Alex L. Riley scite author profile

Carbonate formation in waste from the steel industry could constitute a nontrivial proportion of the global requirements for removing carbon dioxide from the atmosphere at a potentially low cost. To utilize this potential, we examined atmospheric carbon dioxide sequestration in a >20 million ton legacy slag deposit in northern England, United Kingdom. Carbonates formed from the drainage water of the heap had stable carbon and oxygen isotope values between -12 and -25 ‰ and -5 and -18 ‰ for δC and δO, respectively, suggesting atmospheric carbon dioxide sequestration in high-pH solutions. From the analyses of solution saturation states, we estimate that between 280 and 2900 tons of CO have precipitated from the drainage waters. However, by combining a 37 year long data set of the drainage water chemistry with geospatial analysis, we estimate that <1% of the maximum carbon-capture potential of the deposit may have been realized. This implies that uncontrolled deposition of slag is insufficient to maximize carbon sequestration, and there may be considerable quantities of unreacted legacy deposits available for atmospheric carbon sequestration.

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Long-term evolution of highly alkaline steel slag drainage waters

Riley

Mayes

2015

Environ Monit Assess

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The disposal of slag generated by the steel industry can have negative consequences upon the surrounding aquatic environment by the generation of high pH waters, leaching of potentially problematic trace metals, and rapid rates of calcite precipitation which smother benthic habitats. A 36-year dataset was collated from the long-term ambient monitoring of physicochemical parameters and elemental concentrations of samples from two steel slag leachate-affected watercourses in northern England. Waters were typified by elevated pH (>10), high alkalinity, and were rich in dissolved metals (e.g. calcium (Ca), aluminium (Al), and zinc (Zn)). Long-term trend analysis was performed upon pH, alkalinity, and Ca concentration which, in addition to Ca flux calculations, were used to highlight the longevity of pollution arising as a result of the dumping and subsequent leaching of steel slags. Declines in calcium and alkalinity have been modest over the monitoring period and not accompanied by significant declines in water pH. If the monotonic trends of decline in alkalinity and calcium continue in the largest of the receiving streams, it will be in the region of 50–80 years before calcite precipitation would be expected to be close to baseline levels, where ecological impacts would be negligible.Electronic supplementary materialThe online version of this article (doi:10.1007/s10661-015-4693-1) contains supplementary material, which is available to authorized users.

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Legacy iron and steel wastes in the UK: Extent, resource potential, and management futures

Riley

MacDonald

Burke

et al. 2020

Journal of Geochemical Exploration

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Behaviour and fate of vanadium during the aerobic neutralisation of hyperalkaline slag leachate

Hobson

Stewart

Bray

et al. 2018

Science of The Total Environment

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Vanadium is a toxic metal present in alkaline leachates produced during the weathering of steel slags. Slag leaching can therefore have deleterious effects on local watercourses due to metal toxicity, the effects of the high pH (9-12.5) and rapid carbonation (leading to smothering of benthic communities). We studied the fate and behaviour of V in slag leachate both through field observations of a heavily affected stream (Howden Burn, Consett UK) and in controlled laboratory experiments where slag leachates were neutralised by CO ingassing from air. V was found to be removed from leachates downstream from the Howden Burn source contemporaneously with a fall in pH, Ca, Al and Fe concentrations. In the neutralisation experiments pH reduced from 12 → 8, and limited quantities of V were incorporated into precipitated CaCO. The presence of kaolinite clay (i.e. SiOH and AlOH surfaces) during neutralisation experiments had no measureable effect on V uptake in the alkaline to circumneutral pH range. XANES analysis showed that V was present in precipitates recovered from experiments as adsorbed or incorporated V indicating its likely presence in leachates as the vanadate oxyanion (HVO). Nano-scale particles of 2-line ferrihydrite also formed in the neutralised leachates potentially providing an additional sorption surface for V uptake. Indeed, removal of V from leachates was significantly enhanced by the addition of goethite (i.e. FeOOH surfaces) to experiments. EXAFS analysis of recovered goethite samples showed HVO was adsorbed by the formation of strong inner-sphere complexes, facilitating V removal from solution at pH < 10. Results show that carbonate formation leads to V removal from leachates during leachate neutralisation, and the presence of both naturally occurring and neoformed Fe (oxy)hydroxides provide a potent sink for V in slag leachates, preventing the spread of V in the environment.

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Alex L. Riley

Atmospheric CO₂ Sequestration in Iron and Steel Slag: Consett, County Durham, United Kingdom

Long-term evolution of highly alkaline steel slag drainage waters

Legacy iron and steel wastes in the UK: Extent, resource potential, and management futures

Behaviour and fate of vanadium during the aerobic neutralisation of hyperalkaline slag leachate

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About

Alex L. Riley

Atmospheric CO2 Sequestration in Iron and Steel Slag: Consett, County Durham, United Kingdom

Long-term evolution of highly alkaline steel slag drainage waters

Legacy iron and steel wastes in the UK: Extent, resource potential, and management futures

Behaviour and fate of vanadium during the aerobic neutralisation of hyperalkaline slag leachate

Contact Info

Product

Resources

About

Atmospheric CO₂ Sequestration in Iron and Steel Slag: Consett, County Durham, United Kingdom