The characteristics of biochars and

The characteristics of biochars and its potential benefits
when applied to the land are both influenced by the specific
material of the biochar and the processing technique used.
Biochars can retain applied fertilizer and nutrients and
release them to agronomic crops over time. Biochars’ ability
to retain water and nutrients in the surface soil horizons
for long periods benefits agriculture by reducing nutrients
leaching from the crop root zone, potentially improving
crop yields, and reducing fertilizer requirements. Thus,
using biochars in production agriculture should improve
yields and reduce negative impacts on the environment. A
distinction between biochars and composts should be made
here for clarity. Biochars differ from composts commonly
added to soils for agricultural production in that compost is
a direct source of nutrients through further decomposition
of organic materials. However, biochars do not decompose
with time and so additional applications should not be
necessary.
A recent review of biochar articles by Spokas et al. (2012)
concluded that while application of biochars can lead
to positive results in agricultural production, there have
been some reports of no crop yield benefits (Schnell et al.
2012) or even negative yield responses (Lentz and Ippolito
2012). Reported low yields could be because of reduced
nutrient release for plant uptake, application of biochar
on fertile soils, or a low rate of biochar application. High
yields observed in some cases of biochar application could
not be easily explained, but might depend on biochar
properties, the soil fertility status, and the agronomic crop
under consideration. Ippolito, Laird, and Busscher (2012)
pointed out that most recent research on biochar has been
conducted on highly weathered and infertile soils where
benefits of biochar application were often noted. UF/IFAS
researchers are working on determining benefits of biochars
on sandy soils of Florida with low fertility and documenting
any improvements in crop growth and yield.
Impacts on the Environment
As discussed earlier, biochars can have benefits for waste
reduction, energy production, C-sequestration, and soil
fertility. Also, different biochars (derived from a variety of
feedstocks) have been recognized as highly efficient lowcost sorbents for various pollutants in the environment.
Application of biochars to soils has been investigated at the
laboratory and field scale as an in-situ remediation strategy
for both organic and inorganic contaminants to determine
their ability to increase the sorption capacity of varying
soils and sediments. For example, Chun et al. (2004)
reported biochars generated by pyrolyzing wheat residues
at temperatures ranging from 300
o
C to 700
o
C removed
benzene and nitrobenzene (organic contaminants) from
wastewater. Similarly, biochars produced from greenwaste
(a mixture of maple, elm, and oak woodchips and bark)
removed atrazine and simazine from aqueous solution
(Zheng et al. 2010). Pine needle-derived biochar removed
naphthalene, nitrobenzene, and m-dinitrobenzene from
water (Chen, Zhou, and Zhu 2008). Straw-derived biochar
was found to be an excellent, cost-effective substitute for
activated carbon to remove dyes (reactive brilliant blue and
rhodamine B) from wastewater (Qiu et al. 2009). Biochar
derived from dairy manures (pyrolysis from 200°C to
300°C) also removed substantial amounts of atrazine from
wastewater (Uchimiya et al. 2010).
In addition to removing organic contaminants, biochars
have also been shown to remove metal contaminants
3 An Introduction to Biochars and Their Uses in Agriculture
and nutrients from wastewater and soil. Cao et al. (2009)
investigated the sorption capacities of biochars produced
by the pyrolysis of dairy manures at low temperatures
(200
o
C and 350
o
C). They found that the biochar was six
times more effective in removing lead (Pb) from wastewater
than a commercial activated carbon. Broiler litter manure
biochar enhanced the immobilization of heavy metals
including cadmium (Cd), copper (Cu), nickel (Ni), and Pb
in soil and water (Uchimiya et al. 2011). Yao et al. (2011)
reported biochar derived from anaerobically digested sugar
beet tailings (DSTC) removed 73% of phosphate from the
tested water. Also, magnetic biochars were found to be
effective at removing hydrophobic organic contaminants
and phosphate from solution simultaneously (Chen, Chen,
and Lv 2011). These results show the potential of biochars
to minimize nutrient leaching in agricultural fields
The term biochar was originally associated with a specific type of production, known as ‘slow
pyrolysis’. In this type of pyrolysis, oxygen is absent, heating rates are relatively slow, and
peak temperatures relatively low (Section 2.1.3.1). However, the term biochar has since
been extended to products of short duration pyrolysis at higher temperatures known as ‘fast
pyrolysis’ (Section 2.1.3.2) and novel techniques such as microwave conversion.
It is important to note that there is a wide variety of char products produced industrially. For
applications such as activated carbon, char may be produced at high temperature, under
long heating times and with controlled supply of oxygen. In contrast, basic techniques for
manufacture of charcoal (such as clay kilns) tend to function at a lower temperature, and
reaction does not proceed under tightly controlled conditions. Traditional charcoal production
should be more accurately described as 'carbonisation' (Section 2.1.3.4), which involves
smothering of biomass with soil prior to ignition or combustion of biomass whilst wet. Drying
and roasting biomass at even lower temperatures is known as ‘torrefaction’ (Arias et al.,
2008).
A charred material is also formed during 'gasification' of biomass, which involves thermal
conversion at very high temperature (800°C) and in the partial presence of oxygen (Section
2.1.3.5). This process is designed to maximise the production of synthesis gas (‘syngas’).
Materials produced by torrefaction and gasification differ from biochar in physico-chemical
properties, such as particle pore size and heating value (Prins et al., 2006) and have
industrial applications, such as production of chemicals (methanol, ammonia, urea) rather
than agricultural applications.
In order to differentiate biochar from charcoal formed in natural fire, activated carbon, and
other black carbon materials, the following list of terms aims to better define the different