Gav,

This is an excellent post. Certainly the sort of "carbon geosequestration" that I can live with!
;-)

I imagine that most of the scientific unknowns could easily be answered with only a fraction of our current "clean coal research" budget. (And if you ask me, I think plants will end up being the only workable solution to getting rid of our coal emissions, since I can't see people giving up their addiction to coal...)

While reading your article, I started to worry about "scalability", "centralisation", "transport" etc... And then it suddenly hit me. Biochar is an ideal decentralised solution!
;-)
- Have each wheat farmer put in a stand of the local eucalypts on a percentage of their land, set up a small processing plant and churn out their own biodiesel and topsoil dressing, as well as keeping the dreaded dryland salinity at bay. (Actually, why not put the biochar plant on wheels and trundle it between farms like a contract wheat harvester!)
- Plantation timber harvesters should have a mobile unit with them, making their fuel and eliminating most of the current CO2 emissions from waste burning, etc.etc.

Inspirational!

Yes, excellent post Gav. This is an important area of study. Here in the 4th corner of the U.S. we have some folks working on terra preta as well.

To add to your "Further Reading" list, check out "Charcoal, Agriculture and Climate Change" by Richard Haard, PhD. at the Energy Bulletin.
http://www.energybulletin.net/node/46029

Thanks for this great introduction to terra preta and its modern day variant.

We try to implement biochar at the tropical forest frontier, where the technique was first developed (thousands of years ago, not only in the Amazon, but there's evidence for it in Western Africa too) and where the first modern in-depth and longest running field trials can be found (near Manaus, running for over 5 years now). However, our focus is to try it out in Central Africa.

It is here that the concept possibly yields the greatest advantages, because farming on these nutrient-poor, acidic tropical soils is notoriously difficult. Because these soils lose their fertility so quickly, farmers are forced to engage in a slash-and-burn cycle. With increased population pressure, this type of farming is fueling deforestation, but it is also keeping these communities in extreme poverty.

So our focus is in Central Africa, where we aim to make biochar the core of an integrated sustainable development model. In theory, biochar should (1) maintain soil fertility, (2) thus reduce deforestation and short-circuit the slash-and-burn cycle, (3) strengthen food security (because yields also increase), (4) make available modern energy, yielding both electricity and char obtained from using field residues, which are currently burned (thus once more reducing deforestation, because local communities use wood), and, (5) as an interesting side-effect, sequester carbon permanently (possible carbon-credits could make the concept self-financing).

Obviously, this is a model, and many questions remain as to its viability. But if the model works, we perhaps have a concept that can tackle some of the most immediate problems amongst these communities (food insecurity, deforestation, soil destruction, energy insecurity, climate change), - simultaneously. Please do check it out, we would very much appreciate your input, thoughts, criticism and suggestions.

The "Biochar Fund" website can be found here: http://www.biocharfund.com .

Our ultimate aim is to transition from slash-and-burn systems in which a small number of low yielding crops is used, to a non-deforestation farming concept based on agro-forestry and reforestation. This way, we can sequester carbon in soils, and use these fertile soils to grow food trees on them, sequestering even more carbon.

The bacterial origin of biochar makes sense. The pre-Columbian Amerindians had a low energy, low physical technology culture , and this is the state upon which the west is about to embark.

Should this very elegant solution prove correct then one can envisage a simple path to a sustainable agriculture.

Place starter culture in several mulch pockets over the field and then feed the culture by felling the trees, shrubs and grasses that is the native covering of the field - leave to ferment and then you have a biologically active field that will sustain food crops for millenia.

The bacterial soup could harvest essential elements from the atmosphere and hold them in the soil for use by the plants.

Wow.. lets keep our fingers crossed.

A simple experiment would be to take a few cups of the original terra preta and place in mulch and see if it grows!!

For the small-scale, backyard gardener, activated charcoal is very expensive to buy. As I have a wood-burning fire for heating, I've taken to digging in the ashes & charred bits into the soil and/or compost heap. I have no idea if this is will encourage eventual formation of terra preta or whether I'm potentially damaging the soil instead. Has anyone else tried a low-tech, low-cost, backyard scale biochar implementation?

Great stuff Big Gav.

Jeff Vail's ideas about rhizome parallels stuff I've been pondering. My thinking was specifically non-hierachical.

a networked "grid," "lattice," or "peer-to-peer" structure of small, minimally self-sufficient villages, or "rhizome"

That's where we are going.

Would there also be an option to use available manufactured type appliances, for instance approximately ~1 kW with solar energy systems at the point of use. For example, the quick cooking time, requires relatively less energy. Where energy = power * time. Besides cultural and other issues, the solution would be, for instance, a photovoltaic array, inverter, charge controller, batteries, other balance of systems, ... simplifies the situation?

Hi Gav,
Great article and excellent links.
MEGO is the acronymn that certainly describes the reaction from folks when I introduce them to the concept of terra preta.
However that vanishes when they see my garden or taste its produce.
Below is a useful link from a blacksmith for building a retort than can produce appreciable amounts of charcoal if one has the area and tinkering skills.
It has inspired me to design and build retorts that generate steady amounts of char and help heat my home.
http://www.twinoaksforge.com/BLADSMITHING/MAKING%20CHARCOAL.htm

Another site for those wishing to produce char while driving about.
http://www.gengas.nu/byggbes/contents.shtml

Wow! I got all excited about this. I had read the Scientific American article, this brings back some ideas I had then.

I just wonder if I am missing something though.

"Carbon dating has shown them to date back between 1780 and 2260 years."

What then disturbed the system? It couldn't have been the european invasion - that is too recent. Why was such a successful farming system not still extensively in use when the europeans did invade?

I'll have to reread some of these links.

too tired tonight - I'll quote Mudd:

Dorme bien

Al

Its great to talk in quality but no practical work can be done without knowing some quantity detail. A few questions:

How many kg of coal is needed per acre of poor soil?

How much time it takes to become terra petra?

How much carbon is captured per acre? Is it once only carbon capture or do it happen every year?

You mentioned that terra petra soil is rich, how much yield increase it give in crops as compare to the surrounding poor quality non terra petra soil?

Keep up the great work. Can't change habit of thinking in numbers :).

I love to see people working with nature rather than against it. These types of projects tend to fend off destructive technologies by making such clearly helpful additions to the planet and our understanding of it. I chuckle to see so many people of a scientific bent marveling over the wonderful insights of the ancients. They had it right all along. I can only hope people continue to listen in egoless appreciation.

Very good work, Big Gav.

Great to see this getting such attention. One problem is the fire used in turning the biomass to charcoal. I believe it would be possible to sufficiently concentrate sunlight to replace all or most of the heat from fire. The idea might be called solar hydrous pyrolysis. See wikipedia for the hydrous part.
http://en.wikipedia.org/wiki/Hydrous_pyrolysis

Charcoal production can generate toxic waste if performed incorrectly.

That's not quite correct. Pyrolysis can produce toxic liquids even if performed correctly. It all depends on the feedstock used and the exact sort of process used.

In addition, if carbonization of biochar is done in a low tech way, then it usually leads to uncontrolled emissions, including tars which are highly toxic organic complexes. Do not try doing this at home!

The type of biomass and production conditions also have a major impact on the amount and composition of phytotoxic and potentially carcinogenic organic materials that are produced during pyrolysis (Lima A, Farrington J, and Reddy C. 2005. Combustion-derived polycyclic aromatic hydrocarbons in the environment: a review. Environ Forensics 6: 109–31)

Pyrolyzed oils and liquids can be carcinogenic and destructive to plant and animal life. You may like to take a look at the MSDS for pyrolyzed wood bio-oil

I hope this process will help combat GW, but we need the scientists to take the lead here. If they can determine a safe process and then implement it on an industrial scale, we may benefit. This is essentially a high-tech field of endeavour with great promise, but also significant dangers.

More reading: Biotox - toxicity and biodegradability of a representative bio-oil

Yes! Terra Preta!

One of my favorite odd subjects! Thank you for the article and thread!!

   I read the Nat. Geographic article when it came out and have been studying "soil life" (had never thought of it that way) and TP / bio-char and pyrolysis since learning about it all about a year ago. So many avenues, and possibilities. Carbon sequestration, fuel, heat, waste disposal (and of course, more waste).

   I also suspect the sometimes extended depth of the soil greatly enhances water retention, as well as the resilience of the microbial life-cycle within.

   As I posted above there are gardeners using charcoal in their soil already and having good results. Though I suspect that the soil being so old is part of what makes it so nutrient rich and hard to reproduce.... you need a few decades for it to evolve?

   I bought, and beat to shreds, a 40lb bag of natural charcoal the other week, to bury in the garden. - Calculated my Carbon footprint (CFP) to find that that 40lb bag compensates for only a day and half or so of my CFP! I'd need to spend about $15-25 a day to compensate for my existance! :D

Again, many thanks!

More links:

http://www.shimbir.demon.co.uk/biocharrefs.htm

International Biochar Initiative:
http://www.biochar-international.org/home.html

There's a long informative comment after this article, lots of links:
http://www.carboncommentary.com/2007/11/11/52

Quite a few years ago I read an article about Justus Von Liebig, who is the most important scientist in the advancement of modern chemical fertilizer industry. Here is a link to the article.

http://www.nutri-tech.com.au/blog/?p=375#more-375

As you can read, he realized the mistake to underestimate the role of carbon, but it was too late. Even today his error is ignored.

...Nitrate beds from Chile, potash mines from Germany and American phosphate deposits were sources for the initial N-P-K rush, but in a few short years chemical companies had begun to process and synthesise “the big three”. The profits in providing these new “essential” commodities, on a world stage, were stupendous. It was no surprise that, when a humbled von Leibig announced ten years later that he had made a huge mistake, his confession was completely ignored. Von Liebig had realised that a large part of the initial response to N-P-K fertilising was actually derived from the release of nutrients from the gradual breakdown of the humus component of the soil....

Whoa. Steady on.
Mamba up the thread has some good points on the science.
I am an (ex) agri scientist, and though my soil science is a while ago, a few points strike me.

The film I saw on TV of existing (still used) growing beds in Mayan territory (South America) showed essentially floating raised organic debris mats (beds), perhaps 2 or 3 meters thick. The human culture had created essentially a system for nutrient recycling (NPK + minor elements) supplemented or drained by the river.
There are several physical processes that hold nutrients in position in soil, and that help / degrade a soil's capacity to hold / lose nutrient ions from porous soil solution - cation exchange being very important. Some soils hold sequestered (unavailable to plant roots) large proportions of some of their mineral constituents - typically phosphates (hence the 'success' of inorganic soluble superphosphate, processed from mined rock phosphate from 19thC onwards}.
'Pretta' could be a useful additional medium for holding and / or mobilizing soil nutrients. If it also allowed some nitrogen-fixing soil bacteria to increase their N input, then that would be a bonus.
Whether there are bonuses to be had in other agricultural systems and in drier environments, ranging from cool temperate to dry tropics, remains for research to discover.
If a large proportion of nutrients in food are not recycled you will still need a 'primary' source of NPK. Clover and other legumes fix N from atmospheric N2, and soils often have reserves of P&K, if the latter can be made more labile, as in Western 'modern' (last 250 years) organic farming. (The fertilizer wars of the 19thC were mainly because organic agriculture production could not keep up with rapidly increasing urban populations.)
Do not confuse charcoal with humus.
Old, high-humus, pasture or mire or river-amended soils do provide a store of original nutrients and have been 'mined' historically until they become less fertile (think USA, Eastern England and etc). Their soil carbon has been oxidised gradually to CO2.
Big Gav, I see a typo, you say "Biochar is the term for what is left over after the energy is removed: a charcoal-based soil amendment - this process is called pyrolysis."
You mean 'some' of the energy is removed - like when coal was used to produce 'town gas', leaving coke.
Not a bad idea to sequester some long-life biomass 'coke', but 'success' depends on global numbers and whether we can afford turning over large areas to 'energy' biomass production.
best of luck
Phil
EDIT: if you burn wood for cooking on open fires or stoves, most (?) of the N is lost to the atmosphere but much of the P & K and trace elements are retained in the ash. The ash also contains a lot of 'charcoal' embers. I imagine this is what the Maya did. If they put the ash on their gardens, which they would do,being good gardeners, they were probably 'importing' P&K soil nutrients from the large surrounding areas of forests as well as accumulating gradually the 'pretta' in their soil.

A freind of mine works with Danny Day. He tends to emphasize that quite a lot can be learned about charcoal making from Japan, which had a number of technical programs during the war years whose liturature is worth translating. Anyone here who is good at reading technical books and papers in Japanese might be able to help out be contacting Danny Day's company that Big Gav linked above. You might have to help to write a grant though if you want to get payed.

Chris

I've been playing with terra preta for a number of years. First, here's a link to a post of mine about "Todd's Black Gold Method" from 2007 on TOD http://www.theoildrum.com/node/2410#comment-173726

My interest was first peaked because it appeared that tp held phosphorous which I saw as the one nutrient that I couldn't supply. Initially, I set up three beds with 0%, 2.5% and 5% charcoal (The charcoal was derived from mesquite barbeque charcoal that was so hard I had to run it through a chipper.) Since I couldn't afford a multitude of soil tests, my plan was to grow winter wheat in them since winter wheat won't head out without adequate phosphorous. So, the plan was to grow wheat on wheat until they stopped heading out.

After three years I had to stop it so I could rotate my potatoes to that bed since the bed they were in had wire worms.

But even in that short time I started to notice one difference; although head size didn't change, the wheat in the beds with charcoal was shorter depending upon the amount of charcoal. The 2.5% bed wheat was about 1-2" shorter while the wheat in the 5% bed was 3-4" shorter. The source of the N was calcium nitrate and the K was from green sand. No P was added.

In any case, I so believed in tp that I converted about 1,000 SF to tp. My charcoal comes from burning small slash piles from cutting firewood.

One side note is that I had discussed this with our county's deputy agricultural commissioner who is a friend. Last year his 6th grade daughter did a tp experiment for the county science fair. They used some charcoal I had given him and added it to soil along with fertilizer, with plain soil as a control. They then leached the test pots. They planted corn as the "crop." The results were that the corn in the tp pots grew far better.

I agree that there are a ton of unanswered questions. For example, does particle size matter? Does tp, indeed, hold nutrients? Does the temperature at which the charcoal is made matter? Is organic matter decomposed at a rapid rate (due to a more active rhizosphere)?

In any case, I'm a believer in terra preta. I still have another 1,000SF I'll be converting over the next few years.

Todd

Aside from the useful comments on biochar by Big Gav, the statement "however soil is renewable, so any "peak" should be able to be reversed if sufficient time and effort is put into doing so" is a truism impossible to achieve. The time required for soil formation greatly exceeds any human relevance. It is possible to upgrade the growing ability of residue from soil loss, but soil is a nonrenewable resource and should be treated as such.

FWIW, David Montgomery is one of the 2008 MacArthur Fellows (the US$500K genius awards), is essentially a soil scientist ("geomorphologist" is a higher order label), and wrote the recent book Dirt: The erosion of civilizations.

An earlier book in the same vein is soil scientist Daniel Hillel's Out of the Earth: Civilization and the Life of the Soil and his recent text Soil in the Environment: Crucible of Terrestrial Life

As a carbon sequestration method, bio-char is not very efficient compared to carbon capture(+85% efficient). A million tons of coal with CCS would fuel a ~250 MW power plant and release up to 550,000 tons of CO2 to the atmosphere.

The typical bio-char method is pyrolysis to 'bio-oil'(60%),
hot gases(30%) which are vented after pre-drying the biomass and char(10%).

Bio-oil is NOT petroleum but a black highly acidic gummy goo; to usual approach is to turn it into low BTU synthesis gas. Still, bio-oil can be easily stored.

1 million tons of biomass could produce 100000 tons of biochar and furnish oil to fuel a 125 MW power station for a year. One ton of biomass normally produces 1.8 tons of CO2.

Therefore, a 125 MW bio-char plant would release 1,620,000 tons of carbon dioxide, but would be carbon negative ASSUMING there would be no change in land use.

It would take 40 square miles of high yield Brazilian(tropical) sugar cane to produce 1000000 tons of biomass. Non-tropical biomass will be much less productive.

An acre of terra preta holds 150
more tons of carbon per acre than normal soil which has 100 tons of carbon in it.
Therefore 100000 tons of biochar per year would be spread over up to 660 acres, square mile every year.

Terra preta would probably work best in tropical countries with bio-oil being exported
as a carbon cap and trade chip. But as such it would be a threat to the ecology of rainforests and other undeveloped areas.

A 1000000 tons of biomass might produce either
140000 toe of cellulosic ethanol(70 gal per ton currently) or 260000 toe of bio-oil(bio-oil has 40% of the energy of diesel and contains 25% water and ash). If the bio-oil is then gasified and reconstituted by Fischer Tropsch methods(50% efficient), the 260000 toe would be reduced to about 130000 of petroleum type products. It's hard to see that other technologies could use bio-oil much better.

The fertilizing power of bio-char/terra preta is rather speculative but it may fix a certain amount of nitrogen in tropical soils. I doubt it can fix enough to support the large amounts of nitrogen used in modern mass agriculture, IMO.

Or is there evidence otherwise?

Soils are critical to the health of our planet and of course human survival. For a great read be sure to check "The Worst Hard Time".
http://www.amazon.com/Worst-Hard-Time-Survived-American/dp/061834697X

My father remembers living in Colorado during the Dust Bowl, although many of the lessons learned were ignored. In the book a farmer mentions that where ever you are standing, all the separates you from Hell is the thin layer of A horizon soil. Without that thin layer you are utterly doomed.

Of course in understanding any scientific subject we stand on the shoulders of giants, Darwin was here.
http://darwin-online.org.uk/EditorialIntroductions/Freeman_VegetableMoul...

Thanks for posting this.

There was one paper I saw a couple of months back, that reported on a counterintuitive net soil carbon loss, from a biochar experiment in Boreal Forest. (Note Boreal Forest is subarctic, think Canada/Russia, not prime farmland). Apparently the charcoal changed the soil ecology such that soil carbon was lost. I think the takeaway from this is that the benefit/damage from using biochar probably depends upons details of the local soil and climate, and perhaps on the details of the biochar process itself. I think this means that a lot of local research will be needed to determine the areas and crops for which the method is effective. My guess wrt carbon storage, is that we can probably absorb so small fraction of our current carbon emissions with this method, but I don't think it is a silver bullet. Just as in energy, it looks like their are no silver bullets, but all silver BBs should be pursued.

Hello TODers,

The US military command, AFRICOM, goes fully operational in October. Who knows what the future holds, but, IMO, Morocco's P is incredibly strategic at 47% of the total current global flowrate.

I really hope huge, Global progress can be made with TP,Biochar in the postPeak years ahead.

Bob Shaw in Phx,Az Are Humans Smarter than Yeast?

It is wishful thinking to believe that biochar is self-regenerating. Also, ascribing regeneration to mycorrhizae is unreasonable. Mycorrhizae do not perform pyrolysis. Rather, they consume plant carbohydrates for energy. Mycorrhhizae are heterotrophic and would not be in the business of intensive energy waste, by excreting reduced carbon.

The persistence of carbon char in Amazon basin soils is favored by anoxic and acidic conditions.

While charcoal itself is persistent, it speeds the decomposition of more fragile organic materials that are also present.

http://www.sciencemag.org/cgi/content/abstract/320/5876/629

The whole concept of sustainability seems to have come down to this: the pitting our twin champions of technology and science in a foot race against our own flawed human nature. The latter induces us to defile our environment while simultaneously out-populating the capacity of remaining resources to meet our needs.

In my view, unless we control our population all the feel good ideas and hopeful breakthroughs such as this one will, in the end, not be enough to save us. It's like a new, Malthusian version of the "Tortoise and the Hare" allegory. In this version, the tortoise still wins but because the hare is busy giving birth to its own extinction.