Showing posts with label rice paddies. Show all posts
Showing posts with label rice paddies. Show all posts

Thursday, September 25, 2008

Phillipine Terra Preta

This is a good field report on terra preta experimentation in the Philippines. This should be useful to many others trying the same thing.

My only comment is that I suspect rice paddy culture is a poor candidate because the paddies are nutrient sinks to begin with, or at the least should be.

I would like to see this work focus on depleted soils and implement a seed hill planting system to increase efficiency. He mentions the growing of corn, so the three sisters is possible here. I think that the three sisters will maximize performance and encourage adoption.

The three sisters is of course the combination of corn, beans and pumpkin in a seed hill carrying all the applied nutrients and manure.

My Projects in the Philippines by Jochen Binikowski

Terra Preta / Biochar Experiments

Making charcoal from rice husk

My name is Jochen Binikowski, from Hamburg, Germany. I am the consignee of Tigaon Handicraft, a small, family owned and run, handicraft business, based in Tigaon, Camarines Sur, Philippines, which is owned and managed by the family of my Filipina wife. Since 1980 I have regularly visited the Philippines.

As a sideline we have been conducting some trials in the local agricultural sector. Since February 2007 we have been experimenting with rice husk charcoal, with a view to improving local soils (Terra Preta) and the production of briquettes. The most common cooking fuels in Tigaon (42.000 inhabitants) are firewood, charcoal and liquified gas. The huge consumption of firewood and charcoal has resulted in the dramatic deforestration of the local rainforest at nearby Mt. Isarog. In the event that we are successful, these problems could become significantly reduced and hence, we are very willing to share our experience with others.

We are exclusively using agricultural waste as our raw material (biomass stream). So far we have experimented with rice husk, corn cobs, corn stems, coconut shells and waste wood from local carpenters. In order to dispose of this �waste�, these materials are typically burnt by local farmers.

Since January 2008 I am back in the Philippines. My brother in law, Elmer L. Orfanel is working with me on these experiments. He is an engineer and very creative in designing new equipment. In the meantime we are testing already our semi-commercial briquette press and charcoal production in drums, the kiln method. Both tests are very promissing so far.

Our current , most pressing priorities are the construction of a permanent site for pyrolysis. It will be designed in a way to accomodate a truckload of rice husks. The rice mills are happy to supply us free of charge because as of now they just dump it at remote places. We do have a feasible site where water, storage places, electricity etc. are abundant and which is far away from residents who might become affected from smoke. At this location we will also operate the briquette press and drying room. This will minimize the cost of transportation. At present our main problem is the lack of capital.

In commercial quantities we can use the process heat i.e. for a rice drier. This would solve another big problem that the smaller farmers suffer from, which is the post harvest losses due to a lack of drying equipment during rainy season. So far we have been using corn starch as our binding material. Provided the briquettes are completely dry they are getting very hard and are easy to store. They must be wrapped in paper to avoid absorption of air humidity. We do hope to reduce our drying time through higher pressure levels produced by the new briquette press. This is an important factor with regards to feasibility.

In order to become feasible the briquetts must compete with the existing fuel prices in Tigaon, 1 US$ = approx. 42 Peso

  • Firewood dried = 3 Peso/KG
  • Charcoal regular = 8 Peso/KG
  • Charcoal from coconut shells = 10 Peso/KG
  • 11 KG Gas bottle 660 Peso
  • Kerosin/Diesel 38 Peso/Liter
  • Electricity about 10 Peso/KWH (Industrial consumption)
  • Electricity about 14 Peso/KWH (Household consumption)

There are huge seasonal differences in the prices of firewood and charcoal. During the dry season (January to June) the market prices are much lower as opposed to the rainy season (July to December). The daily wages are very low: assistant 120 Peso, qualified worker 250 Peso, engineer 400 Peso.

The materials already tested yielded different heating values. So far the best was corn cobs, coconut shell, coconut trunks, bamboo and corn stems. The heating value was even higher than that of traditional charcoal. Rice husks had a much lower heating value due to the high silica (SiO2) content of more than 50%. But the rice husks are required as a filler material during pyrolysis anyway and moreover can be used for soil improvement (Terra Preta). We also did some experiments attempting to separate the SiO2 from the carbon, but so far without any success.

Some of the experiments were carried out just a short time before my departure back to Germany in June 2007. As such we have not yet acquired the proper heating test results for these materials integrated into the graph below.

In February 2007 we prepared 5 adjucent rice paddys at 4x5 meter size:

  1. Traditional planting 100% fertilizer
  2. 1 KG/sqm charcoal, 100% fertilizer
  3. 1 KG/sqm charcoal, 50% fertilizer
  4. 1 KG/sqm charcoal, no fertilizer
  5. 1 KG/sqm charcoal, 1 KG/sqm old compost, no fertilizer

Harvest gross weight of each paddy:

  1. 13,750 KG
  2. 14,175 KG
  3. 11,550 KG
  4. 10,475 KG
  5. 10,550 KG

According to these figures the positive effect of charcoal was just minimal and does not justify the additional expenses for production and distribution on the fields. After the harvest, the paddies were treated again in the same way with charcoal and rice was planted. But unfortunately this harvest was partly damaged by heavy rains and no proper result could be computed.

On April 7, 2008 we started a new rice experiment. Now we are using a special mixure of soil bacterias, complete fertilizer and charcoal for a seedbed starter. The Philippine Government is propagating a simmelar technique to the rice and corn farmers:

BIO-N Fertilizer

The BIO-N is also used in our control seedbeds. We expect initial results by end of April. After transplanting the seedlings the seedbeds will be used as an experimental field for potatoe planting. If this will work it could be a profitable alternative to rice planting during rainy season and it could reduced the emission of the greenhouse gas methane.

Vegetable planting experiments with charcoal enriched soil

In 2006 and 2007 we tried to plant several vegetable species in fields which where prepared using compost and charcoal. We had very confusing results: What was growing well in 2006, suffered drastically in 2007 and vice versa.

In 2008 we experienced big problems with our vegetable seeds. Most of them did not germinate. The lesson is not to store seeds for too long time... Actually we are just experimenting with different typs of lettuce in terra preta soil and it looks good so far.

We are still puzzled by the possible reasons as conditions were replicated to the best of our ability (ie. the same seeds, soil, season, climate conditions etc). At present I am preparing for a new trial. The target is to develop a method to minimize some of the common problems in vegetable farming:

  • Draught and flooding
  • Attacks by soil insects
  • Damages by fungi
  • Different soil conditions
  • Damages by Typhoones

Since we have an abundance of different raw materials , i.e. charcoal, compost, animal waste, seaweeds, lahar (volcanic stones and ashes) etc. what we can experiment with is different soil mixtures. This means the experiments can be reproduced at any location in the tropics. Empty cans, cut plastic bottles, plastic bags, rice bags and disposable plastic cups can be used as containers or pots.

Another target is to harvest out of season when prices are high. Since the pots are portable they can be temporarily transferred to safe places in case of typhoon warnings. We tried this successfully with a few tomato plants in 2006.

Thursday, April 17, 2008

Potatoes Rising

Sometimes, you forget what you know. I thank Terry Wade for reminding me that the potato revolution is long from over. The potato single handedly freed Europe from endemic famine and fed the population expansion from the seventeenth century to the present.

That China has made such a huge investment in potato production comes as a complete surprise. That India also will is another surprise.

Yet the logic is there. A mere acre of land can easily produce over a ton of potatoes. I know this from personal experience. It takes several acres to produce the equivalent in grains. This is why famine is no longer a real threat anywhere unless it is artificially caused.

The only difficulty is that at the subsistence level it takes a little more labor than almost any other crop. For the uninitiated, besides cutting seed eyes and planting them several inches deep, one has to also hill the rows at least twice, if not three times, normally by hand with a hoe. However, an acre of such work is not onerous and it is the best payoff in the household garden with enough for a family all winter.

It also solves another issue that I was mulling over. Subsistence level biochar production with corn root earthen kilns requires a sister crop to plant every second season at the least. The Amazon Indios were able to use cassava in the rainforest. This is an unlikely option elsewhere. The fact is that the potato is suitable everywhere else that you are able to grow corn.

Thus in one season the land can produce a ton of corn and in the next season a couple tons of potatoes. If one is additionally growing legumes with the corn as in the three sisters system, then the soil is getting a nitrogen boost.

Returning to my favorite tropical soils that are today a disaster, this growing protocol has one other advantage. Freshly cleared and broken soil requires a great deal of working in order to provide a quality seedbed. The extra hilling needed for potatoes does exactly this.

I once converted a section of lawn into a planting bed by first breaking and turning the sod deeply enough to give me several inches of working soil. I then planted potatoes. By season’s end I had a fine seedbed. The potatoes were scarred from a too biologically active soil but by then I knew how to work with the resultant soil. And I had my bed. I would recommend this process to any hobby gardener who wants to restore flower beds.

I am optimistic that huge tracts of tropical soils can be brought into continuous cultivation using this virtuous corn potato protocol producing viable livelihoods for a couple of billion people at least. I would expect to feed a family of several mouths on perhaps two to three acres of tropical soils that once could only give one crop in fifteen years. Just three growing seasons per year with one crop of corn and two crops of potatoes would produce about ten tons of potatoes and likely a couple of tons of corn on two to three acres of land. I suspect that this is much more productive than a rice paddy.

As other staples soar, potatoes break new ground

TERRY WADE
Reuters

April 16, 2008 at 9:04 AM EDT
LIMA — As wheat and rice prices surge, the humble potato - long derided as a boring tuber prone to making you fat - is being rediscovered as a nutritious crop that could cheaply feed an increasingly hungry world.

Potatoes, which are native to Peru, can be grown at almost any elevation or climate: from the barren, frigid slopes of the Andes Mountains to the tropical flatlands of Asia. They require very little water, mature in as little as 50 days, and can yield between two and four times more food per hectare than wheat or rice.

"The shocks to the food supply are very real and that means we could potentially be moving into a reality where there is not enough food to feed the world," said Pamela Anderson, director of the International Potato Center in Lima , a non-profit scientific group researching the potato family to promote food security.

Like others, she says the potato is part of the solution.

The potato has potential as an antidote to hunger caused by higher food prices, a population that is growing by one billion people each decade, climbing costs for fertilizer and diesel, and more cropland being sown for biofuel production. To focus attention on this, the United Nations named 2008 the International Year of the Potato, calling the vegetable a "hidden treasure."

Governments are also turning to the tuber. Peru's leaders, frustrated by a doubling of wheat prices in the past year, have started a program encouraging bakers to use potato flour to make bread. Potato bread is being given to school children, prisoners and the military, in the hope the trend will catch on.

Supporters say it tastes just as good as wheat bread, but not enough mills are set up to make potato flour.

"We have to change people's eating habits," said Ismael Benavides, Peru's agriculture minister. "People got addicted to wheat when it was cheap."

Even though the potato emerged in Peru 8,000 years ago near Lake Titicaca, Peruvians eat fewer potatoes than people in Europe: Belarus leads the world in potato consumption, with each inhabitant of the Eastern European state devouring an average of 171 kilograms a year.

India has told food experts it wants to double potato production in the next five to 10 years. China, a huge rice consumer that historically has suffered devastating famines, has become the world's top potato grower. In Sub-Saharan Africa, the potato is expanding more than any other crop right now.

The developing world is where most new potato crops are being planted, and as consumption rises poor farmers have a chance to earn more money.

"The countries themselves are looking at the potato as a good option for both food security and also income generation," Ms. Anderson said.

The potato is already the world's third most-important food crop after wheat and rice. Corn, which is widely planted, is mainly used for animal feed.

One factor helping the potato remain affordable is the fact that unlike wheat, it is not a global commodity, so has not attracted speculative professional investment.

Each year, farmers around the globe produce about 600 million tonnes of wheat, and about 17 per cent of that flows into foreign trade.

Wheat production is almost double that of potato output. Analysts estimate less than 5 per cent of potatoes are traded internationally.

Raw potatoes are heavy and can rot in transit, so global trade in them has been slow to take off. They are also susceptible to infection with pathogens, hampering export to avoid spreading plant diseases.

But science is moving fast. Genetically modified potatoes that resist "late blight" are being developed by German chemicals group BASF. Scientists say farmers who use clean, virus-free seeds can boost yields by 30 per cent and be cleared for export.

Touting the tubers

257.25 million - World potato production in 1991 (tonnes)
320.71 million - World potato production in 2007 (tonnes)
110 - Number of calories in a medium-sized potato.
5 - Number of kilograms of potatoes needed to produce one litre of vodka.

Sources: Reuters, UN Food and Agriculture Organization

Top potato producers

In 2007, in millions of tonnes: China 72, Russian Fed. 35.7, India 26.3, Ukraine 19.1, U.S. 17.7, Germany 11.6, Poland 11.2, Belarus 8.5, Netherlands 7.2, France 6.3

Source: UN Food and Agriculture Organization

Wednesday, August 29, 2007

Methane fears

We have had a lot of enthusiasm for methane lately for its potential as a so called greenhouse gas.

http://www.physicalgeography.net/fundamentals/7a.html


Methane is a very strong greenhouse gas. Since 1750, methane concentrations in the atmosphere have increased by more than 150%. The primary sources for the additional methane added to the atmosphere (in order of importance) are: rice cultivation; domestic grazing animals; termites; landfills; coal mining; and, oil and gas extraction. Anaerobic conditions associated with rice paddy flooding results in the formation of methane gas. However, an accurate estimate of how much methane is being produced from rice paddies has been difficult to ascertain. More than 60% of all rice paddies are found in India and China where scientific data concerning emission rates are unavailable. Nevertheless, scientists believe that the contribution of rice paddies is large because this form of crop production has more than doubled since 1950. Grazing animals release methane to the environment as a result of herbaceous digestion. Some researchers believe the addition of methane from this source has more than quadrupled over the last century. Termites also release methane through similar processes. Land-use change in the tropics, due to deforestation, ranching, and farming, may be causing termite numbers to expand. If this assumption is correct, the contribution from these insects may be important. Methane is also released from landfills, coal mines, and gas and oil drilling. Landfills produce methane as organic wastes decompose over time. Coal, oil, and natural gas deposits release methane to the atmosphere when these deposits are excavated or drilled.

Table 7a-1: Average composition of the atmosphere up to an altitude of 25 km.

Gas Name

Chemical Formula

Percent Volume

Nitrogen

N2

78.08%

Oxygen

O2

20.95%

*Water

H2O

0 to 4%

Argon

Ar

0.93%

*Carbon Dioxide

CO2

0.0360%

Neon

Ne

0.0018%

Helium

He

0.0005%

*Methane

CH4

0.00017%

Hydrogen

H2

0.00005%

*Nitrous Oxide

N2O

0.00003%

*Ozone

O3

0.000004%

I want you to observe that everything in this list is at its lowest oxygenation level with the sole exception of methane. Also observe that CO2 is 200 times more available. This is true because methane is almost as good a rocket fuel as hydrogen. We usually call it natural gas when we use it to heat our homes. In fact, it is the one gas that has all the cards stacked against its survival.

Even with all the rice paddies, termites and cows hard at work producing methane and all the plants on earth consuming CO2 and nothing consuming methane except oxidizers, CO2 content exceeds CH4 content by a factor of 200.

This entry also makes the claim that since 1750, methane content has increased 150%. Who was measuring? Most certainly this has to be an educated guess linking human population growth and normal related agricultural usage to the current regime. In other words, rubbish has discovered a neat new way to produce methane.

The point is that CH4 is produced in normal biomass combustion and almost as swiftly consumed. This is not true at all for carbon dioxide.

Yesterday we addressed sustainable biochar production. Much concern was expressed over the production of combustibles like CH4 that will escape into the atmosphere. And a natural earthen field kiln will lose a lot of combustibles in this manner and not just methane. My description of the inexpensive modified incinerator design took advantage of that out gassing to fuel a second high temperature oven whose heat was then used to accelerate the carbonization process.

That solution is possibly available to industrialized agriculture. It is certainly not an option for everyone else, and may be suspect even were the equipment is available. Of course even more expensive systems can be deployed for a very small incremental gain.

The point that I want to make is that the primitive earthen kiln and my incinerator are separated only by efficiency. I would reasonably expect perhaps twice as much product to be produced. This cannot be accomplished with a sharp increase in haulage costs. I also point out that the jury is truly out as to the quality of the end product. The kiln promises to produce a more uniform end product but that may not be as advantageous.

In either case, gases are produced once a year for any plot of land and are then swiftly mopped up by the local environment.

The objective after all is to put carbon into the soil for a long time. Both these techniques do just that. The only other technique that convincingly does the same thing is the growth of new forests. Every other agricultural process that we have created is in a constant struggle to just maintain carbon content and related fertility. Terra preta promises to end this ten thousand year struggle forever.

Every subsistence farmer now has the option of either burning all his plant waste out in the open field as he has done forever, or building an earthen kiln and producing a few tons of Biochar as fertilizer for next year’s crop. He does not need a dime from his government to do this nor does he need any special equipment that he does not already have. He had no other choice before and has been the source of monster smoke clouds out of Asia’s rainforests. Now those smoke clouds can become a fraction of what they are today while he mops up the carbon for us and strengthens his farms fertility.