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Biochar: Examination of an Emerging Concept
to Mitigate Climate Change

Kelsi Bracmort
Analyst in Agricultural Conservation and Natural Resources Policy
January 22, 2010
Congressional Research Service
7-5700
www.crs.gov
R40186
CRS Report for Congress
P
repared for Members and Committees of Congress
c11173008

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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

Summary
Biochar is a charcoal produced under high temperatures using crop residues, animal manure, or
any type of organic waste material. Depending on the feedstock, biochar may look similar to
potting soil or to a charred substance. The combined production and use of biochar is considered
a carbon-negative process, meaning that it removes carbon from the atmosphere.
Biochar has multiple potential environmental benefits, foremost the potential to sequester carbon
in the soil for hundreds to thousands of years at an estimate. Studies suggest that crop yields can
increase as a result of applying biochar as a soil amendment. Some contend that biochar has value
as an immediate climate change mitigation strategy. Scientific experiments suggest that
greenhouse gas emissions are reduced significantly with biochar application to crop fields.
Obstacles that may stall rapid adoption of biochar production systems include technology costs,
system operation and maintenance, feedstock availability, and biochar handling. Biochar research
and development is in its infancy. Nevertheless, interest in biochar as a multifaceted solution to
agricultural and natural resource issues is growing at a rapid pace both nationally and
internationally.
Past Congresses have proposed numerous climate change bills, many of which do not directly
address mitigation and adaptation technologies at developmental stages like biochar. However,
biochar may equip agricultural and forestry producers with numerous revenue-generating
products: carbon offsets, soil amendments, and energy. A clearly defined policy medium that may
support this technology (e.g., soil conservation, renewable energy, greenhouse gas emission
reduction) has yet to emerge.
This report briefly describes biochar, its potential advantages and disadvantages, legislative
support, and research and development activities underway in the United States and abroad.

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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

Contents
Introduction ................................................................................................................................ 1
Biochar ....................................................................................................................................... 1
Potential Advantages............................................................................................................. 3
Carbon Sequestration ...................................................................................................... 3
Greenhouse Gas Emission Reduction .............................................................................. 4
Soil Fertility.................................................................................................................... 4
Potential Disadvantages ........................................................................................................ 5
Feedstock Availability ..................................................................................................... 5
Biochar Handling............................................................................................................ 5
Biochar System Deployment ........................................................................................... 5
Policy Context ............................................................................................................................ 6
Climate Change Debate......................................................................................................... 6
Introduced Legislation .......................................................................................................... 7
Farm Bill .............................................................................................................................. 7
Long-Term Prospects ............................................................................................................ 7
International Recognition ...................................................................................................... 8
U.S. Department of Agriculture Activities ................................................................................... 8
Select U.S. Manufacturers........................................................................................................... 8
Eprida, Inc. ........................................................................................................................... 8
Carbon Char Group, LLC...................................................................................................... 9
Biochar Engineering (BEC Inc.)............................................................................................ 9
International Activities ................................................................................................................ 9

Figures
Figure 1. Biochar ........................................................................................................................ 2
Figure 2. Biochar Production via Pyrolysis.................................................................................. 2
Figure 3. Carbon Cycle for Soil Carbon and Biochar ................................................................... 3

Contacts
Author Contact Information ........................................................................................................ 9

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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

Introduction
Biochar—a charcoal produced under high temperatures using crop residues, animal manure, or
organic waste material—has the potential to offer multiple environmental benefits. Some contend
that biochar can meet pressing environmental demands by sequestering large amounts of carbon
in soil. It is of interest to those seeking to sell or purchase carbon offsets, increase soil
conservation efforts, improve crop yield, and produce renewable energy. However, little is known
about how biochar production systems could successfully be implemented and what the effect
would be on long-term operations in the U.S. agriculture and forestry sectors. Some contend that
it will be a considerable amount of time before this technology reaches its full potential. Studies
underway at federal government research institutions and in academia are focused on ensuring
that biochar production systems are a practical and reliable technology for producers to adopt.
Biochar
Biochar is a soil supplement that sequesters carbon in the soil and thus may help to mitigate
global climate change. It has the potential to curtail greenhouse gas emissions and other
environmental hazards in the near term and to benefit agricultural producers as a soil amendment
and source of renewable energy. Thus far, biochar use in the United States has been limited to
small-scale applications reflective of the limited but growing number of researchers in this area
over the last few years.
Biochar is similar in appearance to potting soil or to a charred substance, depending on the
feedstock (Figure 1). Modern biochar production is based on an ancient Amazon technique for
creating a nutrient-rich soil, terra preta. As a charcoal containing high levels of organic matter,
biochar is formed from plant and crop residues or animal manure under pyrolysis conditions
(Figure 2). Pyrolysis is the chemical breakdown of a substance under extremely high
temperatures in the absence of oxygen. The quantity and quality of biochar production depends
on the feedstock, pyrolysis temperature, and pyrolysis processing time. A “fast” pyrolysis
(~500°C) produces biochar in a matter of seconds, while a “slow” pyrolysis produces
considerably more biochar but in a matter of hours.1
Biochar production via pyrolysis is considered a carbon-negative process because the biochar
sequesters carbon while simultaneously enhancing the fertility of the soil on which the feedstock
used to produce the bioenergy grows (Figure 3). The biochar production system is operated using
energy produced by the system. The three main outputs of a biochar production system are
syngas, bio-oil, and biochar.2

1 Institute for Governance & Sustainable Development and IGDS/INECE Climate Briefing Note, “Significant climate
mitigation is available form biochar,” December 8, 2008.
2 Syngas, or synthesis gas, consists of varying concentrations of carbon monoxide and hydrogen and can be used as a
replacement to natural gas or liquid fuel. Bio-oil is a liquid fuel that can be used, once upgraded, as a motor fuel.
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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

Figure 1. Biochar

Source: Biochar Engineering (BEC Inc.; http://www.biocharengineering.com).
Notes: Wood chips on the right and in barrel were processed through a biochar production system.
Figure 2. Biochar Production via Pyrolysis

Source: U.S. Department of Agriculture (USDA) Agricultural Research Service (ARS), ARS Biochar & Pyrolysis
Initiative, 2009.
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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

Figure 3. Carbon Cycle for Soil Carbon and Biochar

Source: J. Lehmann, “A Handful of Carbon,” 2007. Nature 447, pp. 143-144.
Potential Advantages
Whether used as a soil amendment3 or burned as an energy source (e.g., for cooking and heating),
biochar provides numerous potential environmental benefits, some of which are not quantifiable.
The three primary potential benefits are carbon sequestration, greenhouse gas emission reduction,
and soil fertility.
Carbon Sequestration
Carbon sequestration is the capture and storage of carbon to prevent it from being released to the
atmosphere. Studies suggest that biochar sequesters approximately 50% of the carbon available
within the biomass feedstock being pyrolyzed, depending upon the feedstock type.4 The

3 A soil amendment improves the physical properties of soil (e.g., moisture-holding capacity, nutrient retention ability).
4 Johannes Lehmann, John Gaunt, and Marco Rondon, “Bio-char Sequestration in Terrestrial Ecosystems—A Review,”
Mitigation and Adaptation Strategies for Global Change, vol. 11 (2006), pp. 403-427.
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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

remaining carbon is released during pyrolysis and may be captured for energy production. Large
amounts of carbon may be sequestered in the soil for long time periods (hundreds to thousands of
years at an estimate),5 but precise estimates of carbon amounts sequestered as a result of biochar
application are scarce. One scientist suggests that a 250-hectare farm could sequester 1,900 tons
of CO2 a year.6
Greenhouse Gas Emission Reduction
Primary greenhouse gases associated with the agriculture sector are nitrous oxide (N2O) and
methane (CH4). Cropland soils and grazing lands are an agricultural source of nitrous oxide
emissions.7 Livestock manure management and enteric fermentation are leading agricultural
sources of methane emissions.8 When applied to the soil, biochar can lower greenhouse gas
emissions by substantially reducing the release of nitrous oxide.9 Emissions of nitrous oxide, a
greenhouse gas that is approximately 298 times stronger than carbon dioxide in terms of global
warming potential, were reduced by 40% in one report.10 Laboratory studies suggest that nitrous
oxide emission reductions from biochar-treated soil are dependent on soil moisture and soil
aeration.11 Greenhouse gas emission reductions may be 12%-84% greater if biochar is land-
applied instead of combusted for energy purposes.12
Soil Fertility
Biochar retains nutrients for plant uptake and soil fertility. The infiltration of harmful quantities of
nutrients and pesticides into groundwater and soil erosion runoff into surface waters can be
limited with the use of biochar.13 If used for soil fertility, biochar may have a positive impact on
those in developing countries. Impoverished tropical and subtropical locales with abundant plant
material feedstock, inexpensive cooking fuel needs, and agricultural soil replenishment needs
could see an increase in crop yields.14

5 Bruno Glaser, Johannes Lehmann, and Wolfgang Zech, “Ameliorating Physical and Chemical Properties of Highly
Weathered Soils in the Tropics with Charcoal—A Review,” Biology and Fertility of Soils, vol. 35 (2002), pp. 219-230.
6 Emma Marris, “Black Is the New Green,” Nature, vol. 442, no. 10 (August 2006), pp. 624-626.
7 For more information on nitrous oxide emissions, see CRS Report R40874, Nitrous Oxide from Agricultural Sources:
Potential Role in Greenhouse Gas Emission Reduction and Ozone Recovery
, by Kelsi Bracmort.
8 For more information on methane emissions from agricultural sources, see CRS Report R40813, Methane Capture:
Options for Greenhouse Gas Emission Reduction
, by Kelsi Bracmort et al.
9 Johannes Lehmann, “Bio-energy in the Black,” Frontiers in Ecology and the Environment, vol. 5, no. 7 (2007), pp.
381-387.
10 Tyler Hamilton, “The Case for Burying Charcoal,” Technology Review, April 26, 2007.
11 Yosuke Yanai, Koki Toyota, and Masanori Okazaki, “Effects of Charcoal Addition on N2O Emissions from Soil
Resulting from Rewetting Air-Dried Soil in Short-Term Laboratory Experiments,” Japanese Society of Soil Science
and Plant Nutrition
, vol. 53 (2007), pp. 181-188.
12 Johannes Lehmann, “A Handful of Carbon,” Nature, vol. 447 (May 10, 2007), pp. 143-144.
13 Johannes Lehmann, “Bio-energy in the Black,” Frontiers in Ecology and the Environment, vol. 5, no. 7 (2007), pp.
381-387.
14 Stephan M. Haefele, “Black Soil, Green Rice,” Rice Today, April-June 2007, p. 27.
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Potential Disadvantages
Recognizing that biochar technology is in its early stages of development, there are many
concerns about the applicability of the technology in the United States. Three issues are feedstock
availability, biochar handling, and biochar system deployment. Successful implementation of
biochar technology depends on the ability of the agricultural community to afford and operate a
system that is complementary to current farming and forestry practices.
Feedstock Availability
The availability of a plentiful feed supply for biochar production is an area for further study. To
date, feedstock for biochar has consisted mostly of plant and crop residues, a primary domain of
the agricultural community. There may be a role for the forestry community to be involved as
woody biomass is deemed a cost-effective, readily available, feasible feedstock. Little is known
about the advantages of using manure as a biomass feedstock. According to a group of
researchers in Australia, manure-based biochar
has advantages over typically used plant-derived material because it is a by-product of
another industry and in some regions is considered a waste material with little or no value. It
can therefore provide a lower cost base and alleviate sustainability concerns related to using
purpose-grown biomass for the process.15
Biochar Handling
The spreading of biochar as a soil amendment is ripe for further exploration. Specific questions
concern the ideal time to apply biochar and how to ensure that it remains in place once applied
and does not cause a risk to human health or degrade air quality.16 Particulate matter, in the form
of dust that is hard for the human body to filter, may be distributed in abnormal quantities if the
biochar is mishandled. There are potential public safety concerns for the handling of biochar as it
is a flammable substance. Additionally, the amount of land available for biochar application
requires further investigation.
Biochar System Deployment
Biochar systems are designed based on the feedstock to be decomposed and the energy needs of
an operation. It would be ambitious to expect a “one size fits all” standard biochar system.
According to proponents, a series of mass-produced biochar systems designed for the needs of a
segment of the agriculture or forestry communities might prove to be feasible (e.g., forestry
community in the southeastern region, corn grower community in the midwestern region, poultry
producer community in the mid-Atlantic region). Extensive deployment of biochar systems would
depend on system costs, operation time, collaboration with utility providers for the sale of bio-oil,
and availability of information about technology reliability.

15 K. Y. Chan, L. Van Zwieten, and I. Meszaros et al., “Using Poultry Litter Biochars as Soil Amendments,” Australian
Journal of Soil Research
, vol. 46 (2008), pp. 437-444.
16 David A. Laird, “The Charcoal Vision: A Win-Win-Win Scenario for Simultaneously Producing Bioenergy,
Permanently Sequestering Carbon, While Improving Soil and Water Quality,” Agronomy Journal, vol. 100, no. 1
(2008), pp. 178-181.
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Biochar: Examination of an Emerging Concept to Mitigate Climate Change

Policy Context
Climate Change Debate
The 110th Congress deliberated over a large number of bills to address and organize climate-
change mitigation efforts, including legislation for carbon offsets.17 In the 111th Congress, carbon
offsets are a prominent factor in the climate change debate. The establishment of an offset
program, identification of eligible projects types, and offset verification may be pertinent to the
adoption of biochar production technology.18 A carbon offset is defined as “a measurable
avoidance, reduction, or sequestration of carbon dioxide (CO2) or other greenhouse gas (GHG)
emissions.”19 Carbon sequestration projects are one type of carbon offset. In addition to direct
carbon capture and sequestration activities, the 111th Congress may consider the role of biological
(indirect) sequestration, such as projects that can be implemented by agricultural producers at the
field level.20 Furthermore, Congress may decide who is granted carbon offset ownership for
biochar production (e.g., landlord, feedstock provider, production plant).
Congress may examine the use of biochar as an indirect carbon sequestration technology that
could be used to offset carbon emissions from major emitters. In 2007, 6% of total U.S.
greenhouse gas emissions were attributed to the agricultural sector.21 While not as large as the
amounts produced by some other sectors, agricultural emissions come from a large number of
decentralized sources, leading many to conclude that controlling such emissions would be
difficult. On the other hand, some argue that soil carbon sequestered as a result of biochar
application is easily quantifiable and transparent, which may be ideal for carbon trading
requirements. Others contend that ancillary benefits could include additional revenue earned by
agricultural producers through the sale of carbon credits earned from biochar application or the
sale of biochar as a soil amendment. Energy costs for a producer’s operation may be reduced by
using the energy generated from the biochar production system. Additionally, some assert that the
use of biochar results in higher crop yields. This could be a criterion to consider within the larger
land use debate.

17 For more information pertaining to climate change legislation in the 110th Congress, see CRS Report RL34067,
Climate Change Legislation in the 110th Congress, by Jonathan L. Ramseur and Brent D. Yacobucci.
18 For more information on the role of offsets in current greenhouse gas legislation, see CRS Report R40643,
Greenhouse Gas Legislation: Summary and Analysis of H.R. 2454 as Passed by the House of Representatives ,
coordinated by Mark Holt and Gene Whitney.
19 For more information on carbon offsets, see CRS Report RL34241, Voluntary Carbon Offsets:
Overview and Assessment
, by Jonathan L. Ramseur.
20 For more information on carbon capture and sequestration, see CRS Report RL33801, Carbon Capture and
Sequestration (CCS)
, by Peter Folger; CRS Report RL33898, Climate Change: The Role of the U.S. Agriculture Sector,
by Renée Johnson; and CRS Report RL34560, Forest Carbon Markets: Potential and Drawbacks, by Ross W. Gorte
and Jonathan L. Ramseur.
21 U.S. Environmental Protection Agency, 2009 U.S. Greenhouse Gas Inventory Report, Inventory of U.S. Greenhouse
Gas Emissions and Sinks: 1990-2007, April 2009. http://epa.gov/climatechange/emissions/usinventoryreport.html
Unlike the U.S. Environmental Protection Agency Greenhouse Gas Inventory Report that covers all U.S. greenhouse
gas emission sources and sinks, USDA only reports for the agriculture and forestry sectors. The U.S. Agriculture and
Forestry Greenhouse Gas Inventory: 1990-2005
, Technical Bulletin No. 1921, issued by the U.S. Department of
Agriculture in 2008, reports the agricultural sector as having contributed approximately 481 teragrams (Tg) of carbon
to the atmosphere in 2005. With the addition of forest carbon sequestration (approximately 787 Tg), the agriculture and
forestry sectors combined contributed a net sink of approximately 306 Tg of carbon in 2005. One teragram equals one
million metric tons (MMTE).
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Introduced Legislation
The Water Efficiency via Carbon Harvesting and Restoration (WECHAR) Act of 2009,22
introduced in September 2009, seeks, among other things, to establish loan guarantee programs
that would develop biochar technology to use excess plant biomass and establish biochar
demonstration projects on public lands. The legislation is primarily focused on woody biomass as
the feedstock. Some contend that the legislation addresses research and development needs for
biochar production. Others argue that the legislation lacks specific actions regarding technology
transfer or commercial development of biochar production systems.
Farm Bill
The 110th Congress promoted biochar development through the 2008 farm bill (P.L. 110-246),
which listed it under grants for High Priority Research and Extension Areas. Noted research areas
include biochar production and use, co-production with bioenergy, soil enhancements, and soil
carbon sequestration. Listing biochar development as a high-priority research area in the 2008
farm bill did not authorize a specific appropriations amount. Funding for biochar development
research would be determined in future appropriation bills and by the U.S. Department of
Agriculture. Farm managers facing needs with respect to soil fertility, residue and manure
management, energy efficiency, and additional revenue generation may benefit from a policy that
further supports biochar production and use (e.g., technology practice standard, cost-share).
Long-Term Prospects
Biochar’s fate as a viable component of the long-term solution to mitigate climate change by way
of carbon sequestration depends upon further development by the scientific and technology
transfer communities. In particular, biochar’s practical application at various locations and scales
using multiple feedstocks throughout the United States is an area for additional study. A policy
vehicle to communicate the status of biochar technology to decision-makers and interested
communities has not been identified. Natural resources conservation policy, renewable energy
policy, or climate change policy are a few examples of possible policy areas. Policy that
encourages academia and other institutions to conduct in-depth research and development could
quicken the pace of technology deployment.
An assessment of external factors (e.g., feedstock transportation costs and disposal fees)
associated with the economic growth of biochar production systems, similar to studies conducted
for the biofuels industry, could provide guidance on the types of federal financial and technical
incentives necessary to spur development (e.g., regulatory requirements, technical standards). The
definition of biomass used in climate change and energy legislation will directly affect the
eventual impact of biochar in limiting GHG emissions.23 Indeed, the biomass definition would
determine what sources of material are deemed acceptable and which lands would be eligible
lands for biomass removal.

22 S. 1713.
23 For more information on biomass definitions, see CRS Report R40529, Biomass: Comparison of Definitions
in Legislation
, by Kelsi Bracmort and Ross W. Gorte.
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International Recognition
A series of presentations delivered at the United Nations Climate Change Conference in
December 2008 has elevated interest in biochar as an immediate response to mitigate climate
change, given its carbon sequestration ability.24 Biochar’s success rate as a potential clean
development mechanism (CDM) mitigation technology may provide insight on its use for U.S.
carbon trading purposes.25 A CDM, monitored by the United Nations Framework Convention on
Climate Change (UNFCCC), allows developed countries to invest in and receive credit for
activities that reduce greenhouse gas emissions in developing countries. A formal discussion by
the UNFCCC to include biochar as a CDM mitigation technology is expected to take place in
2009.
U.S. Department of Agriculture Activities
According to a U.S. Department of Agriculture (USDA) Agricultural Research Service (ARS)
official, an estimated $1.1 million was allocated in 2008 toward in-house biochar research by
ARS. ARS has over a dozen projects underway to analyze the use of fast pyrolysis to convert
biomass into biochar and bio-oil at various labs nationwide. ARS estimates that the United States
could use biochar to sequester 139 Tg of carbon on an annual basis if it were to harvest and
pyrolyze 1.3 billion tons of biomass.26
Select U.S. Manufacturers
While some consider biochar research to be in its infancy, a limited number of U.S.
manufacturers are selling biochar production technology to the public. CRS was not able to
obtain the level of private investment in biochar technology and promotion.
Eprida, Inc.
Located in Georgia, this technology development company sells biochar production equipment.
The company advocates use of both the biochar and the bio-oil produced from its patented
system. Officials at Eprida, Inc., believe their technology brings value to three markets: energy,
fertilizer, and carbon credit.27

24 “Dangerous Sea Level Rise Imminent without Large Reductions of Black Carbon and Implementation of Other Fast-
Action Mitigation Strategies,” Environmental Research Web, December 12, 2008.
25 For more information on the clean development mechanism, see CRS Report RL34150, Climate Change and the EU
Emissions Trading Scheme (ETS): Kyoto and Beyond
, by Larry Parker.
26 Correspondence with USDA ARS official, January 2009. A teragram (Tg) is equivalent to 1 trillion grams. A Tg C
(teragram of carbon) is a unit of measurement used to compare greenhouse gases emitted from different sources on the
same basis.
27 See http://www.eprida.com.
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Carbon Char Group, LLC
Agricultural grade value-added biochar is available for purchase from this New Jersey company.28
In 2008, the company received approximately $50,000 from the USDA New Jersey Conservation
Innovation Grants program (CIG) to use biochar to enhance the soil condition in sunflower fields.
The CIG is a program administered by the USDA Natural Resources Conservation Service
(NRCS) to encourage the development and adoption of innovative conservation technologies that
work in conjunction with agricultural production.
Biochar Engineering (BEC Inc.)
Field-scale biochar production systems for research purposes are available from BEC Inc., a
Colorado company. Woody biomass is the preferred feedstock for the systems. The Biochar 1000
model produces approximately 250 pounds of biochar for every 1,000 pounds of biomass on an
hourly basis. BEC is designing a larger system to process a ton of biomass in an hour that may
yield a quarter ton of biochar as well as 8 million British thermal units (MBTU) of heat in one
hour.29
International Activities
The International Biochar Initiative (IBI) is a nonprofit organization consisting of individuals that
support a sustainable biochar production system that would remove carbon from the atmosphere
and would enhance the earth’s soils. IBI currently has nine developing country projects in
progress to analyze cost-effective alternatives for the introduction and adoption of biochar. In
Vietnam, scientists are conducting an environmental, economic, and social assessment of
introducing biochar technology at the household level. The University of Tarapacá in Chile is
working on a project to promote the use of biochar to stabilize and buffer soil salinity and
increase water retention. Researchers in Kenya are developing a sustainable pyrolysis cook-stove
and biochar system for rural agricultural households. More information concerning these projects
in Africa, Asia and South America is available at http://www.biochar-international.org.

Author Contact Information

Kelsi Bracmort

Analyst in Agricultural Conservation and Natural
Resources Policy
kbracmort@crs.loc.gov, 7-7283



28 See http://www.carbonchar.com.
29 A Btu (British thermal unit) is a unit of energy used to express the heating value of fuels.
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