Hydroxymethyl PEDOT microstructure-based electrodes for high-performance supercapacitors

Wustoni, Shofarul; Nikiforidis, Georgios; Inal, Sahika; Indartono, Yuli Setyo; Suendo, Veinardi; Yuliarto, Brian

doi:10.1063/5.0088452

Cited by 15 publications

(10 citation statements)

References 44 publications

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“…The working principle of an electrochemical double‐layer supercapacitor [48] is based on the physical adsorption of high specific surface area electrodes (in this case activated carbon with a specific surface area of 2270 cm 2 ). When charging, the electrode surface accumulates charge and attracts diffused anions and cations from the electrolyte to adsorb on the electrode surface in a directional arrangement, which forms a double electric layer structure.…”

Section: Resultsmentioning

confidence: 99%

Deep Eutectic Mn(NO₃)₂−H₂O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

2023

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Deep eutectic solvents (DESs) have proved to be an effective substitute for conventional electrolytes for energy storage applications because of their unique properties and ability to adapt them to specific applications. In this regard, this study examines an easy-to-produce, widely available and cheap manganese nitrate concentrated electrolyte that holds DES traits. The electrolyte (i. e., manganese nitrate; (Mn(NO 3 ) 2 • 6H 2 O with a weight composition of 42 %) revealed its eutectic behaviour by benchmarking the eutectic distance (53 °C), thermal expansion coefficient (3.9 × 10 À 4 K), activation energy for conductivity (~2.45 kJ mol À 1 ), and viscosity (14 kJ mol À 1 ). What's more, it was successfully incorporated into a twoelectrode symmetric supercapacitor comprising activated carbon electrodes and demonstrated specific capacitance retention of 93 % (170 F g À 1 ) through 2000 consecutive galvanostatic charge-discharge cycles at 25 and À 20 °C.

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Section: Resultsmentioning

confidence: 99%

Deep Eutectic Mn(NO₃)₂−H₂O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

2023

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“…In a symmetrical two‐electrode system, the active material weight is the same for both electrodes. The specific capacitance, C sp (F g −1 ) is related to the capacitance of the cell by [ 44 ] :

\begin{array}{*{20}{c}}{{C_{{\rm{sp}}}} = \frac{{2C}}{m}}\end{array}

where C is the capacitance of the cell, and m describes the mass of the active material.…”

Section: Resultsmentioning

confidence: 99%

“…In a symmetrical two-electrode system, the active material weight is the same for both electrodes. The specific capacitance, C sp (F g −1 ) is related to the capacitance of the cell by [44] :…”

Section: Electrolyte Salt In Acnmentioning

confidence: 99%

Comparative Internal Pressure Evolution at Interfaces of Activated Carbon for Supercapacitors Containing Electrolytes Based on Linear and Cyclic Ammonium Tetrafluoroborate Salts in Acetonitrile

Nikiforidis

Phadke

Anouti

2022

Adv Materials Inter

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EDLC), where the prevalent mechanism entails non-Faradaic charge storage at the interface between a high surface area material and a liquid electrolyte. These energy storage devices are intriguing due to their high power density (10 kW kg −1 ), rapid response time (1 s), cycle-life (10 5 cycles) and safety. [1] Nanoporous carbon materials are commonly used in EDLCs. Their porous structures act as a bulk buffering reservoir for any medium, curtailing the ion transport resistance to the interior surface of the pores. [2] Increased pore accessibility caters to a larger number of cations to populate the electrode's double layer, leading to specific capacitances of the order of 200 F g −1 , as is for the case of activated carbon. [3] The latter is widely used in these energy storage devices as it is inexpensive, i.e., the carbonization process originates from wood, coal, and nutshell and is easily prepared compared with other porous materials such as templated carbons and carbide-derived carbons. With a specific surface area of ≈2000 m 2 g −1 , it can provide ≈30 mAh g −1 V −1 counter to 150 mAh g −1 V −1 for standard battery electrodes. [4,5] Typically, the electrochemical window of EDLCs is lower than that of batteries (e.g., 4.3 V for nickel manganese oxidegraphite battery). Thus, as the energy stored is proportional to the square root of the voltage (E EDLC = ½ C × V 2 ; C denotes capacitance and V voltage), their energy density is hindered, i.e., E LIB = 3-30 × E EDLC . It should be noted that E EDLC hinges on the nature of the double layer, that is, the specific Helmholtz compact layer geometry, the size of electrolyte cations and anions, their degree of solvation, and the orientation of the electrolyte solvent dipoles in the imposed electric field. [6] Accordingly, organic electrolytes are an attractive choice as they can reach operating voltages as high as 3.5 V. Acetonitrile (ACN) is a representative dipolar aprotic solvent that boasts operating temperatures at sub-zero range (T melting ACN = −45 °C), fluidity (η = 0.345 mPa s −1 at 25 °C), a large operating voltage window (>3.0 V), [7] low internal resistance, facile ionic adsorption within the pores of carbon-based electrodes and electrochemical stability due to its low viscosity and high dielectric constant (e = 38) In this study, the real-time increase in pressure of the accumulated gases at the electrode/electrolyte interface serves as a safety criterion for four conductive electrolytes comprising acetonitrile (ACN) and organic salts. They include tetrafluoroborate as an anion and cyclic 1,1-dimethylpyrrolidinium (Pyr11 + ), spiro-(1,1′)-bipyrrolidinium (SBP + ), acyclic methyl triethyl ammonium (Et 3 MeN + ) or standard tetraethylammonium (Et 4 N + ) as cations. The main focus lies on the SPBF 4 /ACN system. While the concentrated Pyr11BF 4 /ACN exhibits a minimal pressure evolution (≈25 Pa) under ambient conditions at 3.0 V, its electrochemical stability is inferior to SPBF 4 at high operating voltage. The electrolytes with acyclic tetrafluoroborate s...

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“…40 It is important to note that these studies have determined that the decrease in the structural dimensions of the polymer is directly related to the increase in capacitive properties. 41,42 A primordial stage in the increase of the capacity of these polymers has been reported by del Valle et al, 43 who, using mesoporous silicon oxide as a template, managed to obtain thiophene nanowires on a platinum disk electrode in situ. Subsequently, they report obtaining template-free PEDOT nanowires (PEDOT-nw), which were used as a support for Pt nanoparticles for the electro-oxidation of formic acid, demonstrating high reproducibility, repeatability, and adherence of the nanowires on the electrode surface.…”

Section: Introductionmentioning

confidence: 97%

Capacitors based on PEDOT nanowire electrodeposits

Gacitúa,

del Valle,

Ramírez

2023

J of Applied Polymer Sci

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The capacitive properties of poly(3,4‐ethylenedioxythiophene) nanowires (PEDOT‐nw) obtained in situ by the electrosynthesis of EDOT in acetonitrile by cyclic voltammetry on a transparent ITO electrode that has been previously modified with a thin layer of PEDOT, on which mesoporous SiO2 is deposited. Silica acts as a template for the generation of polymer nanowires. The voltammetric profiles are consistent with a large increase in the surface area of the electrode, while their Raman spectroscopy and SEM microscopy demonstrate the formation of polymer nanostructures on the electrode surface. Also, by SEM, the presence of PEDOT deposit is verified in the form of nanowires 30 nm in diameter. On the other hand, galvanostatic measurements show a 20 times higher specific capacity for PEDOT‐nw (516.12 Fg−1) compared to PEDOT bulk (19.62 Fg−1). In the case of PEDOT‐nw, it is also worth noting a 92.3% retention capacity after 1000 successive charge/discharge cycles. Thus, it is verified that PEDOT‐nw modified electrodes are an excellent candidate to be used in polymer‐based capacitors.

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Hydroxymethyl PEDOT microstructure-based electrodes for high-performance supercapacitors

Cited by 15 publications

References 44 publications

Deep Eutectic Mn(NO₃)₂−H₂O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

Deep Eutectic Mn(NO₃)₂−H₂O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

Comparative Internal Pressure Evolution at Interfaces of Activated Carbon for Supercapacitors Containing Electrolytes Based on Linear and Cyclic Ammonium Tetrafluoroborate Salts in Acetonitrile

Capacitors based on PEDOT nanowire electrodeposits

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Hydroxymethyl PEDOT microstructure-based electrodes for high-performance supercapacitors

Cited by 15 publications

References 44 publications

Deep Eutectic Mn(NO3)2−H2O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

Deep Eutectic Mn(NO3)2−H2O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

Comparative Internal Pressure Evolution at Interfaces of Activated Carbon for Supercapacitors Containing Electrolytes Based on Linear and Cyclic Ammonium Tetrafluoroborate Salts in Acetonitrile

Capacitors based on PEDOT nanowire electrodeposits

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Product

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Deep Eutectic Mn(NO₃)₂−H₂O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications

Deep Eutectic Mn(NO₃)₂−H₂O Binary System as a Safe, Cost‐Effective, and Efficient Electrolyte for Supercapacitor Applications