Lett fir46—53 Chltosan Electron transfer in Muscle building nutrition acidophilic bacterium: interaction Dance fitness and Zumba sessions a diheme cytochrome and a cupredoxin. These results indicate that chitosan-PVA-CaO composite membranes have excellent methanol barrier properties which in turn make them feasible for DMFC applications [ 3 ].

Chitosan for energy -

This is a preview of subscription content, log in via an institution to check access. Rent this article via DeepDyve. Institutional subscriptions. Altin, S. Article Google Scholar. Elshkaki, T. Graedel, Solar cell metals and their hosts: a tale of oversupply and undersupply. Energy , — Fant, C.

Adam Schlosser, K. Strzepek, The impact of climate change on wind and solar resources in southern Africa. Lojpur, J. Krstić, Z. Kačarević-Popović, N. Filipović, I. Magal, V. Selvaraj, A comparative study for the electrocatalytic oxidation of alcohol on Pt-Au nanoparticle-supported copolymer-grafted graphene oxide composite for fuel cell application.

Ionics 24 , — Zheng, A. Eseye, J. Zhang, H. Li, Short-term wind power forecasting using a double-stage hierarchical ANFIS approach for energy management in microgrid. Control Mod.

Power Syst. Sheu, A. Mitsos, Optimization of a hybrid solar-fossil fuel plant: solar steam reforming of methane in a combined cycle. Energy 51 , — Desideri, P.

Campana, Analysis and comparison between a concentrating solar and a photovoltaic power plant. Sobrino, C. Monroy, J. Pérez, Critical analysis on hydrogen as an alternative to fossil fuels and biofuels for vehicles in Europe.

Samsatli, N. Samsatli, The role of renewable hydrogen and inter-seasonal storage in decarbonising heat—comprehensive optimisation of future renewable energy value chains. Energy — , — Wang, S. Wang, Impacts of wind energy on environment: a review.

Energy Rev. Corazzari, R. Nisticò, F. Turci, M. Faga, F. Franzoso, S. Tabasso, G. Magnacca, Advanced physico-chemical characterization of chitosan by means of TGA coupled on-line with FTIR and GCMS: thermal degradation and water adsorption capacity. Guo, H. Liu, X. Chen, X. Ji, P. Li, Hydroxyl radicals scavenging activity of N-substituted chitosan and quaternized chitosan.

Pandiselvi, S. Ionics 20 , — Liu, B. Qin, L. He, R. Pan, T. Wu, H. Bao, L. Li, Green fabrication of chitosan films reinforced with parallel aligned graphene oxide.

Sahu, P. Sahu, S. Gupta, D. Agarwal, Chitosan: an efficient, reusable, and biodegradable catalyst for green synthesis of heterocycles. Buraidah, L. Teo, S. Majid, R.

Yahya, R. Taha, A. Arof, Characterizations of chitosan-based polymer electrolyte photovoltaic cells. Photoenergy , 1—7 Sadasivuni, K. Deshmukh, T. Ahipa, A. Muzaffar, M. Ahamed, S. Pasha, M. Al-Maadeed, Flexible, biodegradable and recyclable solar cells: a review. Google Scholar. Hao, Z. Zhao, Y.

Leng, J. Tian, Y. Sang, R. Boughton, C. Wong, H. Yang, Graphene-based nitrogen self-doped hierarchical porous carbon aerogels derived from chitosan for high performance supercapacitors.

Nano Energy. Sun, B. Li, J. Ran, X. Shen, H. Acta , 13—22 Yamagata, K. Soeda, S. Ikebe, S. Yamazaki, M. Ishikawa, Chitosan-based gel electrolyte containing an ionic liquid for high-performance nonaqueous supercapacitors.

Acta , — Ma, Y. Sahai, Chitosan biopolymer for fuel cell applications. Shaari, S. Kamarudin, Chitosan and alginate types of bio-membrane in fuel cell application: an overview. Power Sources , 71—80 Kalaiselvimary, M. Chupp, A. Shellikeri, G. Palui, J. Chatterjee, Chitosan-based gel film electrolytes containing ionic liquid and lithium salt for energy storage applications.

Hassan, M. Suzuki, A. El-Moneim, Synthesis of MnO 2 —chitosan nanocomposite by one-step electrodeposition for electrochemical energy storage application. Power Sources , 68—73 Ramkumar, M.

Minakshi, Fabrication of ultrathin CoMoO 4 nanosheets modified with chitosan and their improved performance in energy storage device.

Dalton Trans. Nasution, M. Balyan, I. Nainggolan, New application of chitosan film as a water vapor cell. Key Eng. Nainggolan, Improved lifetime of chitosan film in converting water vapor to electrical power by adding carboxymethyl cellulose. IOP Conf. Ghosh, M. AzamAli, R. Walls, Modification of microstructural morphology and physical performance of chitosan films.

Pradipkanti, D. Satapathy, Water desorption from a confined biopolymer. Soft Matter 14 , — Rinaudo, Chitin and chitosan: properties and applications. Sreekumar, F. Goycoolea, B. Moerschbacher, G.

Rivera-Rodriguez, Parameters influencing the size of chitosan-TPP nano- and microparticles. Begum, R. Pandian, V. Aswal, R. Ramasamy, Chitosan—gold—lithium nanocomposites as solid polymer electrolyte. Tuhin, N. Rahman, M. Haque, R. Shin, H. Sensors Actuators B Chem , — Pillai, C.

Chitin and chitosan polymers: Chemistry, solubility and fiber formation. El Ichi, S. Chitosan improves stability of carbon nanotube biocathodes for glucose biofuel cells.

Dash, M. Chitosan—A versatile semi-synthetic polymer in biomedical applications. Jeon, S. Underlying mechanism of antimicrobial activity of chitosan microparticles and implications for the treatment of infectious diseases.

PLoS One 9 , e Janaki, V. Polym 88 , — Huang, W. Optical properties of polyaniline. Polymer Guildf 34 , — Borah, R. Surface functionalization effects on structural, conformational, and optical properties of polyaniline nanofibers.

Met , — Fratoddi, I. Chemiresistive polyaniline-based gas sensors: A mini review. Qiu, S. Long-term corrosion protection of mild steel by epoxy coating containing self-doped polyaniline nanofiber.

Met , 39—46 Kohl, M. Effect of polyaniline salts on the mechanical and corrosion properties of organic protective coatings. Coatings 86 , 96— Kumar, L. Flexible room temperature ammonia sensor based on polyaniline. Zhang, K. Alloys Compd. Liao, G. The chemical modification of polyaniline with enhanced properties: A review.

Coatings , 35—43 Su, N. Improving electrical conductivity, thermal stability, and solubility of polyaniline-polypyrrole nanocomposite by doping with anionic spherical polyelectrolyte brushes. Nanoscale Res. ADS PubMed Central Google Scholar. Cao, Y. Counter-ion induced processibility of conducting polyaniline.

Met 57 , — Zhou, X. Solid State Electrochem. Effect of solvents and co-solvents on the processibility of polyaniline: I. solubility and conductivity studies. Met 69 , — Thanpitcha, T. Polym 64 , — Tiwari, A. Synthesis and characterization of electrical conducting chitosan-graft-polyaniline.

Express Polym. Lett 1 , — Shukla, S. Synthesis of chemical responsive chitosan—grafted-polyaniline bio-composite. Res — , 82—86 Luo, J. Part A Polym. Chem 50 , — Nguyen, V.

Chen, N. Kumar, N. Polyaniline-grafted reduced graphene oxide for efficient electrochemical supercapacitors. ACS Nano 6 , — Stankovich, S. Graphene-based composite materials. Nature , — Li, R.

J , — Chang, C. Carbon N. Y 50 , — Jafari, Y. Al-Mashat, L. C , — Synthesis and characterization of a novel electron conducting biocomposite as biofuel cell anode.

Fan, L. Colloids Surfaces B Biointerfaces , — Travlou, N. Jia, Z. Chinese Phys. B 27 , Wu, H. Multishelled metal oxide hollow spheres: Easy synthesis and formation mechanism.

J 22 , — Hummers, W. Preparation of graphitic oxide. Usman, F. Synthesis and characterisation of a ternary composite of polyaniline, reduced graphene-oxide and chitosan with reduced optical band gap and stable aqueous dispersibility.

Results Phys 15 , Mitra, M. Reduced graphene oxide-polyaniline composites—synthesis, characterization and optimization for thermoelectric applications. RSC Adv 5 , — Kabiri, R. Heller, A. Miniature biofuel cells. Electrocatalytic performance of chemically synthesized PIn-Au-SGO composite toward mediated biofuel cell anode.

Dai, Z. Direct electrochemistry of glucose oxidase immobilized on a hexagonal mesoporous silica-MCM matrix.

Bioelectrochemistry 70 , — Shan, C. Direct electrochemistry of glucose oxidase and biosensing for glucose based on graphene. Zhao, X. Direct electrochemistry and electrocatalysis of horseradish peroxidase based on clay—chitosan-gold nanoparticle nanocomposite.

Bioelectron 23 , — Campbell, A. ACS Appl. Interfaces 7 , — Laviron, E. Surface linear potential sweep voltammetry. Interfacial Electrochem 52 , — Liu, S.

Reagentless glucose biosensor based on direct electron transfer of glucose oxidase immobilized on colloidal gold modified carbon paste electrode. Bioelectron 19 , — Ehret, R. Monitoring of cellular behaviour by impedance measurements on interdigitated electrode structures.

Bioelectron 12 , 29—41 Kang, Z. RSC Adv 7 , — Kang, X. Glucose Oxidase—graphene—chitosan modified electrode for direct electrochemistry and glucose sensing. Bioelectron 25 , — Engel, A.

Optimization of chitosan film-templated biocathode for enzymatic oxygen reduction in glucose hybrid biofuel cell. Buckner, S. A metallacarborane redox mediator for an enzyme-immobilized chitosan-modified bioanode.

Bioelectrochemistry 78 , — Park, H. Solonaru, A. Lett 11 , — Patil, S. Effect of Camphor Sulfonic Acid Doping on Structural, Morphological, Optical and Electrical Transport Properties on Polyaniline-ZnO Nanocomposites. Soft Nanosci. Lett 02 , 46—53 Download references. This project was funded by the Deanship of Scientific Research DSR , King Abdulaziz University, Jeddah, under grant No.

The authors, therefore, gratefully acknowledge DSR technical and financial support. The authors are thankful to the Department of Applied Chemistry, Faculty of Engineering and Technology, Aligarh Muslim University, India for providing the research facilities.

Advanced Functional Materials Laboratory, Department of Applied Chemistry, Faculty of Engineering and Technology, Aligarh Muslim University, Aligarh, , India. Chemistry Department, Faculty of Science, King Abdulaziz University, P.

Box , Jeddah, , Saudi Arabia. You can also search for this author in PubMed Google Scholar. Formal analysis, S. All authors have read and agreed to the published version of the manuscript.

Correspondence to Inamuddin. Open Access This article is licensed under a Creative Commons Attribution 4. Reprints and permissions. Applications of chitosan CHI -reduced graphene oxide rGO -polyaniline PAni conducting composite electrode for energy generation in glucose biofuel cell.

Sci Rep 10 , Download citation. Received : 02 May Accepted : 05 June Published : 26 June Anyone you share the following link with will be able to read this content:. Sorry, a shareable link is not currently available for this article. Provided by the Springer Nature SharedIt content-sharing initiative.

Bioprocess and Biosystems Engineering Journal of Nanostructure in Chemistry By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily. Skip to main content Thank you for visiting nature. nature scientific reports articles article.

Download PDF. Subjects Chemistry Energy Energy science and technology Materials science. Introduction The pursuit of sustainable and green energy sources emerges because of the uneven geographical dispersal of fossil fuels, which are linked with the severe effects of environmental pollution.

Figure 1. Full size image. Materials and Method Materials Hydrazine hydrate N 2 H 4. Synthesis of rGO-PAni composite through in-situ polymerization A 1.

CHI rGO-PAni synthesis A solution was prepared by dissolving 0. Figure 2. Figure 3. FTIR spectra of a CHI, b rGO-PAni, and c CHI rGO-PAni. Table 1 FTIR peaks of CHI, rGO-PAni and CHI rGO-PAni. Full size table. Figure 4. Figure 5. Figure 6. Figure 7. Figure 8. Figure 9. Table 2 Comparison with the other similar studies employing CHI.

Figure Conclusion The synthesized CHI rGO-PAni biocomposite was used to construct a bioanode for glucose-based EFCs application showed good electrochemical properties along with substantial stability due to the collaborative effects among CHI, PAni, and rGO.

References Carrette, L. CAS Google Scholar Windmiller, J. CAS Google Scholar Zhong, Z. CAS Google Scholar Katz, E. CAS Google Scholar Fan, S.

CAS PubMed Google Scholar Rasmussen, M. CAS PubMed Google Scholar Calabrese Barton, S. Google Scholar Kim, J. CAS PubMed Google Scholar Cracknell, J. CAS PubMed Google Scholar Cosnier, S. ADS CAS Google Scholar Cosnier, S. CAS Google Scholar Xiao, X. CAS PubMed Google Scholar Kamitaka, Y.

CAS PubMed Google Scholar Hou, C. ADS CAS Google Scholar Sakai, K. CAS Google Scholar Ramanavicius, A. CAS Google Scholar Kontani, A. CAS Google Scholar Wang, X. CAS PubMed PubMed Central Google Scholar Zhang, L. PubMed Google Scholar Feng, R. CAS PubMed Google Scholar Ghindilis, A.

CAS Google Scholar Falk, M. CAS Google Scholar Kano, K. CAS Google Scholar Nasar, A. CAS Google Scholar Umar, M. ADS Google Scholar Axford, D. ADS Google Scholar Xu, D. ADS CAS PubMed Google Scholar Haque, S. ADS PubMed PubMed Central Google Scholar Inamuddin, Haque, S.

PubMed Google Scholar Perveen, R. CAS Google Scholar Perveen, R. CAS Google Scholar Pillai, C. CAS Google Scholar El Ichi, S. CAS Google Scholar Dash, M. CAS Google Scholar Jeon, S. ADS PubMed PubMed Central Google Scholar Janaki, V.

CAS Google Scholar Huang, W. CAS Google Scholar Borah, R. CAS Google Scholar Fratoddi, I. CAS Google Scholar Qiu, S. CAS Google Scholar Kohl, M. CAS Google Scholar Kumar, L. CAS Google Scholar Zhang, K. CAS Google Scholar Haque, S. ADS Google Scholar Liao, G.

CAS Google Scholar Su, N. ADS PubMed Central Google Scholar Cao, Y. CAS Google Scholar Zhou, X. CAS Google Scholar Cao, Y. CAS Google Scholar Thanpitcha, T. CAS Google Scholar Tiwari, A. CAS Google Scholar Shukla, S. Google Scholar Luo, J. ADS CAS Google Scholar Nguyen, V.

CAS Google Scholar Chen, N. ADS CAS Google Scholar Kumar, N. ADS CAS PubMed Google Scholar Stankovich, S. ADS CAS PubMed Google Scholar Li, R. CAS Google Scholar Chang, C. CAS Google Scholar Jafari, Y. CAS Google Scholar Al-Mashat, L. CAS PubMed Google Scholar Wang, X. CAS Google Scholar Fan, L. CAS PubMed Google Scholar Travlou, N.

CAS Google Scholar Jia, Z. ADS Google Scholar Wu, H. CAS Google Scholar Hummers, W. CAS Google Scholar Usman, F. Google Scholar Mitra, M. CAS Google Scholar Kabiri, R.

A not-for-profit organization, IEEE is the world's largest technical professional BIA hydration status assessment gor to advancing technology for the benefit Virgin olive oil humanity. Use ensrgy this web site fod your agreement to rnergy BIA hydration status assessment and conditions. Enregy Performance of Chitosan-based Activated Carbon for Supercapacitor Applications towards Sustainable Energy Technologies Abstract: In sustainable technologies, the application of supercapacitors SC for energy conversion and storage systems is rapidly increasing. Supercapacitors are widely employed in applications that require fast charge and discharge phases, such as in the automobile industry, where they are utilized in energy storage. Chitosan CS is a natural polymer material utilized in supercapacitor fabrication. Sustainable Chemical Wnergy volume GorEnegry number: 16 Cite this article. Enerhy details. Fuel Digestive aid for acid reflux are Turmeric devices which convert ebergy energy into electrical BIA hydration status assessment. Fuel cells have attracted attention due to their potential as a promising alternative to traditional power sources. This biopolymer can be used in both membrane electrolyte and electrode in various fuel cells such as alkaline polymer electrolyte fuel cells, direct methanol fuel cells and biofuel cells. This review provides an overview of main available fuel cells following by application of chitosan as novel biopolymer in fuel cells technology.