Climate Change Policy and the Adoption of Methane Digesters on Livestock Operations
by
Nigel Key and
Stacy SneeringerEconomic Research Report No. (ERR-111) 47 pp, February 2011
What Is the Issue?
Methane digester systems capture methane from lagoon or pit
manure storage facilities and use it as a fuel to generate
electricity or heat. In addition to providing a renewable source of
energy, digesters can reduce greenhouse gas emissions, odors from
manure, and potential contamination of surface water. Methane
digesters have not been widely adopted in the United States mainly
because the costs of constructing and maintaining these systems
have exceeded the value of the benefits provided to the operator.
Policies to reduce greenhouse gas emissions could create new
opportunities for livestock producers to earn revenue from burning
methane from manure, making such biogas recovery facilities
profitable for many livestock producers. However, there is likely
to be wide variation in the scale, location, and characteristics of
livestock operations that would benefit, so these policies could
have longrun structural implications for the U.S. livestock sector.
In this report we estimate the number and type of hog and dairy
operations that would find it profitable to adopt a digester at any
given carbon price. We also estimate the relationship between the
price of carbon (CO2) and the amount of emissions reduced by
digesters on these operations.
What Are the Major Findings?
The extent to which livestock operations can reduce greenhouse
gas emissions from manure management depends in part on the number
of livestock operations that adopt methane digesters, which in turn
depends on digester profitability from energy savings, energy
sales, and/or sales of emission reductions in a carbon offset
market. An offset market allows livestock producers who reduce
methane emissions to sell these reductions or "carbon offsets" to
other greenhouse gas emitters who might face emissions caps.
Factors that influence digester profitability and that determine
the characteristics and locations of the livestock operations that
could benefit from the introduction of a carbon offset market
include:
• operation size-costs of constructing and operating a digester
decline on a per-head basis, making digesters more profitable on
larger operations
• the selling price of surplus electricity-a higher price makes
digesters more valuable for operations that can generate more
electricity than they use onfarm
• farm electricity expenditures, which depend on electricity
prices and onfarm use-higher expenditures make digester-generated
electricity more valuable, especially if the operation cannot sell
electricity or if the selling price of electricity is below the
retail price
• participation in cost-share and other incentive programs-this
can defray the cost of building digesters
• farm's initial level of methane emissions-this determines the
maximum quantity of carbon emissions reductions that can be
sold
• carbon price-a higher carbon price makes digesters more
profitable for operations that can sell carbon offsets.
Larger operations would be more likely to adopt a digester, and
likely would earn substantially higher profits on average than
smaller operations. Hence, introduction of a carbon market in a
region could enhance existing economies of scale in production and
result in further concentration of production on the largest
operations. However, smaller livestock operations may be able to
achieve a more efficient digester scale by supplementing manure
with food waste products or by sharing a digester with other small
operations. In addition, if the adoption of methane digesters by
smaller operations is a policy goal, several tools exist-such as
cost-share subsidies or tax incentives-that could be used to
encourage their adoption by small farms.
Additional revenues from the sale of carbon emissions reductions
(offsets) could substantially increase the number of operations
that would adopt a biogas recovery system. Findings in this study
indicate that a carbon price of $13 per metric ton of carbon
dioxide equivalent emissions (an initial price estimated under one
scenario for a nationwide capand- trade program for greenhouse
gases) would:
• induce dairy and hog operations to supply offsets equivalent
to about 22 million tons of carbon dioxide annually, amounting to
about 62 percent of the current greenhouse gas emissions from
manure management in these industries, or about 5 percent of total
greenhouse gas emissions from the U.S. agricultural sector
• allow dairy and hog operators as a group to earn up to $1.8
billion in additional profits over 15 years from installing methane
digesters.
Currently, the price of electricity and onfarm electricity
expenditures are key determinants of digester profitability.
However, when carbon prices are above $4 per metric ton of CO2
equivalent emissions, carbon offset sales comprise a larger source
of digester revenue than electricity generation. At a price of $13
per metric ton of CO2 equivalent emissions, revenues from emission
reduction sales (offsets) contribute 66 percent of gross digester
revenues for all dairy and hog operations, electricity sales
contribute 8 percent, and cost savings from avoided energy expenses
contribute the remaining 26 percent.
At higher carbon prices, the distribution of profits from
digesters reflects the location of large-scale operations and the
prevalence of lagoons. Among States with the greatest number of
dairies, the study finds that California, New York, Wisconsin, and
Texas each have at least 100 such operations that would find it
profitable to adopt a digester at a carbon price of $13 per metric
ton of CO2 equivalent emissions. At the same price, North Carolina,
Illinois, Indiana, Missouri and Oklahoma each have at least 100 hog
farm operators who would find a methane digester profitable.
How Was the Study Conducted?
We used a model of digester profitability to estimate how farm
size, manure management methods, electricity prices, and carbon
prices affect producers' decisions to adopt biogas recovery
systems. Hog and dairy producers are assumed to adopt a digester if
the present value of the discounted stream of profits (the net
present value) is positive. Profits derive from electricity
generation and carbon emission reductions sales less the digester
construction and maintenance costs. Using case study information,
we parameterized the model. Electricity price data are drawn from
the U.S. Department of Energy, and methane emissions are estimated
using State-level Intergovernmental Panel on Climate Change
emission coefficients.
By computing the present value of digester profits for every
farm in nationally representative samples of dairy and hog
operations (USDA's Agricultural Resource Management Survey or
ARMS), we used the model to provide an estimate of the number,
size, and location of farms that would find it profitable to adopt
a digester at any given carbon price. ARMS is conducted by USDA's
National Agricultural Statistics Service (NASS) in conjunction with
the Economic Research Service. By predicting which operations would
earn profits from digester adoption and then summing the reduction
in tons of carbon dioxide equivalent emissions, it is possible to
estimate the relationship between the price of carbon and the
amount of emissions reduced by methane digesters on dairy and hog
operations. We used the model to estimate how the present value of
farm revenues changes with the carbon price and to simulate the
effect of surplus electricity prices and Government cost-share
policies on the potential supply of carbon emissions
reductions.