energy’s Pacific Northwest National Laboratory points out that crop residues usually oxidize into CO2 and are released into the atmosphere within a couple of years, and the lifetime of carbon in humus is typically less than 25 years.

Four scenarios for carbon storage have been calculated by the nonprofit International Biochar Initiative (IBI). The "moderate" scenario assumed that 2.1 per cent of the earth's annual total photosynthesized carbon would be available for conversion to biochar, containing 40 per cent of the carbon in the original biomass. It estimates that incorporating this charcoal in the soil would remove half a billion metric tons of carbon from the atmosphere annually.

Because the heat and chemical energy released during pyrolysis could replace energy derived from fossil fuels, the IBI calculates the total benefit would be equivalent to removing about 1.2 billion metric tons of carbon from the atmosphere each year. That would offset 29 per cent of today’s net rise in atmospheric carbon, which is estimated at 4.1 billion metric tons, according to the Energy Information Administration.

Ordinary biomass fuels are carbon-neutral — the carbon captured in the biomass by photosynthesis would have eventually returned to the atmosphere through natural processes; burning plants for energy just speeds it up. Biochar systems can be carbon-negative because they retain a substantial portion of the carbon fixed by plants.

Simple technology

It is these large numbers — combined with the simplicity of the technology — that has attracted a broad range of supporters. At Michigan Technological University, for example, undergraduate Amanda Taylor says she is "interested in changing the world" by sequestering carbon through biochar.

Under the guidance of Department of Humanities instructor Michael Moore, Taylor and fellow students established a research group to study the production and use of biochar as well as how terra preta might fit into a framework of community and global sustainability. Among other projects, the students made their own biochar in a 55-gallon drum and found that positioning the drum horizontally produced the best burn.

The numbers are entirely theoretical at this point, and any effort to project the impact of biochar on the global carbon cycle is necessarily speculative, says Lehmann. "These estimates are at best probing the theoretical potential as a means of highlighting the need to fully explore any practical potential, and these potentials need to be looked at from environmental, social, and technological viewpoints. The reason we have no true prediction of the potential is because biochar has not been fully tested at the scale that it needs to be implemented at to achieve these predictions."

Still, Steiner stresses that other large-scale carbon-storage possibilities also face uncertainties. "Forests only capture carbon as long as they grow, and the duration of sequestration depends very much on what happens afterward," he says. "If the trees are used for toilet paper, the capture time is very short." Soilborne charcoal, in contrast, is more stable, he says: "The risk of losing the carbon is very small — it cannot burn or be wiped out by disease, like a forest."

As a carbon mitigation strategy, most biochar advocates believe biochar should be made only from plant waste, not from trees or plants grown on plantations. "The charcoal should not come from cutting down the rainforest and growing eucalyptus," says Amonette.

Mitigation strategy

Biochar took a step toward legitimacy at the December Poznan conference, when the UNCCD placed it in consideration for negotiations for use as a mitigation strategy during the second Kyoto Protocol commitment period, which begins in 2013.

Under the cap-and-trade strategy that forms the backbone of the Kyoto Protocol, businesses can buy certified emission reduction (CER) credits to offset their emissions of greenhouse gases. If biochar is recognized as a mitigation technology under the Kyoto Clean Deveopment Mechanism, people who implement this technology could sell CER credits.

The market price of credits would depend on supply and demand; a high enough price could help promote the adoption of the biochar process.

The possibility that the United Nations will give its stamp of approval to biochar as a climate mitigation strategy means the ancient innovation may finally undergo large-scale testing. "The interest is growing extremely fast, but it took many years to receive the attention," says Steiner. "Biochar for carbon sequestration does not have strong financial support compared to carbon capture and storage through geological sequestration. [However,] biochar is much more realistic for carbon capture."

This is a shortened version of an article which first appeared in Environmental Health Perspectives Volume 117, Number 2, February 2009
To find out more about the potential of biochar look out for the publication by Earthscan next month (April) of 'Biochar for Environmental Management: Science and Technology'Edited by Johannes Lehmann and Stephen Joseph. (Hardback £49.95)

Benny Peiser heralds end of Kyoto

This article by Benny Peiser was published this morning in the Financial Post. The Kyoto circus continues on to its inevitable demise amid rancor and recrimination. It could only fail from inception since the business model is grossly flawed and completely an invitation to greed and stupidity. What were they thinking?

As I have intimated but not perhaps fully enunciated, the carbon economy can be made to work for everyone provided everyone participates and provided the business model is simple enough to apply universally. I have described such a model.

It is enough that all carbon emitters buy offsetting carbon credits on the open market without exception. It is enough that a licensing system be put in place to permit the origination and sale of these credits worldwide. The brokers will be quite happy to take care of the details and prices will soon sort themselves out.

Every farmer in the world can then become a carbon credit granter by simply manufacturing terra preta soils using corn or maize culture as I have already described. On top of all that, a good way to place foreign aid money is to simply use it to buy carbon credits from third world farmers at market prices. This will slowly sponge up a surplus over actual production rolling back the CO2 surplus.

It is an absolute waste of time and resources to attempt to make this happen from further up the food chain which is the fatal flaw with Kyoto. Making the rich pay has always resulted in the poor dying.

If an international consensus is impossible, then internal national deals can go a long way toward obviating the problem. For example, Canada has a huge CO2 production problem, thanks to the fact that we are on the way to becoming the global oil reserve backstop. If we convert all our land capable of growing corn into terra preta soils, it will take a minimum of twenty years and create the most fertile soils on earth, effectively doubling agricultural production.

This then becomes a classic case of the rich getting richer. I suspect that all developed countries can benefit by taking this approach, even to the extent of successfully offsetting the entire problem. It is just that it would be more satisfying to use this need to lift two billion people out of the subsistence lifestyle globally over the next two generations.

Any other approach is no more than cash grabs by stupid and greedy elites. I get tired of listening to it.

Climate blowback

The CO2 crusade only generates hostility against the West; Benny Peiser

Financial Post Published: Tuesday, April 08, 2008

Imagine, there is a UN climate conference, and hardly anybody seems to note or care. This is what appears to have happened with the latest round of post-Kyoto negotiations that ended in Bangkok last Friday. While delegates from more than 160 nations met at yet another United Nations Framework Convention on Climate Change confab in the Thai capital, much of the media seemed indifferent to its deliberations or did not bother to report about it.

What used to be major environmental gatherings that would trigger global media hype and front-page headlines has turned into routine diplomatic meetings that wrap up, these days, on more or less the same note: Let's meet again. Eight more such meetings are planned for the next 18 months to negotiate a replacement for the Kyoto Protocol, which runs out in 2012.

Instead of the passionately celebrated "breakthroughs" that used to be the hallmark of international climate conferences, today they often end in deadlock and disappointment.

At the heart of the solidifying standoff lies a growing realization that the entire Kyoto process has been an abject failure. Not only did it fail to slow (never mind reduce) carbon-dioxide emissions over the last 15 years or so, climate hysteria is pitting rich and poor nations against each other, dividing the world into opposing camps that embrace incompatible strategies and competing demands.

Developing nations insist that the rich world unilaterally commit to stringent and legally binding CO2 emissions cuts at home. At the same time, they also demand massive wealth transfers from the West in the form of 'clean' technologies and financial funds for adaptation and energy initiatives.

The self-inflicted damage as a result of Western climate policies has been ruinous. Japan alone faces a Kyoto bill of more than US$500-billion -- if the country endeavours to cut CO2 emissions by 11% over the next decade. No wonder, then, that Japan has officially given up on Kyoto and is now calling for a much softer replacement based on select sectoral, rather than national emission targets.

In Europe, too, policy-makers and business leaders now realize that the European Union's unilateral actions are threatening to drive energy-intensive industries abroad. According to recent estimates, European industries are expected to shoulder ¤50-billion to ¤80-billion ($128-billion) per year if the EU's agreed climate targets were to become legally binding. Unsurprisingly, the European Commission has now warned that it will abandon its own goals if the rest of the world won't agree to a new climate treaty.

These staggering costs, however, pale in comparison with what China and the developing nations are demanding for their signature under any new climate treaty. Arguing that Europe, Japan and North America have caused much of the buildup of the world's CO2 emissions in the atmosphere over the last century or so, China has called on Western nations to hand over 0.5% of their GDP per year in form of funds and clean-technology transfer to developing nations to counter global warming. China's demand amounts to a wealth transfer of around US$200-billion a year from the OECD to the rest of the world, of which US$65-billion annually would come from the United States alone.

China's exorbitant request, however, has been eclipsed by demands by African campaigners, who are charging a payback that is twice as high. At the Bangkok meeting, African non-governmental organizations called on rich countries to commit 1% of their GDP each year -- for Africa alone -- for adaptation policies dealing with the effects of climate change, in addition to existing development aid.

In response to mounting pressure and demands, the West is trying to divide the developing world by treating China and India differently to poorer countries. It is attempting to draw China and India, now defined as "major emitters," into an

Stop already! We are not going to reduce CO2 emissions until every human being is rich or the oil actually runs out, whichever comes first. But we can sequester it all in farm soils forever.

international regime of binding emissions cuts. Despite many years of self-righteous denunciation and disagreement, most industrialized countries have begun to band together around Tony Blair's and President George Bush's long-established strategy, which is beginning to enjoy bipartisan support in most Western capitals. Even in Washington there is now a solid bipartisan consensus on this red line. This hardening stance means that any climate treaty that does not include China and India has absolutely no chance of being ratified by the U.S. Senate -- regardless of whom the next U.S. president may be.

Nevertheless, the West's feeble response to international pressure is a defensive strategy. It is looked upon with bitterness in many parts of the world where climate campaigners have created a mood of anti-American anger and resentment. While the Western approach may be able to corner the rising giants of China and India, it will almost certainly fail to compel them to commit to legally binding emissions cuts-- in whatever form.

As a result of promoting environmental alarmism, Western governments find themselves trapped in a perilous, yet largely self-constructed catch. As long as climate change is elevated as the principal liability of industrial countries, as long as Western CO2 emissions are blamed for exacerbating natural disasters, death and destruction around the globe, green pressure groups and officials from the developing world will continue to insist that the West is liable to recompense its exorbitant carbon debt by way of wealth transfer and financial compensation.

Yet this is highly unlikely to happen. Attempts to punish developing countries by introducing carbon tariffs, on the other hand, would only create more fury and resentment. Ultimately, there is now a growing risk that the whole global-warming scare is creating more anti-Western hostility and further loss of influence on the international stage.

Unless the industrial nations are prepared to sacrifice a substantial fraction of their wealth and economic stability, it is extremely unlikely that a new climate treaty will be agreed upon in the foreseeable future. While rich countries will put the blame squarely at the door of their Asian competitors, much of the rest of the world is likely to point the finger at Western greediness and intransigence. In this way, the global warming scare is creating a lose-lose situation for the West which is causing lasting damage to its standing, influence and economic strength.

-Benny Peiser is the editor of CCNet, an international science-policy network.