25 research outputs found
Melamine formaldehyde-metal organic gel interpenetrating polymer network derived intrinsic Fe-N-doped porous graphitic carbon electrocatalysts for oxygen reduction reaction
Fe, N doped porous graphitic carbon electrocatalyst (Fe-MOG-MF-C), obtained by pyrolysis of an Interpenetrating Polymer Network (IPN) comprised of melamine formaldehyde (MF as hard segment) and Metal-Organic Gel (MOG as soft segment), exhibited significant Oxygen Reduction Reaction (ORR) activity in alkaline medium. BET surface area analysis of Fe-MOG-MF-C showed high surface area (821 m2 g-1), while TEM, Raman and XPS results confirmed Fe and N co-doping. Furthermore, a modulated porous morphology with a higher degree of surface area (950 m2 g-1) has been accomplished for the system (Fe-MOG-MFN-C) when aided by a sublimable porogen, such as naphthalene. XPS results further demonstrated that these systems exhibited a better degree of distribution of graphitic N and an onset potential value of 0.91 V vs. RHE in 0.1 M KOH solution following an efficient four-electron ORR pathway. The electrocatalytic activity of Fe-MOG-MFN-C is superior to that of Fe-MOG-MF-C by virtue of its higher graphitic N content and surface area. Thus, the study presents a new class of IPN derived MF-MOG nanocomposites with the potential to generate extended versions of in situ Fe-N doped porous graphitic carbon structures with superior ORR activity
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Interlayer hydrogen-bonded covalent organic frameworks as high-performance supercapacitors
Covalent organic frameworks (COFs) have emerged as promising electrode materials in supercapacitors (SCs). However, their insoluble powder like nature, poor capacitive performance in pristine form, integrated with inferior electrochemical stability is a primary concern for their long-term use in electrochemical-devices. Keeping this in perspective, herein, we report a redox active and hydrogen bonded COF with ultrahigh stability in conc. H2SO4 (18 M), conc. HCl (12 M) and NaOH (9 M). The as-synthesized COF fabricated as thin sheets were efficiently employed as a free-standing supercapacitor electrode material using 3 M aq. H2SO4 as an electrolyte. Moreover, the pristine COF sheet showcased outstanding areal capacitance 1600 mFcm-2 (gravimetric 169 Fg-1) and excellent cyclic stability (> 1,00,000) without compromising its capacitive performance or coulombic efficiency. Moreover, as a proof-of-concept, a solidstate supercapacitor device was also assembled and subsequently tested
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Weak intermolecular interactions in covalent organic framework-carbon nanofiber based crystalline, yet flexible devices
The redox-active and porous structural backbone of covalent organic frameworks (COFs) can facilitate high-performance electrochemical energy storage devices. However, the utilities of such 2D-materials as supercapacitor electrodes in advanced self power-pack systems have been obstructed due to the poor electrical conductivity and subsequent indigent performance. Herein, we report an effective strategy to enhance the electrical conductivity of COF thin sheets through the in situ solid-state inclusion of carbon nanofiber (CNF) into the COF precursor matrix. The obtained COF-CNF hybrids possess a significant intermolecular π•••π interaction between COF and the graphene layers of the CNF. As a result, these COF-CNF hybrids (DqTp-CNF and DqDaTp-CNF) exhibit good electrical conductivity (0.25×10-3 Scm-1), as well as high performance in electrochemical energy storage (DqTp-CNF: 464 mFcm-2at 0.25 mAcm-2). Also, the fabricated, mechanically strong quasi-solid-state supercapacitor (DqDaTp-CNF SC) delivered an ultra-high device capacitance of 167 mFcm-2 at 0.5 mAcm-2. Furthermore, we integrated a monolithic photovoltaic self-charging power-pack by assembling DqDaTp-CNF SC with a perovskite solar cell. The fabricated self power-pack delivered excellent performance in the areal capacitance (42 mFcm-2) at 0.25 mAcm-2 after photo charging for 300 seconds
Bio-inspired catalyst compositions for enhanced oxygen reduction using nanostructured Pt electrocatalysts in polymer electrolyte fuel cells
Composites of Nafion with a class of bio-molecules viz., plant hormones, are explored as potential polymer electrolytes for improving the proton transport inside the catalyst layer of a H2/O2 fuel cell. Specifically, four nitrogenous plant hormones, two each from the class of auxins and cytokinins have been investigated, following preliminary characterization of the composite dispersions and membranes. Interestingly, the use of indole-3-acetic acid (an auxin) in the catalyst layer reveals a 30% enhancement in Pt catalyst utilization and improved fuel cell performance by 150 mW /cm2. The effect of these
bio-molecules on the kinetic and mass transport parameters has been analyzed systematically using a combination of electrochemical and spectroscopic techniques
Strategic Preparation of Efficient and Durable NiCo Alloy Supported N-Doped Porous Graphene as an Oxygen Evolution Electrocatalyst: A Theoretical and Experimental Investigation
Development of an efficient and durable water splitting electrocatalyst holds a great commitment for the future energy devices. The real application of oxygen evolution reaction (OER) catalysts mainly suffers from sluggish kinetics and high overpotential except for the Ir and Ru-based systems. However, the high cost and vulnerability of the Ir and Ru metals are the main hostiles to use them for marketization. Herein, a high-performance OER electrocatalyst consisting of NiCo alloy nanoparticles supported on high surface area N-doped porous graphene (NiCo/pNGr(75: 25)) is reported. The importance of the doped-N for achieving the uniform dispersion-cum-effective interaction of the size controlled NiCo alloy nanoparticles has been explicitly investigated by transmission electron microscopy, X-ray diffraction, X-ray photo electron spectroscopy, Raman, density functional theory (DFT) calculations, etc. The electrochemical analysis of NiCo/pNGr(75: 25) shows an overpotential of approximate to 260 mV at 10 mA cm(-2) with a smaller Tafel slope of approximate to 87 mV dec(-1) and long catalytic durability. DFT calculations are done to check the interaction between the NiCo alloy nanoparticles and the defective sites of pNGr and also with the doped-N, which could be attained for maintaining long catalytic durability. Furthermore, NiCo/pNGr(75: 25) is used as an OER catalyst to fabricate an electrolyzer, which works at very low potential of 1.5 V in 1 M KOH
Naphthalene Diimide Copolymers by Direct Arylation Polycondensation as Highly Stable Supercapacitor Electrode Materials
Conjugated donor–acceptor
copolymers based on naphthalene
diimide (NDI) as acceptor and thiophene-terminated oligophenylenevinylene
as donor moieties (P<sub>1</sub> and P<sub>2</sub>, respectively)
were synthesized using the direct (hetero) arylation (DHAP) polymerization
route. Nitrile groups were introduced at the vinylene linkage in one
copolymer (P<sub>2</sub>) to fine-tune its electrochemical properties.
Both polymers show π–π* transition in the 300–480
nm region and intramolecular charge transfer (ICT) from thiophene
to NDI in the 500–800 nm region in the absorption spectra.
P<sub>2</sub> exhibits a blue-shifted intramolecular charge transfer
(ICT) band in the absorption spectrum as well as a lower reduction
potential in the cyclic voltammogram compared to the analogous polymer
without the nitrile substitution (P<sub>1</sub>). The two polymers
were evaluated as type III supercapacitor materials by preparing composite
electrodes with carbon nanotubes (CNTs) and employing 0.5 M H<sub>2</sub>SO<sub>4</sub> as the electrolyte. Their performance was compared
with that of P(NDI2OD-T2) as a reference polymer. The polymer P<sub>2</sub> based supercapacitor exhibits a specific capacitance of 124
F/g with excellent stability up to 5000 cycles with almost 100% retention
of the initial capacitance in the potential window of −0.7
to 0.5 V. Compared to P<sub>2</sub>, P<sub>1</sub> exhibits a specific
capacitance of 84 F/g, while the corresponding value for the reference
polymer P(NDI2OD-T2) is 61 F/g under identical conditions
Naphthalene Diimide Copolymers by Direct Arylation Polycondensation as Highly Stable Supercapacitor Electrode Materials
Conjugated donor–acceptor
copolymers based on naphthalene
diimide (NDI) as acceptor and thiophene-terminated oligophenylenevinylene
as donor moieties (P<sub>1</sub> and P<sub>2</sub>, respectively)
were synthesized using the direct (hetero) arylation (DHAP) polymerization
route. Nitrile groups were introduced at the vinylene linkage in one
copolymer (P<sub>2</sub>) to fine-tune its electrochemical properties.
Both polymers show π–π* transition in the 300–480
nm region and intramolecular charge transfer (ICT) from thiophene
to NDI in the 500–800 nm region in the absorption spectra.
P<sub>2</sub> exhibits a blue-shifted intramolecular charge transfer
(ICT) band in the absorption spectrum as well as a lower reduction
potential in the cyclic voltammogram compared to the analogous polymer
without the nitrile substitution (P<sub>1</sub>). The two polymers
were evaluated as type III supercapacitor materials by preparing composite
electrodes with carbon nanotubes (CNTs) and employing 0.5 M H<sub>2</sub>SO<sub>4</sub> as the electrolyte. Their performance was compared
with that of P(NDI2OD-T2) as a reference polymer. The polymer P<sub>2</sub> based supercapacitor exhibits a specific capacitance of 124
F/g with excellent stability up to 5000 cycles with almost 100% retention
of the initial capacitance in the potential window of −0.7
to 0.5 V. Compared to P<sub>2</sub>, P<sub>1</sub> exhibits a specific
capacitance of 84 F/g, while the corresponding value for the reference
polymer P(NDI2OD-T2) is 61 F/g under identical conditions
Morphological Ensembles of N-Doped Porous Carbon Derived from ZIF-8/Fe-Graphene Nanocomposites: Processing and Electrocatalytic Studies
© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim Engineering the active site density of porous carbon catalysts for enhanced electrocatalytic activity is the current focus in the quest for economically viable fuel cells. Herein, we synthesise ZIF-8/Fe-graphene composites for the formation of N and Fe co-doped carbon with diverse morphologies ranging from tubes and sheets to frameworks of carbon. A synthetic strategy involving the one pot synthesis of ZIF-8 based composites is accomplished by the reaction of 2-methylimidazole with mixed Zn/Fe salt solution containing graphene dispersions. The high temperature heat treatment of this precursor mix yielded micro-meso porous architectures of N, Fe co-doped carbon with dispersions of Fe/Fe3C. An onset potential value of 0.95 V and a half-wave potential of 0.82 V coupled with excellent durability and stability in alkaline medium indicated improved electrocatalytic performances over its commercial Pt/C counterpart. The appreciable electrocatalytic properties of the synthesized carbon are attributed to its morphological diversity, hybrid structure, high N doping and its heteroporous characteristics. The dispersed Fe/Fe3C and FeNx sites facilitated enhanced oxygen adsorption and the graphene inclusions in the composite provided retention of high nitrogen contents
Graphene Oxide Sheathed ZIF-8 Microcrystals: Engineered Precursors of Nitrogen-Doped Porous Carbon for Efficient Oxygen Reduction Reaction (ORR) Electrocatalysis
© 2016 American Chemical Society.Nitrogen containing mesoporous carbon obtained by the pyrolysis of graphene oxide (GO) wrapped ZIF-8 (Zeolitic Imidazolate Frameworks-8) micro crystals is demonstrated to be an efficient catalyst for the oxygen reduction reaction (ORR). ZIF-8 synthesis in the presence of GO sheets helped to realize layers of graphene oxide over ZIF-8 microcrystals and the sphere-like structures thus obtained, on heat treatment, transformed to highly porous carbon with a nitrogen content of about 6.12% and surface area of 502 m2/g. These catalysts with a typical micromeso porous architecture exhibited an onset potential of 0.88Vvs RHE in a four electron pathway and also demonstrated superior durability in alkaline medium compared to that of the commercial Pt/C catalyst. The N-doped porous carbon derived from GO sheathed ZIF-8 core-shell structures could therefore be employed as an efficient electrocatalyst for fuel cell applications