Chemical vs. Biological Crystals, all the Same?

Jan Weijma; Paula Gonzàles-Contreras; Cees N.J. Buisman

doi:10.4028/www.scientific.net/SSP.262.559

Paper Titles

Leaching of Pyrite by Acidithiobacillus ferrooxidans Monitored by Electrochemical Methods
p.541

X-Ray Diffraction of Iron Containing Samples: The Importance of a Suitable Configuration
p.545

Biogenic Iron Compounds for Hazardous Metal Remediation
p.551

Optimization of Bioscorodite Crystallization for Treatment of As(III)-Bearing Wastewaters
p.555

Chemical vs. Biological Crystals, all the Same?
p.559

Microbial Recycling of Precious and Rare Metals Sourced from Post-Consumer Products
p.563

Microbial Production of Schwertmannite: Development from Microbial Fundamentals to Marketable Products
p.568

Rare Earth Elements Recovery and Sulphate Removal from Phosphogypsum Waste Waters with Sulphate Reducing Bacteria
p.573

The Use of Algal Biomass to Sustain Sulfidogenic Bioreactors for Remediating Acidic Metal-Rich Waste Waters
p.577

HomeSolid State PhenomenaSolid State Phenomena Vol. 262Chemical vs. Biological Crystals, all the Same?

Chemical vs. Biological Crystals, all the Same?

Abstract:

Using microorganisms to mediate crystallisation of metals and minerals in open-culture bioreactors has potential to recover recyclable materials from dilute aqueous streams, but also to prevent their emission to the environment. Although this potential is already exploited in practice to some extent, biological crystallization for metal recovery is still largely a black box technology with limited understanding of the role of the microorganisms in the crystallization, and the differences with chemical crystallisation. Using biocrystallisation of scorodite (FeAsO₄.2H₂O) and sphalerite (ZnS) as examples we propose that the role of microorganisms strongly depends on established saturation state of the solution. For scorodite, microorganisms are used to exert control over the crystallization as their ferrous iron-oxidizing activity keeps the solution slightly oversaturated. Also, the oversaturation level is kept homogeneous because of continuous biological formation of the reactant ferrous iron throughout the solution. In continuous bioreactor experiments on which we reported previously, scorodite crystal sizes still increased after 72 days of bioreactor operation indicating that indeed crystal growth was favored over nucleation. On the other hand, in our experiments with zinc sulfide, crystallization proceeded in highly oversaturated solutions in a continuous sulfate reducing bioreactor fed with a zinc sulfate solution and H₂/CO₂ as electron donor and carbon source. The high oversaturation likely resulted in dominant primary nucleation in the bulk solution, with little or no control over crystal growth, even though agglomeration may still have occurred. This was exemplified by particle sizes which decreased in the bioreactor experiment and remained stable after already about 2 weeks of operation.

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Periodical:

Solid State Phenomena (Volume 262)

Pages:

559-562

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.262.559

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Online since:

August 2017

Authors:

Jan Weijma*, Paula Gonzàles-Contreras, Cees N.J. Buisman

Keywords:

Biocrystallisation, Bioreactor, Metals, Scorodite, Zinc Sulfide

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References

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