Biosynthesis of Zinc Sulfide Quantum Dots Using Waste Off-Gas from Metal Bioremediation Process

Jimmy Roussel; A.J. Murray; John Rolley; D. Barrie Johnson; L.E. Macaskie

doi:10.4028/www.scientific.net/AMR.1130.555

Paper Titles

Dynamic Modelling of Biofilm Reactors with Immobilised Sulfate-Reducing Bacteria
p.539

Biorecovery of Rare Earth Elements: Potential Application for Mine Water Remediation
p.543

Passive System for Bio-Recovery of Copper from Acid Mine Drainage
p.547

Bioremediation and Metal Resistant Bacteria in a Closed, Cold Northern Mine
p.551

Biosynthesis of Zinc Sulfide Quantum Dots Using Waste Off-Gas from Metal Bioremediation Process
p.555

Enhancing ARD Mitigation by Application of Benign Tailings to Reduce the Permeability of Waste Rock Dumps
p.560

Metal Removal from Spent Catalyst Using Microbacterium liquefaciens in Solid Culture
p.564

Study on As Uptake and Rhizobacteria of Two as Hyperaccumulators Forward to As Phytoremediation
p.568

Phytoremediation of Heavy Metal Contaminated Soil by Selection of Plant Species
p.572

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1130Biosynthesis of Zinc Sulfide Quantum Dots Using...

Biosynthesis of Zinc Sulfide Quantum Dots Using Waste Off-Gas from Metal Bioremediation Process

Abstract:

Dissimilatory reduction of sulfate, mediated by various species of sulfate-reducing bacteria (SRB), can be used to remediate acid mine drainage (AMD). Hydrogen sulfide (H₂S/HS^-) generated by SRB can be used to remove toxic metals from AMD as sulfide biominerals. For this, SRB are usually housed in separate reactor vessels to those where metal sulfides are generated; H₂S is delivered to AMD-containing vessels in solution or as a gas. This allows more controlled separation of metal precipitation and facilitates enhanced process control. Industries such as optoelectronics use quantum dots (QDs) in, for example, light emitting diodes and solar photovoltaics. QDs are nanocrystals with semiconductor bands that allow them to absorb light and re-emit it intensely at specific wavelength couples. Small nanoparticles have the possibility to get electrons shifted to a higher energy and then emit light during the relaxation phase. The QD elemental composition and the presence of doping agent determines its electronic band gaps and can be used to tune the QD to desired emission wavelengths. Traditional QD production at scale is costly and/or complex. Waste H₂S gas from growth of SRB has been used to make zinc sulfide QDs which are indistinguishable from ’classically’ prepared counterparts with respect to their physical and optical properties. Clean recycling of minewater bioremediation process waste gas into high value QD product is described.

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Periodical:

Advanced Materials Research (Volume 1130)

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555-559

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1130.555

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November 2015

Authors:

Jimmy Roussel, A.J. Murray, John Rolley, D. Barrie Johnson, L.E. Macaskie

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H₂S Waste Sulfate-Reducing Bacteria, Quantum Dots

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