R. Wilden et al., Element budgets of two afforested mine sites after application of fertilizer and organic residues, ECOL ENG, 17(2-3), 2001, pp. 253-273
The effects of mineral fertilizer, sewage sludge and compost application on
soil solution chemistry and element fluxes at two mine spoils were studied
in a field trial. The two sites differed in substrate composition: (a) a p
yrite and lignite containing spoil (WEB site); and (b) a pyrite and lignite
free spoil (SEE site). Soil solution was continuously sampled at 70 and 13
0 cm soil depth over a 2-year period, and analyzed for all major elements,
pH, and electrical conductivity. At the WEB site, major elements in soil so
lution at 20 cm depth were Ca, Mg, Al and SO4-S. In the unameliorated subso
il, Fe was detected in high concentrations. Pyrite oxidation caused massive
element fluxes of up to 6 t Fe ha(-1) year(-1) and 14 t SO4-S ha(-1) year(
-1). At the SEE site, major elements in soil solution were Ca, Mg and SO4-S
. Maximum element fluxes measured 1 t Ca ha(-1) year(-1) and 1 t SO4-S ha(-
1) year(-1). Application of mineral fertilizer and organic residues increas
ed NO3, NH4, K, and Cl concentrations and fluxes. Thirty to 40% of the appl
ied mineral fertilizer was leached below 20 cm within 4 weeks. Sewage sludg
e application led to N fluxes in 20 cm depth of 56 kg N ha(-1) (2 years)(-1
) at the SEE site and 94 kg N ha(-1) (2 years)(-1) at the WEB site, equival
ent to 5 and 10%, of N applied with sewage sludge, respectively. At the SEE
site, NO3-N fluxes were increased down to 130 cm soil depth after applicat
ion of sewage sludge. At both sites, compost pints showed lower N fluxes (2
5 and 14 kg N ha(-1)) compared with the control plots (35 and 24 kg N ha (1
)). In contrast, potassium fluxes were significantly increased after compos
t application. However, the overall effects on soil solution chemistry from
application of mineral fertilizer and organic residues were small relative
to the effects from mining only. (C) 2001 Elsevier Science B.V. All rights
reserved.