Inkjet printed doped polyaniline: Navigating through physics and chemistry for the next generation devices

Bocchini, Sergio; Castellino, Micaela; Pina, Cristina Della; Rajan, Krishna; Falletta, Ermelinda; Chiolerio, Alessandro

doi:10.1016/j.apsusc.2018.06.003

Cited by 17 publications

(15 citation statements)

References 35 publications

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“…The weight percentage of doped metal and the atomic ratio of metal to coordinated nitrogen were quantified and listed in Table 1. It is confirmed that the chemical composition of the synthesized EB-PANI is in accordance with the reported molecular structure [27,28], alongside slight oxidation and residual chlorine content from the polymerization process.…”

Section: Physical and Chemical Properties Of The Samplessupporting

confidence: 83%

“…It is believed that the fluorinated groups of the ionomer could increase the hydrophobicity of the electrode and promote the selectivity toward the reduction of CO 2 rather than protons [41]. However, the terminal chain sulfonic groups in Nafion lead to an increase in the overall surface polarity [27], resulting in the enhancement in the HER. The co-presence of Nafion and CB further enhances the HER activity, while CB alone does not add any significant beneficial effect for the CO 2 RR (Fig.…”

Section: Investigation Of the Electrode Compositionmentioning

confidence: 99%

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Polymer-metal complexes as emerging catalysts for electrochemical reduction of carbon dioxide

et al. 2021

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A class of metal-doped polyanilines (PANIs) was synthesized and investigated as electrocatalysts for the carbon dioxide reduction reaction (CO2RR). These materials show good affinity for the electrode substrate and allow to obtain stable binder-free electrodes, avoiding the utilization of expensive ionomer and additives. The emeraldine-base polyaniline (EB-PANI), in absence of metal dopant, shows negligible electrocatalytic activity and selectivity toward the CO2RR. Such behavior significantly improves once EB-PANI is doped with an appropriate cationic metal (Mn, Cu or Sn). In particular, the Sn-PANI outperforms other metal-doped samples, showing a good turnover frequency of 72.2 h−1 for the CO2RR at − 0.99 V vs the reversible hydrogen electrode and thus satisfactory activity of metal single atoms. Moreover, the Sn-PANI also displays impressive stability with a 100% retention of the CO2RR selectivity and an enhanced current density of 4.0 mA cm−2 in a 10-h test. PANI, a relatively low-cost substrate, demonstrates to be easily complexed with different metal cations and thus shows high tailorability. Complexing metal with conductive polymer represents an emerging strategy to realize active and stable metal single-atom catalysts, allowing efficient utilization of metals, especially the raw and precious ones. Graphic abstract

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Section: Physical and Chemical Properties Of The Samplessupporting

confidence: 83%

Section: Investigation Of the Electrode Compositionmentioning

confidence: 99%

Polymer-metal complexes as emerging catalysts for electrochemical reduction of carbon dioxide

et al. 2021

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“…Moreover, it should be emphasized that the VB edge is far below the Fermi level in the ACC substrate, but the growth of PAni increases the density of states near the Fermi energy to delineate a small shoulder at ~4 eV. A similar VB pattern has been reported earlier for PAni films, although the relative peak intensity and resolution of the various peaks is highly dependent on the particular intrinsic redox state, the doping and protonation levels, and the nature of the dopant ion [46,47,48]. Nakajima et al [46] reported a set of peaks in the region 10–20 eV (17.5 eV, 14 eV and 11.5 eV) due to an overlap of molecular orbitals involving benzenoid C and N in leucoemeraldine salt, while the electron density close to the Fermi level was found to be characteristic of a conjugated structure of double and single bonds.…”

Section: Resultssupporting

confidence: 66%

“…Nakajima et al [46] reported a set of peaks in the region 10–20 eV (17.5 eV, 14 eV and 11.5 eV) due to an overlap of molecular orbitals involving benzenoid C and N in leucoemeraldine salt, while the electron density close to the Fermi level was found to be characteristic of a conjugated structure of double and single bonds. More recently, Bocchini et al [48] distinguished a C2s peak at 13 eV, a 9–11 eV feature corresponding to a C–N 2p-σ state, and a group of weak photoemission peaks below 8 eV assigned to C2p-σ and C2p-π bands in polyemeraldine doped with camphorsulphonic or aminosulphonic acids. Hybrid PAni-ACC composites formed at intermediate electropolymerization times (Figure 6b) show mixed features from both the underlying carbon matrix and a polymer thin film.…”

Section: Resultsmentioning

confidence: 99%

Enhanced Adsorptive Properties and Pseudocapacitance of Flexible Polyaniline-Activated Carbon Cloth Composites Synthesized Electrochemically in a Filter-Press Cell

et al. 2019

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Electrochemical polymerization is known to be a suitable route to obtain conducting polymer-carbon composites uniformly covering the carbon support. In this work, we report the application of a filter-press electrochemical cell to polymerize polyaniline (PAni) on the surface of large-sized activated carbon cloth (ACC) by simple galvanostatic electropolymerization of an aniline-containing H2SO4 electrolyte. Flexible composites with different PAni loadings were synthesized by controlling the treatment time and characterized by means of Scanning Electron microscopy (SEM), X-Ray Photoelectron Spectroscopy (XPS), physical adsorption of gases, thermogravimetric analysis (TGA), cyclic voltammetry and direct current (DC) conductivity measurements. PAni grows first as a thin film mostly deposited inside ACC micro- and mesoporosity. At prolonged electropolymerization time, the amount of deposited PAni rises sharply to form a brittle and porous, thick coating of nanofibrous or nanowire-shaped structures. Composites with low-loading PAni thin films show enhanced specific capacitance, lower sheet resistance and faster adsorption kinetics of Acid Red 27. Instead, thick nanofibrous coatings have a deleterious effect, which is attributed to a dramatic decrease in the specific surface area caused by strong pore blockage and to the occurrence of contact electrical resistance. Our results demonstrate that mass-production restrictions often claimed for electropolymerization can be easily overcome.

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“…The world produces more than 50 million tons of e‐waste each year, worth over $62.5 billion, among which only 20% of this is formally recycled . However, we cannot stay away from this faster digitalization where tremendous advancement in wearables and portable smart electronics imposes low‐cost, wireless, and light energy sources that must include green and sustainable materials/technologies to become effective in reducing e‐waste. When it comes to portability, cost effectiveness and green technology altogether, the contribution of energy harvesters which convert the wasted energy from ambient environment or human body motion into electrical energy for diverse applications is an absolute accomplisher …”

Section: Introductionmentioning

confidence: 99%

Touch‐Interactive Flexible Sustainable Energy Harvester and Self‐Powered Smart Card

Ferreira

Goswami

Nandy

et al. 2019

Adv Funct Materials

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Sustainable and safe energy sources combined with cost effectiveness are major goals for society when considering the current scenario of mass production of portable and Internet of Things (IoT) devices along with the huge amount of inevitable e-waste. The conceptual design of a selfpowered "eco-energy" smart card based on paper promotes green and clean energy, which will bring the zero e-waste challenge one step closer to fruition. A commercial raw filter paper is modified through a fast in situ functionalization method, resulting in a conductive cellulose fiber/polyaniline composite, which is then applied as an energy harvester based on a mechano-responsive charge transfer mechanism through a metal/conducting polymer interface. Different electrodes are studied to optimize charge transfer based on contact energy level differences. The highest power density and current density obtained from such a paper-based "eco-energy" smart card device are 1.75 W m −2 and 33.5 mA m −2 respectively. This self-powered smart energy card is also able to light up several commercial light-emitting diodes, power on electronic devices, and charge capacitors.

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Inkjet printed doped polyaniline: Navigating through physics and chemistry for the next generation devices

Cited by 17 publications

References 35 publications

Polymer-metal complexes as emerging catalysts for electrochemical reduction of carbon dioxide

Polymer-metal complexes as emerging catalysts for electrochemical reduction of carbon dioxide

Enhanced Adsorptive Properties and Pseudocapacitance of Flexible Polyaniline-Activated Carbon Cloth Composites Synthesized Electrochemically in a Filter-Press Cell

Touch‐Interactive Flexible Sustainable Energy Harvester and Self‐Powered Smart Card

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