The impact of long-term biosolids application (>100 years) on soil metal dynamics

Sci Total Environ. 2020 Jun 10:720:137441. doi: 10.1016/j.scitotenv.2020.137441. Epub 2020 Feb 20.

Abstract

Biosolids application to arable land is a common, and cost-effective, practice but the impact of prolonged disposal remains uncertain. We evaluated the dynamics of potentially toxic elements (PTEs) at a long-established 'dedicated' sewage treatment farm. Soil metal concentrations exceeded regulations governing application of biosolids to non-dedicated arable land. However, measurement of isotopic exchangeability of Ni, Cu, Zn, Cd and Pb demonstrated support for the 'protection hypothesis' in which biosolids constituents help immobilise potential toxic metals (PTMs). Metal concentrations in a maize crop were strongly, and almost equally, correlated with all 'capacity-based' and 'intensity-based' estimates of soil metal bioavailability. This was attributable to high correlations between soil factors controlling bioavailability (organic matter, phosphate etc.) on a site receiving a single source of PTMs. Isotopic analysis of the maize crop suggested contributions to foliar Pb from soil dust originating from neighbouring fields. There was also clear evidence of metal-specific effects of biosolids on soil metal lability. With increasing metal concentrations there was both decreasing lability of Cd and Pb, due to interaction with increasing phosphate concentrations, and increasing lability of Ni, Cu and Zn due to weaker soil binding. Such different responses to prolonged biosolids disposal to arable soil should be considered when setting regulatory limits.

Keywords: Biosolids; Isotopic dilution; Lead isotopes; Metal lability, trace elements.

MeSH terms

  • Biosolids
  • Metals, Heavy
  • Sewage
  • Soil Pollutants
  • Soil*

Substances

  • Biosolids
  • Metals, Heavy
  • Sewage
  • Soil
  • Soil Pollutants