The adequate restoration of the deg

The adequate restoration of the degraded and
contaminated environment requires cooperation, integration,
and assimilation of different biotechnological
advances along with traditional and ethical sense to
unravel the science of the emerging field of bioremediation,
especially the mechanisms of phytoremediation
of heavy metals (Mani and Kumar, 2014). Success
in restoration and reclamation is dependent on
the physico-chemical soil characteristics and soil community
complexity. Soil amendments by compost,
biochar, and arbuscular mycorrhizal fungi may facilitate
grassland recovery in severely degraded habitats
and the promotion of grassland ecosystem sustainability
(Ohsowski et al., 2012). Biochar has potential
impacts on restoration of degraded and contaminated
land (Table III). Biochar amendment significantly improved
root traits, particularly root mass density and
root length density, enhanced root establishment in
contaminated soils, and reduced Cu uptake to plants
compared to the control soil (Brennan et al., 2014).
Although biochar addition increased extractable
Ca, K, P, Cu, Zn, and Mn, CEC, mesoporosity, and
water-holding capacity in fly ash (an inorganic waste
of coal-fired power generation), it had a little or no stimulatory
effect on the size of the soil microbial community,
N fertility, or plant growth during revegetation
on fly ash. This might be attributable to the lack
of metabolizable C and an insignificant N-supplying
capacity (Belyaeva and Haynes, 2012). Biochars immobilized
soil Cd in industrial wastewater treatment,
but did not improve growth of the emerging wetland
plant species (Juncus subsecundus) at the early
growth stage, probably due to the interaction between
biochars and waterlogged environment (Zhang Z et al.,
2013). Further study is needed to elucidate the underlying
mechanisms.