Continuous electron shuttling by sulfide oxidizing bacteria as a novel strategy to produce electric current

Rieks de Rink; Micaela Lavender; Dandan Liu; Johannes B.M. Klok; Dimitry Y. Sorokin; Annemiek  ter Heijne; Cees J.M. Buisman

doi:10.1016/j.jhazmat.2021.127358

Continuous electron shuttling by sulfide oxidizing bacteria as a novel strategy to produce electric current

Rieks de Rink, Micaela Lavender, Dandan Liu, Johannes B.M. Klok, Dimitry Y. Sorokin, Annemiek ter Heijne, Cees J.M. Buisman

BT/Environmental Biotechnology

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Abstract

Sulfide oxidizing bacteria (SOB) are widely applied in industry to convert toxic H2S into elemental sulfur. Haloalkaliphilic planktonic SOB can remove sulfide from solution under anaerobic conditions (SOB are ‘charged’), and release electrons at an electrode (discharge of SOB). The effect of this electron shuttling on product formation and biomass growth is not known. Here, we study and demonstrate a continuous process in which SOB remove sulfide from solution in an anaerobic ‘uptake chamber’, and shuttle these electrons to the
anode of an electrochemical cell, in the absence of dissolved sulfide. Two experiments over 31 and 41 days were performed. At a sulfide loading rate of 1.1 mmolS/day, electricity was produced continuously (3 A/m2) without
dissolved sulfide in the anolyte. The main end product was sulfate (56% in experiment 1% and 78% in experiment 2), and 87% and 77% of the electrons in sulfide were recovered as electricity. It was found that the current density was dependent on the sulfide loading rate and not on the anode potential. Biological growth occurred, mainly at the anode as biofilm, in which the delta-proteobacterial genus Desulfurivibrio was dominating. Our results demonstrate a novel strategy to produce electricity from sulfide in an electrochemical system.

Original language	English
Article number	127358
Pages (from-to)	1-19
Journal	Journal of Hazardous Materials
Volume	424
DOIs	https://doi.org/10.1016/j.jhazmat.2021.127358
Publication status	Published - 2022

Keywords

Bio-anode
Bioelectrochemistry
Microbial electrochemical system
Sulfide oxidizing bacteria (SOB)
Sulfide removal

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10.1016/j.jhazmat.2021.127358

continuous electron shuttle_Ricks_JHM2022Final published version, 3.72 MBLicence: CC BY-NC-ND

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title = "Continuous electron shuttling by sulfide oxidizing bacteria as a novel strategy to produce electric current",

abstract = "Sulfide oxidizing bacteria (SOB) are widely applied in industry to convert toxic H2S into elemental sulfur. Haloalkaliphilic planktonic SOB can remove sulfide from solution under anaerobic conditions (SOB are {\textquoteleft}charged{\textquoteright}), and release electrons at an electrode (discharge of SOB). The effect of this electron shuttling on product formation and biomass growth is not known. Here, we study and demonstrate a continuous process in which SOB remove sulfide from solution in an anaerobic {\textquoteleft}uptake chamber{\textquoteright}, and shuttle these electrons to theanode of an electrochemical cell, in the absence of dissolved sulfide. Two experiments over 31 and 41 days were performed. At a sulfide loading rate of 1.1 mmolS/day, electricity was produced continuously (3 A/m2) withoutdissolved sulfide in the anolyte. The main end product was sulfate (56% in experiment 1% and 78% in experiment 2), and 87% and 77% of the electrons in sulfide were recovered as electricity. It was found that the current density was dependent on the sulfide loading rate and not on the anode potential. Biological growth occurred, mainly at the anode as biofilm, in which the delta-proteobacterial genus Desulfurivibrio was dominating. Our results demonstrate a novel strategy to produce electricity from sulfide in an electrochemical system.",

keywords = "Bio-anode, Bioelectrochemistry, Microbial electrochemical system, Sulfide oxidizing bacteria (SOB), Sulfide removal",

author = "{de Rink}, Rieks and Micaela Lavender and Dandan Liu and Klok, {Johannes B.M.} and Sorokin, {Dimitry Y.} and {ter Heijne}, Annemiek and Buisman, {Cees J.M.}",

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language = "English",

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T1 - Continuous electron shuttling by sulfide oxidizing bacteria as a novel strategy to produce electric current

AU - de Rink, Rieks

AU - Lavender, Micaela

AU - Liu, Dandan

AU - Klok, Johannes B.M.

AU - Sorokin, Dimitry Y.

AU - ter Heijne, Annemiek

AU - Buisman, Cees J.M.

PY - 2022

Y1 - 2022

N2 - Sulfide oxidizing bacteria (SOB) are widely applied in industry to convert toxic H2S into elemental sulfur. Haloalkaliphilic planktonic SOB can remove sulfide from solution under anaerobic conditions (SOB are ‘charged’), and release electrons at an electrode (discharge of SOB). The effect of this electron shuttling on product formation and biomass growth is not known. Here, we study and demonstrate a continuous process in which SOB remove sulfide from solution in an anaerobic ‘uptake chamber’, and shuttle these electrons to theanode of an electrochemical cell, in the absence of dissolved sulfide. Two experiments over 31 and 41 days were performed. At a sulfide loading rate of 1.1 mmolS/day, electricity was produced continuously (3 A/m2) withoutdissolved sulfide in the anolyte. The main end product was sulfate (56% in experiment 1% and 78% in experiment 2), and 87% and 77% of the electrons in sulfide were recovered as electricity. It was found that the current density was dependent on the sulfide loading rate and not on the anode potential. Biological growth occurred, mainly at the anode as biofilm, in which the delta-proteobacterial genus Desulfurivibrio was dominating. Our results demonstrate a novel strategy to produce electricity from sulfide in an electrochemical system.

AB - Sulfide oxidizing bacteria (SOB) are widely applied in industry to convert toxic H2S into elemental sulfur. Haloalkaliphilic planktonic SOB can remove sulfide from solution under anaerobic conditions (SOB are ‘charged’), and release electrons at an electrode (discharge of SOB). The effect of this electron shuttling on product formation and biomass growth is not known. Here, we study and demonstrate a continuous process in which SOB remove sulfide from solution in an anaerobic ‘uptake chamber’, and shuttle these electrons to theanode of an electrochemical cell, in the absence of dissolved sulfide. Two experiments over 31 and 41 days were performed. At a sulfide loading rate of 1.1 mmolS/day, electricity was produced continuously (3 A/m2) withoutdissolved sulfide in the anolyte. The main end product was sulfate (56% in experiment 1% and 78% in experiment 2), and 87% and 77% of the electrons in sulfide were recovered as electricity. It was found that the current density was dependent on the sulfide loading rate and not on the anode potential. Biological growth occurred, mainly at the anode as biofilm, in which the delta-proteobacterial genus Desulfurivibrio was dominating. Our results demonstrate a novel strategy to produce electricity from sulfide in an electrochemical system.

KW - Bio-anode

KW - Bioelectrochemistry

KW - Microbial electrochemical system

KW - Sulfide oxidizing bacteria (SOB)

KW - Sulfide removal

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Continuous electron shuttling by sulfide oxidizing bacteria as a novel strategy to produce electric current

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