Influence of microbial activity on carbonate dominated mineral precipitates in tunnel drainage systems

Publikation: KonferenzbeitragPosterForschungBegutachtung

Abstract

Carbonate scaling in motor-and railway tunnel drainages causes seriousproblems due to narrowed flow cross sections and clogging. Their removal generates high costs and traffic disturbances, arguing for an enhancedunderstanding of installation-specificchemical and mineralogical compositions, microstructures, and environmental controlson theirformationand material characteristics. From asubstantialset of case studiesconductedin Austria, distinct types of scale materialscan be distinguished ranging from unconsolidated softand poroussediments to compactincrustationswith distinct microstructure, mineralogy and variable porosity. In contrast to existingconcepts, nearly all of the investigated scale types indicate a significant impact of microbial communitieson scaledeposition. Even in site-specific aqueous solutions, several types of bacteria could be detected. Documentedchemoautotroph bacteria in these tunnel drainage solutions comprise ofGallionella sp., Leptothrix sp.,Thiothrix,methylococcales, as wellas rare photosynthetic algae. Metabolisms rangefrom Fe(II) to Fe (III) oxidation, methanotrophy, sulfur oxidizing and sulphat reduzingto photosynthesis. Thus,next toinorganically driven mineral precipitation of,e.g. calcite, aragonite, brucite, ferrihydriteand silica, distinct biomineralization products such asFe/Mn–(hydr)oxides and(Mg-) calcite have to be considered. In the latter casesextracellularpolymeric substances seem to play a vitalrole for the consolidation and stiffness of the resultingcomplexand spatiotemporally evolvedscale deposits. An advanced process understandingofthe individual evolution, composition, and character of scaling in drainage systemswould allow fortailored monitoring procedures, countermeasuresand cleaning strategies in order to tackle unwanted scaling in tunnels.
Originalspracheenglisch
PublikationsstatusVeröffentlicht - 20 Aug 2019
VeranstaltungGoldschmidt Conference - Barcelona, Spanien
Dauer: 18 Aug 201923 Aug 2019

Konferenz

KonferenzGoldschmidt Conference
LandSpanien
OrtBarcelona
Zeitraum18/08/1923/08/19

Fields of Expertise

  • Advanced Materials Science

Dies zitieren

Eichinger, S., Boch, R., Koraimann, G., Leis, A., & Dietzel, M. (2019). Influence of microbial activity on carbonate dominated mineral precipitates in tunnel drainage systems. Postersitzung präsentiert bei Goldschmidt Conference, Barcelona, Spanien.

Influence of microbial activity on carbonate dominated mineral precipitates in tunnel drainage systems. / Eichinger, Stefanie; Boch, Ronny; Koraimann, Günther; Leis, Albrecht; Dietzel, Martin.

2019. Postersitzung präsentiert bei Goldschmidt Conference, Barcelona, Spanien.

Publikation: KonferenzbeitragPosterForschungBegutachtung

Eichinger S, Boch R, Koraimann G, Leis A, Dietzel M. Influence of microbial activity on carbonate dominated mineral precipitates in tunnel drainage systems. 2019. Postersitzung präsentiert bei Goldschmidt Conference, Barcelona, Spanien.
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abstract = "Carbonate scaling in motor-and railway tunnel drainages causes seriousproblems due to narrowed flow cross sections and clogging. Their removal generates high costs and traffic disturbances, arguing for an enhancedunderstanding of installation-specificchemical and mineralogical compositions, microstructures, and environmental controlson theirformationand material characteristics. From asubstantialset of case studiesconductedin Austria, distinct types of scale materialscan be distinguished ranging from unconsolidated softand poroussediments to compactincrustationswith distinct microstructure, mineralogy and variable porosity. In contrast to existingconcepts, nearly all of the investigated scale types indicate a significant impact of microbial communitieson scaledeposition. Even in site-specific aqueous solutions, several types of bacteria could be detected. Documentedchemoautotroph bacteria in these tunnel drainage solutions comprise ofGallionella sp., Leptothrix sp.,Thiothrix,methylococcales, as wellas rare photosynthetic algae. Metabolisms rangefrom Fe(II) to Fe (III) oxidation, methanotrophy, sulfur oxidizing and sulphat reduzingto photosynthesis. Thus,next toinorganically driven mineral precipitation of,e.g. calcite, aragonite, brucite, ferrihydriteand silica, distinct biomineralization products such asFe/Mn–(hydr)oxides and(Mg-) calcite have to be considered. In the latter casesextracellularpolymeric substances seem to play a vitalrole for the consolidation and stiffness of the resultingcomplexand spatiotemporally evolvedscale deposits. An advanced process understandingofthe individual evolution, composition, and character of scaling in drainage systemswould allow fortailored monitoring procedures, countermeasuresand cleaning strategies in order to tackle unwanted scaling in tunnels.",
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T1 - Influence of microbial activity on carbonate dominated mineral precipitates in tunnel drainage systems

AU - Eichinger, Stefanie

AU - Boch, Ronny

AU - Koraimann, Günther

AU - Leis, Albrecht

AU - Dietzel, Martin

PY - 2019/8/20

Y1 - 2019/8/20

N2 - Carbonate scaling in motor-and railway tunnel drainages causes seriousproblems due to narrowed flow cross sections and clogging. Their removal generates high costs and traffic disturbances, arguing for an enhancedunderstanding of installation-specificchemical and mineralogical compositions, microstructures, and environmental controlson theirformationand material characteristics. From asubstantialset of case studiesconductedin Austria, distinct types of scale materialscan be distinguished ranging from unconsolidated softand poroussediments to compactincrustationswith distinct microstructure, mineralogy and variable porosity. In contrast to existingconcepts, nearly all of the investigated scale types indicate a significant impact of microbial communitieson scaledeposition. Even in site-specific aqueous solutions, several types of bacteria could be detected. Documentedchemoautotroph bacteria in these tunnel drainage solutions comprise ofGallionella sp., Leptothrix sp.,Thiothrix,methylococcales, as wellas rare photosynthetic algae. Metabolisms rangefrom Fe(II) to Fe (III) oxidation, methanotrophy, sulfur oxidizing and sulphat reduzingto photosynthesis. Thus,next toinorganically driven mineral precipitation of,e.g. calcite, aragonite, brucite, ferrihydriteand silica, distinct biomineralization products such asFe/Mn–(hydr)oxides and(Mg-) calcite have to be considered. In the latter casesextracellularpolymeric substances seem to play a vitalrole for the consolidation and stiffness of the resultingcomplexand spatiotemporally evolvedscale deposits. An advanced process understandingofthe individual evolution, composition, and character of scaling in drainage systemswould allow fortailored monitoring procedures, countermeasuresand cleaning strategies in order to tackle unwanted scaling in tunnels.

AB - Carbonate scaling in motor-and railway tunnel drainages causes seriousproblems due to narrowed flow cross sections and clogging. Their removal generates high costs and traffic disturbances, arguing for an enhancedunderstanding of installation-specificchemical and mineralogical compositions, microstructures, and environmental controlson theirformationand material characteristics. From asubstantialset of case studiesconductedin Austria, distinct types of scale materialscan be distinguished ranging from unconsolidated softand poroussediments to compactincrustationswith distinct microstructure, mineralogy and variable porosity. In contrast to existingconcepts, nearly all of the investigated scale types indicate a significant impact of microbial communitieson scaledeposition. Even in site-specific aqueous solutions, several types of bacteria could be detected. Documentedchemoautotroph bacteria in these tunnel drainage solutions comprise ofGallionella sp., Leptothrix sp.,Thiothrix,methylococcales, as wellas rare photosynthetic algae. Metabolisms rangefrom Fe(II) to Fe (III) oxidation, methanotrophy, sulfur oxidizing and sulphat reduzingto photosynthesis. Thus,next toinorganically driven mineral precipitation of,e.g. calcite, aragonite, brucite, ferrihydriteand silica, distinct biomineralization products such asFe/Mn–(hydr)oxides and(Mg-) calcite have to be considered. In the latter casesextracellularpolymeric substances seem to play a vitalrole for the consolidation and stiffness of the resultingcomplexand spatiotemporally evolvedscale deposits. An advanced process understandingofthe individual evolution, composition, and character of scaling in drainage systemswould allow fortailored monitoring procedures, countermeasuresand cleaning strategies in order to tackle unwanted scaling in tunnels.

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