Geochemical Study of Weathered Coal, a Co-Substrate for Bioremediation of South African Coal Discard Dumps

Breugel, Yvonne van; Cowan, A. Keith; Tsikos, Harilaos

doi:10.3390/min9120772

Cited by 4 publications

(1 citation statement)

References 34 publications

(55 reference statements)

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“…In contrast, the present study used substrates not treated with HNO 3 . Rather, coal discard and a geologically weathered coal were used, the latter with substantially higher oxygen concentration (Table 1), decreased aromaticity and abundant C-16 and C-18 fatty acids (van Breugel et al 2019) and, without any confounding influence of nitrous acid and its associated nitrosation reactions.…”

Section: Discussionmentioning

confidence: 99%

Bacterial degradation of coal discard and geologically weathered coal

Olawale

Edeki

Cowan

2020

Int J Coal Sci Technol

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The biodegradation of coal discard is being intensively studied in South Africa in an effort to develop passive methods for the successful revegetation and rehabilitation of waste dumps, to mitigate pollution, and facilitate mine closure. Bacteria were isolated from slurries of coal tailings and diesel-contaminated soil, screened for coal biodegradation competence, characterized, and the colonization and degradation of coal discard and geologically weathered coal investigated using individual isolates and consortia. Ten novel coal-degrading bacterial strains were isolated and characterized, the gene sequences deposited with GenBank, and the (wild-type) strains deposited at Microbial Culture Collection, India. The results from the present work show that bituminous coal discard and geologically weathered coal is used by these isolates as carbon and energy source. Isolated strains and consortia colonized and degraded both coal substrates. Growth rate of the isolates is faster and stationery phase achieved sooner in minimal medium containing geologically weathered coal. This observation suggests that the oxygen-rich weathered coal is a more friable substrate and thus readily colonised and biodegraded. A reduction in mass of substrate is demonstrated for both individual isolates and consortia. The changes in pH and associated media colouration occurred concomitant with formation of humic acid-like (HS) and fulvic acid-like substances (FS) which is confirmed following analysis of these products by FT-IR spectroscopy. It is concluded that preferential metabolism of alkanes from the coal substrates provided the carbon and energy for bacterial growth and transformation of the substrates to HS and FS. Keywords Bacteria Á Biodegradation Á Coal discard Á Humic acid Á Fulvic acid Á FT-IR Á Geologically weathered coal Abbreviations CYP Cytochrome P450 DPA Diphenylamine ECCN EBRU culture collection number FT-IR Fourier transform infrared spectroscopy FA Fulvic acid FS Fulvic acid-like substances HA Humic acid HS Humic acid-like substances LAC Laccase PAH Poly aromatic hydrocarbon Electronic supplementary material The online version of this article (

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Section: Discussionmentioning

confidence: 99%

Bacterial degradation of coal discard and geologically weathered coal

Olawale

Edeki

Cowan

2020

Int J Coal Sci Technol

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Critical steps in the restoration of coal mine soils: Microbial-accelerated soil reconstruction

Lu,

Wang,

Wang

et al. 2024

Journal of Environmental Management

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Study on Separation Kinetics of Non-Spherical Single Feeding Particle in the Gas–Solid Separation Fluidized Bed

Fan,

Fu,

et al. 2024

Separations

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Gas–solid separation fluidized bed is an efficient and clean coal separation technology with a good separation effect for coal particles. However, there is a lack of systematic research on the complex motion behavior of the feeding particles in gas–solid separation fluidized beds. In this study, the separation kinetics of non-spherical single feeding particles in the fluidized bed are examined. The particle sphericity coefficient Φ is introduced to characterize the morphology of irregular coal particles, and the drag coefficient for the feeding particles is modified to verify the suitability of the non-spherical particle drag model for gas–solid fluidized bed separation. After optimization and correction, a ρS.sus (the bed density when single feeding particles are suspended in the gas–solid separation fluidized bed) prediction model is obtained. When the prediction accuracy of the ρS.sus prediction model is 90%, the confidence degree is 85.72%. This ρS.sus of the single non-spherical feeding particle prediction model highlights a direction for improving the separation effect, provides a theoretical basis for the industrialization of gas–solid fluidized bed, and promotes the process of dry fluidized separation.

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Geochemical Study of Weathered Coal, a Co-Substrate for Bioremediation of South African Coal Discard Dumps

Cited by 4 publications

References 34 publications

Bacterial degradation of coal discard and geologically weathered coal

Bacterial degradation of coal discard and geologically weathered coal

Critical steps in the restoration of coal mine soils: Microbial-accelerated soil reconstruction

Study on Separation Kinetics of Non-Spherical Single Feeding Particle in the Gas–Solid Separation Fluidized Bed

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