Evaluation of Algal Biofilms on Indium Tin Oxide (ITO) for Use in Biophotovoltaic Platforms Based on Photosynthetic Performance

Ng, Fong-Lee; Phang, Siew‐Moi; Periasamy, Vengadesh; Yunus, Kamran; Fisher, Adrian C.

doi:10.1371/journal.pone.0097643

Cited by 63 publications

(47 citation statements)

References 46 publications

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“…17 From the level of microbial communities, observing the anode can supplement highthroughput sequencing. From the level of the microstructure of microorganisms, it can provide direct evidence of electrochemically active microbe (EAM) nanowires.…”

Section: 16mentioning

confidence: 99%

Interaction of bacteria and archaea in a microbial fuel cell with ITO anode

et al. 2018

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A microbial fuel cell with an indium tin oxide (ITO) coated glass anode was used to study the mechanism of electricity generation and electron transfer of electrochemically active microbes (EAMs). A simple method of ITO anode pretreatment (pickling) was developed to improve the performance of the microbial fuel cell.After proper treatment, ITO-glass anodes maintained their conductivity with a slight increase in resistance.Using this pickling pretreatment, the ITO-glass microbial fuel cell with an anode area of only 8.3 cm 2 , was successfully initiated and obtained a stable voltage and power output of 418.8 mW m À2 . The electrode material with pretreatment showed optimal performance for the in situ study of EAMs. DNA was extracted from various parts of the reactor and the microbial communities were analyzed. The results indicated that the large proportion of methane-related microbes on the cathode of the MFC was one of the reasons for its high COD removal and low columbic efficiency. ITO glass is suitable as an anode material for the in situ study of EAMs, and shows potential for practical application.Microbial fuel cells (MFCs) are one type of "green energy generating" device that is able to convert the chemical energy of organic matter into electrical energy.1 The process of conversion from chemical energy to electrical energy takes place during wastewater treatment using MFCs. This type of device utilizes microorganisms as the biocatalyst and has attracted a great deal of attention from researchers around the world. 1-4Studies of MFCs have been mainly focused in a few specic areas: increasing the efficiency of converting organic matter into electrical energy, reducing the cost of assembling the reactors, and the mechanism of MFCs that converts chemical energy into electrical energy. 2,4-6In the rst step of energy conversion, microorganisms at the MFC anode consume organic matter from their growth medium and release electrons.7 To study this critical step involving the anode, the microorganisms located their, and their mechanism of electron deposition, it is necessary to choose proper anodic materials. 8At present, more and more choices have got to fabricate or modify the electrode of MFCs, with nanomaterials, nanocomposites, graphene sheet and graphene oxides owing to their high surface area, porosity and prompt electron conduction properties.9-13 The results showed that the electrodes fabricated or modied by nonamaterials exhibited excellent electrochemical activity. Signicant redox peaks have found in cyclic voltammograms and electricity production of the MFCs also obtained.To harvest the largest columbic efficiencies and chemical oxygen demand (COD) removal efficiencies, most MFC anodes are carbon-felt brushes with a large surface area.

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Section: 16mentioning

confidence: 99%

Interaction of bacteria and archaea in a microbial fuel cell with ITO anode

et al. 2018

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“…5 The use of suspension algal cultures to biofilms 6 and finally alginate-immobilized systems 7 resulted in further increase in power density. 5 The use of suspension algal cultures to biofilms 6 and finally alginate-immobilized systems 7 resulted in further increase in power density.…”

Section: Discussionmentioning

confidence: 99%

“…For the immobilized algae BPV device, the anode had the algal-alginate film (prepared as described in Section 2.2) attached to its surface ( Figure 1) and was sealed with polydimethylsiloxane (PDMS) before 2 mL Bold's Basal Medium was loaded to the device. 5,6,37 Crocodile clips and copper wires were used to connect the anode and cathode to the external circuit. 5,6,37 Crocodile clips and copper wires were used to connect the anode and cathode to the external circuit.…”

Section: Algal Bpv Devices and Experimental Set-upmentioning

confidence: 99%

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Effect of different irradiance levels on bioelectricity generation from algal biophotovoltaic (BPV) devices

Thong

Phang

et al. 2019

Energy Science & Engineering

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Rapid population and economic growth in the world have accelerated the search for new sustainable and environment‐friendly energy sources. Power‐producing systems generally add to the carbon load in the environment, contributing to global climate change. In photosynthesis, energy from light splits water molecules into oxygen, protons, and electrons. Algal biophotovoltaic (BPV) platforms were developed to harvest these electrons to generate bioelectricity through algal photosynthesis. Irradiance is one of the most important parameters that determine power output efficiency from algal BPV devices. In this study, the effective range of irradiance levels for power generation from algal BPV devices comprising of suspension and alginate‐immobilized Chlorella cultures on ITO anodes was determined. Immobilized cultures were prepared by entrapping the algal cells in 2% sodium alginate solution. The algal BPV devices were illuminated by four different irradiance levels (30, 90, 150, and 210 µmol photons m−2 s−1). The maximum power density of 0.456 mW m−2 was generated from the prototype algal fuel cell at the irradiance level of 150 µmol photons m−2 s−1. At 210 µmol photons m−2 s−1, low power density was produced due to photoinhibition as indicated by Fv/Fm values generated through PAM fluorometry. In terms of carbon fixation rate, the highest value was recorded in immobilized culture at 217.11 mg CO2 L−1 d−1. The algal biophotovoltaic device is multifunctional and can provide sustainable energy with simultaneous carbon dioxide removal.

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“…Earlier a series of photosynthetic organisms were evaluated in BPVs e. g., Ng et al. investigated sixteen different algal strain biofilms on indium tin oxide for photocurrent generation, McCormick et al. reported mediator‐less BPV system based on photosynthetic biofilms in pure culture .…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Photocurrent Generation from Different Photosynthetic Organisms

et al. 2017

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Biological photovoltaics (BPVs) are emerging as a potential sustainable energy‐generating technology to convert solar energy into electrical energy. Although a great variety of photosynthetic biomaterials were studied in BPVs, cyanobacteria are considered as superior candidates because of their simpler physiology. To facilitate extracellular electron transfer (EET) from cyanobacteria to electrodes is the greatest challenge to improving the performance of BPVs. However, a systematic study comparing the photo‐excited EET from such organisms is not yet reported. Here we report on a comparison of photocurrent density generated by benthic cyanobacteria, that is, two species of Leptolyngbya sp. (CAWBG62 and CAWBG100), one species from the order Chroococcales (CAWBG64), and a eukaryotic algae, Paulschulzia pseudovolvox (UKE). This algae and CAWBG100 were sourced from New Zealand, CAWBG62 and CAWBG64 were from Antarctica. We demonstrate EET mediated by three different electron transfer (ET) mediating systems on graphite electrodes. These are as follows: (I) [Os(2,2’‐(bipyridine)2(polyvinyl‐imidazole)10Cl]+/2+ (1:9) [Os‐(bpy)PVI] (II) p‐benzoquinone (PBQ) (III) [Os‐(bpy)PVI] together with PBQ. The maximum photocurrent density of 47.2 μA cm−2 was obtained from CAWBG64 mediated by (III) [Os‐(bpy)PVI] together with PBQ.

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Evaluation of Algal Biofilms on Indium Tin Oxide (ITO) for Use in Biophotovoltaic Platforms Based on Photosynthetic Performance

Cited by 63 publications

References 46 publications

Interaction of bacteria and archaea in a microbial fuel cell with ITO anode

Interaction of bacteria and archaea in a microbial fuel cell with ITO anode

Effect of different irradiance levels on bioelectricity generation from algal biophotovoltaic (BPV) devices

Evaluation of Photocurrent Generation from Different Photosynthetic Organisms

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