Facial reconstruction

Search LJMU Research Online

Browse Repository | Browse E-Theses

Critical control of flooding and draining sequences on the environmental risk of Zn-contaminated riverbank sediments

Byrne, PA, Batty, L and Lynch, SFL (2017) Critical control of flooding and draining sequences on the environmental risk of Zn-contaminated riverbank sediments. Journal of Soils and Sediments. ISSN 1439-0108

[img]
Preview
Text
Lynch_et_al-2017.pdf - Published Version

Download (1MB) | Preview

Abstract

Purpose: Diffuse pollution emanating from metal mining impacted sediment could serve as a barrier to achieving European Union Water Framework Directive and US Clean Water Act requirements. UK climate projections (UKCP09) predict increases in rainfall and aridity that will influence river stage alternately exposing and submersing contaminated riverbank sediment. Research focuses on the environmental contaminant dissolved Zn and investigates patterns of release, key geochemical mechanisms controlling Zn mobilisation and the environmental risk of sediment subjected to these perturbations.
Materials and methods: Using two laboratory mesocosm experiments, metal mining-contaminated sediment was subjected to alternate wet and dry sequences of different duration and frequency. The first experiment was run to determine the influence of submersion and exposure of contaminated sediment on releases of Zn and to establish environmental risk. The second experiment utilised diffusional equilibration in thin film (DET) to observe the patterns of Zn release, with depth, in the sediment. Pore water chemical analysis at the sediment-water interface enabled elucidation of key geochemical mechanisms of control of Zn mobilisation.
Results and discussion: Patterns of Zn release were found to be different, depending on the length of wet and dry period. High concentrations of dissolved Zn were released at the start of a flood for runs with longer dry periods. A buildup of soluble Zn sulphate minerals over long dry periods followed by dissolution on first flood wetting was a key geochemical mechanism controlling Zn release. For longer wet runs, increases in dissolved Mn and Zn were observed over the flood period. Key geochemical mechanisms controlling Zn mobilisation for these runs were: (i) reductive dissolution of Mn (hydr)oxides and release of partitioned Zn over prolonged flood periods followed by (ii) oxidation and precipitation of Mn (hydr)oxides and sorption of Zn on exposure to atmospheric conditions.
Conclusions: Mesocosm experiments were a first step in understanding the effects of UK climate projections on the riverbank environment. Contaminated sediment was found to pose a significant environmental risk in response to hydrological perturbations. The ‘transient’ nature of dissolved Zn release could make identifying the exact sources of pollution a challenge; therefore, further field studies are advised to monitor contaminant releases under a range of hydrological conditions and account for complex hydrology at mining sites.

Item Type: Article
Additional Information: The final publication is available at Springer via http://dx.doi.org/10.1007/s11368-016-1646-4
Uncontrolled Keywords: 05 Environmental Sciences, 04 Earth Sciences, 07 Agricultural And Veterinary Sciences
Subjects: G Geography. Anthropology. Recreation > GB Physical geography
G Geography. Anthropology. Recreation > GE Environmental Sciences
Q Science > QD Chemistry
Divisions: Natural Sciences & Psychology (closed 31 Aug 19)
Publisher: Springer Verlag
Date Deposited: 17 Jan 2017 10:00
Last Modified: 04 Sep 2021 12:05
DOI or ID number: 10.1007/s11368-016-1646-4
URI: https://researchonline.ljmu.ac.uk/id/eprint/5266
View Item View Item