Composite of medium‐chain‐length polyhydroxyalkanoates‐<i>co</i>‐methyl acrylate and carbon nanotubes as innovative electrodes modifier in microbial fuel cell

Sirajudeen, Abdul Azeez Olayiwola; Annuar, Mohamad Suffian Mohamad; Subramaniam, Ramesh

doi:10.1002/bab.1928

Cited by 9 publications

(5 citation statements)

References 49 publications

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“…Bacterial polyhydroxyalkanoates (PHAs) are biobased polyesters that can be used as commodity plastics 1 and have attracted considerable interest because of their superior biodegradability in a range of different natural environments, including the sea 2 . In addition, PHAs are used in a variety of potential applications, such as biocompatible materials 3 , components in composites 4,5 , and components in functionalized protein complexes 6 . A key technology for the practical use of PHAs is the regulation of their physical properties.…”

Section: Introductionmentioning

confidence: 99%

Artificial polyhydroxyalkanoate poly[2-hydroxybutyrate-block-3-hydroxybutyrate] elastomer-like material

Kageyama

Tomita

Isono

et al. 2021

Preprint

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The first polyhydroxyalkanoate (PHA) block copolymer poly(2-hydroxybutyrate-b-3-hydroxybutyrate) [P(2HB-b-3HB)] was previously synthesized using engineered Escherichia coli expressing a chimeric PHA synthase PhaCAR with monomer sequence-regulating capacity. In the present study, the physical properties of the block copolymer and its relevant random copolymer P(2HB-ran-3HB) were evaluated. Stress–strain tests on the P(88 mol% 2HB-b-3HB) film showed an increasing stress value during elongation up to 393%. In addition, the block copolymer film exhibited slow contraction behavior after elongation, indicating that P(2HB-b-3HB) is an elastomer-like material. In contrast, the P(92 mol% 2HB-ran-3HB) film, which was stretched up to 692% with nearly constant stress, was stretchable but not elastic. The differential scanning calorimetry and wide-angle X-ray diffraction analyses indicated that the P(2HB-b-3HB) contained the amorphous P(2HB) phase and the crystalline P(3HB) phase, whereas P(2HB-ran-3HB) was wholly amorphous. Therefore, the elasticity of P(2HB-b-3HB) can be attributed to the presence of the crystalline P(3HB) phase. These results show the potential of block PHAs as elastic materials.

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Section: Introductionmentioning

confidence: 99%

Artificial polyhydroxyalkanoate poly[2-hydroxybutyrate-block-3-hydroxybutyrate] elastomer-like material

Kageyama

Tomita

Isono

et al. 2021

Preprint

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“…173 The development of PEM using microorganisms like, polyhydroxybutyrate and polyhydroxyalkanoate, could somehow overcome the highly cost of Nafion and thus highly improved. Sirajudeen et al 174 worked on wastewater treatment and electrical generation via microbial fuel cell application. The PEM was made up of fixed concentration of mediumchain length polyhydroxyalkanoates (mcl-PHAs) and 5-15 wt% of polyhydroxybutyrate (PHB) blend.…”

Section: Electrochemistry Performancementioning

confidence: 99%

Recent biopolymers used for membrane fuel cells: Characterization analysis perspectives

Musa

Shaari

Kamarudin

et al. 2022

Intl J of Energy Research

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The emergence of biopolymers as polymer electrolyte membrane for non-Nafion used fuel cell application in recent years was an impactful finding. This review gives a different approach to researchers, by exposing the characterization analysis perspectives of developed materials from biomass sourcesalginates, carrageenan, cellulose, chitosan and polyhydroxyalkanoates. Their membrane performances are proven in this work through chemistry understandings, hence assuring a clear picture to gain information of these biopolymers' behavior as PEM. These five bio-precursor materials are believed to perform as high potential PEM alternatives, thus this study appeared to be an insightful guidance to the industry replacing high cost Nafion membrane to a lower cost membrane sources for future massive production economically benign. HIGHLIGHTS• Biopolymers are one of the promising natural sources to be utilized as the essential PEM in fuel cell • These biopolymers to be highlighted in this review are alginates, chitosan, carrageenan, cellulose and starch • Electronic biopolymers like carbon composites, hydrogels, nucleic acid, polyester, polysaccharide and protein imposed great features with their abundant functional groups, strong electrical conductivity, excellent ion conduction, versatility and stability

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“…13 It is hypothesized that the superiority in mcl-PHA-co-PEGMA/MWCNT electrode originates from its better biocompatibility and synergistic relationship between the Escherichia coli biocatalyst and the modified anode surface. Recently, Sirajudeen et al 16 modified the surface of purified CC with amphiphilic mcl-PHA-co-methyl acrylate composited with functionalized MWCNT as electrode modifier. The modified anode electrode shows improved conductivity, superior redox peak, stable and elevated voltage and enhanced power and current densities, attributed to improved electron transfer rate on modified anode surface.…”

Section: Nanocomposites Of Polyestersmentioning

confidence: 99%

“…The modified anode electrode shows improved conductivity, superior redox peak, stable and elevated voltage and enhanced power and current densities, attributed to improved electron transfer rate on modified anode surface. 16 Polycaprolactone (PCL) nano-and micro-fibers have also been composited with gold particles and utilized as anode modifier. 36 While high activation loss and high internal resistance are reported, the modified electrode nonetheless shows an improved stability of maximum voltage at 600 mV up to 10 days MFC operation.…”

Section: Nanocomposites Of Polyestersmentioning

confidence: 99%

“…Modification of the anode electrode with polymeric nanocomposites has been reported to reduce internal resistance and improve overall MFC performance arising from more efficient extracellular transfer of electrons to the anode surface. [12][13][14][15][16] A detail review article addressing anode modifications for improved MFC performance has been presented by Hindatu et al 12 . Recent anode modifications with polymeric nanomaterials are discussed herewith.…”

Section: Introductionmentioning

confidence: 99%

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Polymeric nanocomposition for innovative functional enhancement of electrodes and proton exchange membrane in microbial fuel cell

Sirajudeen

Annuar

2021

JSCS

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Practical application of microbial fuel cell (MFC), a sustainable energy device, is hampered by low power output. Its principal components i.e. anode, cathode and proton exchange membrane (PEM) are the focus of enhancement and modification in terms of their functional design and material. The anode surface conduciveness as electron sink is crucial to the power output magnitude, while the cathode electrode should be reactive for efficient oxygen reduction at tri-phase junction. PEM is solely responsible for unidirectional proton flow concomitantly completing the electrical circuit. Polymeric nanocomposites as electrode modifier improved significantly anode/cathode/PEM functions thus overall MFC performance. The review highlights the progress made in polymer-based modifications to anode, cathode and PEM material and function between year 2014 to 2019. The effects to biocompatibility, surface area, internal resistance, electrochemical activities, environmental sustainability, and overall MFC performance are discussed.

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Composite of medium‐chain‐length polyhydroxyalkanoates‐co‐methyl acrylate and carbon nanotubes as innovative electrodes modifier in microbial fuel cell

Cited by 9 publications

References 49 publications

Artificial polyhydroxyalkanoate poly[2-hydroxybutyrate-block-3-hydroxybutyrate] elastomer-like material

Artificial polyhydroxyalkanoate poly[2-hydroxybutyrate-block-3-hydroxybutyrate] elastomer-like material

Recent biopolymers used for membrane fuel cells: Characterization analysis perspectives

Polymeric nanocomposition for innovative functional enhancement of electrodes and proton exchange membrane in microbial fuel cell

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