Optimising the transport properties and reactivity of microbially-synthesised magnetite for in situ remediation

Nimisha Joshi; Feixue Liu; Mathew Paul Watts; Heather Williams; Victoria S. Coker; Doris Schmid; Thilo Hofmann; Jonathan R. Lloyd

doi:10.1038/s41598-018-21733-y

Optimising the transport properties and reactivity of microbially-synthesised magnetite for in situ remediation

Nimisha Joshi, Feixue Liu, Mathew Paul Watts, Heather Williams, Victoria S. Coker, Doris Schmid, Thilo Hofmann, Jonathan R. Lloyd

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Engineered nanoparticles offer the potential for remediation of land and water that has been contaminated by organics and metals. Microbially synthesized nano-scale magnetite, prepared from Fe(III) oxides by subsurface Fe(III)-reducing bacteria, offers a scalable biosynthesis route to such a nano-scale remediation reagent. To underpin delivery of “bionanomagnetite” (BNM) nanomaterial during in situ treatment options, we conducted a range of batch and column experiments to assess and optimise the transport and reactivity of the particles in porous media. Collectively these experiments, which include state of the art gamma imaging of the transport of 99m Tc-labelled BNM in columns, showed that non-toxic, low cost coatings such as guar gum and salts of humic acid can be used to enhance the mobility of the nanomaterial, while maintaining reactivity against target contaminants. Furthermore, BNM reactivity can be enhanced by the addition of surface coatings of nano-Pd, extending the operational lifetime of the BNM, in the presence of a simple electron donor such as hydrogen or formate.

Original language	English
Article number	4246
Number of pages	12
Journal	Scientific Reports
Volume	8
DOIs	https://doi.org/10.1038/s41598-018-21733-y
Publication status	Published - 9 Mar 2018

Austrian Fields of Science 2012

104023 Environmental chemistry
104002 Analytical chemistry
105906 Environmental geosciences

Keywords

ZERO-VALENT IRON
ZEROVALENT IRON
GEOBACTER-SULFURREDUCENS
GROUNDWATER REMEDIATION
OXIDE NANOPARTICLES
POROUS-MEDIA
ORGANIC-MATTER
GUAR GUM
AGGREGATION
PARTICLES
STABILIZATION
SEDIMENTATION
ADSORPTION
VALENT IRON NANOPARTICLES
CR(VI)
GROUNDWATER

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http://phaidra.univie.ac.at/o:1075126Licence: CC BY 4.0

Cite this

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title = "Optimising the transport properties and reactivity of microbially-synthesised magnetite for in situ remediation",

abstract = "Engineered nanoparticles offer the potential for remediation of land and water that has been contaminated by organics and metals. Microbially synthesized nano-scale magnetite, prepared from Fe(III) oxides by subsurface Fe(III)-reducing bacteria, offers a scalable biosynthesis route to such a nano-scale remediation reagent. To underpin delivery of “bionanomagnetite” (BNM) nanomaterial during in situ treatment options, we conducted a range of batch and column experiments to assess and optimise the transport and reactivity of the particles in porous media. Collectively these experiments, which include state of the art gamma imaging of the transport of 99m Tc-labelled BNM in columns, showed that non-toxic, low cost coatings such as guar gum and salts of humic acid can be used to enhance the mobility of the nanomaterial, while maintaining reactivity against target contaminants. Furthermore, BNM reactivity can be enhanced by the addition of surface coatings of nano-Pd, extending the operational lifetime of the BNM, in the presence of a simple electron donor such as hydrogen or formate.",

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author = "Nimisha Joshi and Feixue Liu and Watts, {Mathew Paul} and Heather Williams and Coker, {Victoria S.} and Doris Schmid and Thilo Hofmann and Lloyd, {Jonathan R.}",

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doi = "10.1038/s41598-018-21733-y",

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AU - Joshi, Nimisha

AU - Liu, Feixue

AU - Watts, Mathew Paul

AU - Williams, Heather

AU - Coker, Victoria S.

AU - Schmid, Doris

AU - Hofmann, Thilo

AU - Lloyd, Jonathan R.

PY - 2018/3/9

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N2 - Engineered nanoparticles offer the potential for remediation of land and water that has been contaminated by organics and metals. Microbially synthesized nano-scale magnetite, prepared from Fe(III) oxides by subsurface Fe(III)-reducing bacteria, offers a scalable biosynthesis route to such a nano-scale remediation reagent. To underpin delivery of “bionanomagnetite” (BNM) nanomaterial during in situ treatment options, we conducted a range of batch and column experiments to assess and optimise the transport and reactivity of the particles in porous media. Collectively these experiments, which include state of the art gamma imaging of the transport of 99m Tc-labelled BNM in columns, showed that non-toxic, low cost coatings such as guar gum and salts of humic acid can be used to enhance the mobility of the nanomaterial, while maintaining reactivity against target contaminants. Furthermore, BNM reactivity can be enhanced by the addition of surface coatings of nano-Pd, extending the operational lifetime of the BNM, in the presence of a simple electron donor such as hydrogen or formate.

AB - Engineered nanoparticles offer the potential for remediation of land and water that has been contaminated by organics and metals. Microbially synthesized nano-scale magnetite, prepared from Fe(III) oxides by subsurface Fe(III)-reducing bacteria, offers a scalable biosynthesis route to such a nano-scale remediation reagent. To underpin delivery of “bionanomagnetite” (BNM) nanomaterial during in situ treatment options, we conducted a range of batch and column experiments to assess and optimise the transport and reactivity of the particles in porous media. Collectively these experiments, which include state of the art gamma imaging of the transport of 99m Tc-labelled BNM in columns, showed that non-toxic, low cost coatings such as guar gum and salts of humic acid can be used to enhance the mobility of the nanomaterial, while maintaining reactivity against target contaminants. Furthermore, BNM reactivity can be enhanced by the addition of surface coatings of nano-Pd, extending the operational lifetime of the BNM, in the presence of a simple electron donor such as hydrogen or formate.

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Optimising the transport properties and reactivity of microbially-synthesised magnetite for in situ remediation

Abstract

Austrian Fields of Science 2012

Keywords

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