Soil Charcoal Amendments to Maintain Soil Fertility and Fix Carbon

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Soil Charcoal Amendments to Maintain Soil Fertility and Fix Carbon CSD 16 New York 9 May 2008 UNCCD Learning Course http://www.ecoworld.com/maps/world_ecoregion.cfm Scenarios for Major Eco-Regions Christoph Steiner Biorefining and Carbon Cycling Program Global problems soil degradation peak oil Hubbert s Peak in 2007 FAO's global food price index rose 40% to the highest level on record World fertilizer prices surge 200% International Center for Soil Fertility and Agricultural Development, IFDC Climate change Dedicating land to biofuels increases carbon emissions Corn-based ethanol doubles greenhouse gas emissions over 30 years Searchinger et al. 2008, Science

Soil degradation Agriculture without mineral fertilizers maintaining SOC The soil C pool is 3.3 times the size of the atmospheric pool and 4.5 times the size of the biotic pool. Lal 2004, Science Haber-Bosch mineral fertilizers Justus von Liebig mineral nutrition of plants and Haber Bosh process N 2 + 3H 2 2NH 3 (http://www.liebig-museum.de) Consumes 3.35% of world natural gas production = 0.75% of the world's energy supply Boosted agricultural production and replenished nutrient stocks but did not treat soil degradation caused by SOC loss

Soil degradation mineral fertilizers further decline in SOC Laurens Rademakers www.biopact.com Most agricultural soils have lost 60 to >75% (20 80 Mg ha -1 ) of their original SOC (Lal, 2004, Science) From 1750 the emissions form land use change contributed about 30% to global warming, from which more than half of it is estimated from depletion of SOC (Lal, 2003). Example I Chernozem or mollisol http://members.eunet.at/rosenkranz/lysi/lysi1.htm Most agriculturally productive soils (Duchaufour, 1998) (5. 12. 2004 world soil day, Schwarzerde = soil of the year 2005) Residues from vegetation fires, such as black carbon (BC) (Glaser et al., 2000) BC constituting up to 45% of the SOM BC is several millennia in age (Schmidt et al., 2002) www.klett-verlag.de

Example II Terra Preta Cash crop farming Irrigated horticulture lawn production Terra Preta fertility

Charcoal Carbon Sink Long lasting carbon sequestration B 100 Carbon remaining (%) 50 10 Bio-char Un-charred organic matter 1 2 3 4 5 JOHANNES LEHMANN, JOHN GAUNT, and MARCO RONDON Mitigation and Adaptation Strategies for Global Change Lehmann 2006 et al. 2006 Years Values of SOM Charcoal Nutrient content Carbon sink CDM Easy quantifiable Soil Quality maintenance and improvement of water infiltration Water holding capacity Structure stability Nutrient storage and supply Healthy soil biological activity

Biochar Research Terra Preta Nova EMBRAPA research station Brazil Research results Increased yields with biochar Lehmann and Rondon 2006, Steiner et al 2007, Plant and Soil Increased retention of fertilized nitrogen = fertilization efficiency Lehmann et al 2003, and Steiner et al 2008 Reduced GHG emissions (CH 4 and N 2 O) form soil Marco A. Rondón, Juan A. Ramirez, Johannes Lehmann, USDA Symposium on C sequestration. Baltimore, March 24, 2005 Reduced acidity Topoliantz et al 2005, Steiner et al 2007 Increased mineral nutrition (mainly K) Steiner et al 2007 Increased colonization rates my mycorrhizal fungi Warnock et al. 2007, Plant and Soil

Biochar Production The simple way Biochar Production in a cooking stove Clean and efficient Robert Flanagan, SAFFE

Biochar as byproduct from cooking Robert Flanagan, SAFFE Corn cobs biomass/biochar Biochar Production byproduct from pyrolysis UGA Biorefining and Carbon Cycling Program www.biorefinery.uga.edu

Biochar carbon negative energy Waste biomass can be used No competition with food production www.biopact.com Nature (2007), Vol 447 Source www.biopact.com Carbon sequestration, restoring soil fertility and renewable energy production can be complementary Resources global http://www.ecoworld.com/maps/world_ecoregion.cfm

Resources global Global amount of crop residue produced is estimated at 2.8 Pg yr -1 for cereal crops and 3.8 Pg yr -1 for 27 food crops. (without forestry residues) Lal 2005, Environment International Globally 1.5 Pg yr -1 crop residues are wasted. (7 most important crops) Kim and Dale 2004, Biomass and Bioenergy Worldwide, the total carbon release from fire is 4-7 Pg yr -1 (6 Pg from fossil fuel in 1990) Goudriaan 1995, Global Carbon and Carbon Sequestration Burned agricultural wastes in the tropics 0.5-0.8 Pg yr -1 Crutzen and Andreae 1990, Science Tropical Forest humid http://www.ecoworld.com/maps/world_ecoregion.cfm

Tropical Forest slash and char as alternative to slash and burn Tropical forest conversion contribute 25% of the global CO 2 emissions. Palm et al. 2004, Environment, Development and Sustainability 1.31 Pg yr -1 (billion tons) of biomass is cleared in all secondary forests (fallow vegetation) Fearnside 2000, Climatic Change Photo: Steve Welch ~50% of C remains as charcoal ~2% of C remains as charcoal Tropical Forest Sugar cane and palm oil plantations Annual global sugar cane production is 0.33 Pg 44% Asia 27% Brazil Average yield = 17 Mg ha -1 Kim and Dale 2004, Biomass and Bioenergy 5 Million ha in Brazil producing 300 million tons (20% are harvested without burning) Shredded stalks (bagasse) is burned to provide steam and electricity Organic waste stream (vinasse) can be used as fertilizer or converted to methane Cerri et al 2007, Sci. Agric.

Forest Savanna sub-humid http://www.ecoworld.com/maps/world_ecoregion.cfm Forest Savanna Namibia case study Drastically reduced productivity of agricultural land 10 12 million ha (12 14% of Namibia) 100 million tons of biomass available Laurens Rademakers www.biopact.com Harvest of 1 million ha yr -1 necessary 10 million tons of biomass per year = 40 TWh (Electricity consumption of Namibia in 1999 12.6 TWh)

Drylands arid / semi-arid http://www.ecoworld.com/maps/world_ecoregion.cfm Drylands Australia case study 250 450 mm rainfall Syd Shea (http://www.oilmallee.com.au/) and Paul Blackwell (http://www.agric.wa.gov.au/) Salinization problem as response to 200 yrs of land clearing 30% of all farmland 2.4 million ha which could increase to > 15 million ha

Salinization threatens more than 400 species of Australian wildlife Drylands Australia case study Alley cropping with Mallee Eucalyptus From 1994 2001 7560 ha or 25 million trees planted (10 million ha needed) 20% - 40% of all agricultural land

Drylands Australia case study Integrated production of Eucalyptus oil Energy Activated carbon And biochar carbon sink proposed Presentation http://www.biochar.org/

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