3.1.4. Evaluation of biochar system

3.1.4. Evaluation of biochar systems
Since pyrolysis is a more carbon-efficient way to capture bioenergy compared with other
bioenergy systems (in terms of CO2 MJ-1), manufacture and storage of biochar would add
significant benefits for climate change mitigation alone. From this perspective, storage of
biochar does not need to be in the soil, and it had been proposed that entire valleys could be
used as storage facilities for biochar (Seifritz, 1993). However, applying biochar to
agricultural soils is currently the most widely proposed path, since it is more likely to
overcome the opportunity cost in energy production (the recoverable energy forgone in the
biochar). If biochar can provide reliable agronomic benefit it may command a value in crop
production in addition to a potential carbon credit.
However, whilst the potential for management of the terrestrial carbon cycle is the reason for
the current interest in biochar, to be workable a biochar-based scenario must: (1) assess the
monetary value of direct and indirect emission savings arising from the use of biochar
against the opportunity cost of biochar combustion or alternative use, (2) provide certainty,
verification and possibly evidence for carbon-equivalent savings and (3) consider the indirect
costs and benefits to land users and upstream food processors from the use of biochar in
soil. The latter might include the cost of biochar application, weighed against the marketing
benefits gained through carbon-neutral food products.
In short, a full life-cycle analysis of alternative scenarios is required. However, greater
certainty is required on the following in order to fully assess biochar-based soil management
for specific applications: (a) the stability of biochar carbon in soil, (b) the indirect impacts of
biochar on carbon-equivalent emissions and (c) the security, reliability and constancy of price
for pyrolysis feedstocks. These are reviewed in more detail in the next sections.
The potential for technological developments in pyrolysis to enhance flexibility and overall
efficiency is a separate topic, and will be facilitated by its expansion and forums such as IBI,
and national networks such as the Network of Australian and New Zealand Biochar
Researchers, and the UK Biochar Research Centre. It should be highlighted, however, that
from the perspective of the economics of energy capture, the value of biochar and the overall
outcome of the analysis is sensitive to the price of heat and power generated from other
fuels. It is also affected by any subsidy for renewable energy, which may have the effect of
inflating the monetary value of the energy in biochar (Woolf, 2008).
3.1.5. Stability of biochar in soil
Its extraordinary stability means that charcoal particles in soil have been used as a tool for
dating and paleo-environmental reconstruction as well as evaluation of cropping practices
over centennial and millennial timescales (Ferrio et al., 2006, Scott et al 2000). Studies of the
age of the carbon in terra preta of Brazil, as well as similar black carbon accumulations in the
soils of other natural ecosystems that have resulted from natural fire events, provide
considerable reassurance for the general long-term stability of at least some significant
component of biochar. However, laboratory-based studies using freshly-made char tend to
show some mass loss – sometimes large – in a period of days to years.
The paradox of apparent long-term stability against measurable short-term decomposition
suggests that biochar comprises both stable and degradable components. At the moment
there is insufficient data in the literature to compare the responses between short- and longterm
stability under different climates and in different soils, which could enable the relative
size of these fractions to be assessed.
Combustion conditions during pyrolysis as well as the type of feedstock are probably
influential in determining the proportion of relatively labile components in biochar products.
Measuring the influence is essential for the optimisation of pyrolysis for maximum net carbon