Supercapacitor Degradation: Understanding Mechanisms of Cycling‐Induced Deterioration and Failure of a Pseudocapacitor

Mazloomian, Katrina; Lancaster, Holli; Howard, Christopher A.; Shearing, Paul R.; Miller, Thomas S.

doi:10.1002/batt.202300214

Cited by 10 publications

(3 citation statements)

References 62 publications

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“…Aggregation, volume expansion of the electrode material during repeated charge-discharge operations, and degradation of redox-active materials are some of the causes of the low retention rate. Furthermore, the surface Mn-ion reduction has been connected to a two-step oxidation-reduction mechanism including OH oxidation in the electrolyte [71,72]. A material with low retention may deteriorate more quickly, reducing its commercial viability and necessitating frequent replacements or maintenance.…”

Section: Electrochemical Impedance Spectroscopy (Eis)mentioning

confidence: 99%

Effect of graphite concentration on the electrochemical performance of a novel α-MnO₂-expanded graphite-PVDF composite cathode material based on FTO substrate

Philip,

Ruban Kumar

2024

Phys. Scr.

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A facile chemical reduction method is employed for the synthesis of α-MnO2 followed by ultrasonication with synthetic graphite and poly (vinylidene pyrrolidone) PVDF for the development of α-MnO2-expanded graphite-PVDF (MGP) composite. Known masses of MGP composite are drop-casted on a fluorine-doped tin oxide (FTO) conducting glass substrate for the fabrication of composite electrodes to use as the cathode. The compositional effects of various weight percentages of graphite on the electrochemical performance of the MGP composite are studied. The increase in graphite’s weight percentage is always accompanied by an equal reduction in the weight of MnO2 by maintaining a constant amount of PVDF. We demonstrate a maximum electrochemical performance for the composite containing 80% MnO2, 10% expanded graphite, and 10% PVDF, further increases in graphite concentration (reduction in that of MnO2) have detrimental effects on the performance. The basis characterisation of the composite is carried out using XRD, FTIR, UV-VIS, AFM, and SEM and the electrochemical studies are done using CV, GCD and EIS. We observe both faradaic and non-faradaic charge storage mechanisms in the composite samples with a 35% capacitive contribution and a 65% diffusive contribution to the total capacitance. Moreover, the composite electrode demonstrates a maximum specific capacitance of 358 F/g at 10 mV/s with an outstanding power density of 2.8 KW/Kg.

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Section: Electrochemical Impedance Spectroscopy (Eis)mentioning

confidence: 99%

Effect of graphite concentration on the electrochemical performance of a novel α-MnO₂-expanded graphite-PVDF composite cathode material based on FTO substrate

Philip,

Ruban Kumar

2024

Phys. Scr.

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“…have been widely used in various electronic devices. However, they suffer from significant performance degradation over time and device failure in harsh environments. − Therefore, it is greatly required that these materials be processed to work efficiently under broader environmental conditions.…”

Section: Introductionmentioning

confidence: 99%

Applicability of the MoS₂–aSiC Heterostructure for Durable Supercapacitance and NO₂ Gas Sensing in a Harsh Environment

Rahman,

Sharma,

Singh

et al. 2024

ACS Appl. Electron. Mater.

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In the present work, the heterostructure of molybdenum disulfide (MoS 2 ) with amorphous silicon carbide (aSiC) on stainless steel (SS) and Si substrates was fabricated by using a DC magnetron sputtering system. This unique heterostructure was examined for energy storage and NO 2 gas-sensing applications suitable for harsh environmental conditions. The two-dimensional (2D) MoS 2 nanostructured with dissolution resistive aSiC supercapacitor electrode delivers 1.5-fold enhancement in the gravimetric capacitance, a voltage window enlargement from 0.8 to 1.8 V, and an excellent stability of more than 4000 charge−discharge cycles. Further, the high-concentration NO 2 gas-sensing performance of the MoS 2 −aSiC heterostructure on the Si substrate revealed a stable and recoverable response at high operating temperatures. Therefore, loading aSiC with 2D MoS 2 enables a durable electrode material for energy storage and NO 2 gas-sensing applications in adverse conditions. The as-fabricated heterostructure was systematically studied by various material and electrochemical characterizations.

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“…There are several critical differences between pseudocapacitors and other supercapacitors. Pseudocapacitors rely on faradaic reactions, while other supercapacitors, such as electrostatic double-layer capacitors, primarily depend on the physical separation of charges at the electrodeelectrolyte interface (Mazloomian et al, 2023). Pseudocapacitors provide increased energy storage capabilities owing to the faradaic reactions involved.…”

Section: Introductionmentioning

confidence: 99%

MnO2/PANI/SWCNT Nanokompozit Süperkapasitör Elektrot Geliştirilmesi ve Elektrokimyasal Performansının İncelenmesi

ÖZADA,

ÜNAL,

ÖZER

et al. 2023

UUJFE

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In this study, a manganese dioxide (MnO2/polyaniline (PANI)/ single-walled carbon nanotube (SWCNT) nanocomposite electrode was prepared for pseudo-supercapacitors. To reduce the internal resistance of the electrode, increase the capacitance stability, and reduce the cost of single-walled carbon nanotubes, SWCNT was subjected to two-step acid etching. The purity of SWCNT was improved from ~95% to 99.98%. In addition, SWCNT was functionalized by this process. Thus, a nanocomposite was formed by coating PANI around SWCNT. MnO2/PANI/SWCNT were synthesized using the hydrothermal method. Morphological, chemical and thermal analyses of the synthesized nanocomposite structure were carried out. In addition, X-ray diffraction (XRD) was used to determine the crystal structure. Electrochemical analyses were performed using a three-electrode system in a 1 M KOH electrolyte solution. Cyclic voltammetry (CV) and galvanostatic charge-discharge (GCD) measurements were performed. The capacitance of the nanocomposite electrode at 400 cycles was 314 mF/cm2, and the capacitance retention stability was calculated at 73.24%. The results showed that the capacitance stability was high, and the supercapacitor was sensitive to redox reactions.

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Supercapacitor Degradation: Understanding Mechanisms of Cycling‐Induced Deterioration and Failure of a Pseudocapacitor

Cited by 10 publications

References 62 publications

Effect of graphite concentration on the electrochemical performance of a novel α-MnO₂-expanded graphite-PVDF composite cathode material based on FTO substrate

Effect of graphite concentration on the electrochemical performance of a novel α-MnO₂-expanded graphite-PVDF composite cathode material based on FTO substrate

Applicability of the MoS₂–aSiC Heterostructure for Durable Supercapacitance and NO₂ Gas Sensing in a Harsh Environment

MnO2/PANI/SWCNT Nanokompozit Süperkapasitör Elektrot Geliştirilmesi ve Elektrokimyasal Performansının İncelenmesi

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Supercapacitor Degradation: Understanding Mechanisms of Cycling‐Induced Deterioration and Failure of a Pseudocapacitor

Cited by 10 publications

References 62 publications

Effect of graphite concentration on the electrochemical performance of a novel α-MnO2-expanded graphite-PVDF composite cathode material based on FTO substrate

Effect of graphite concentration on the electrochemical performance of a novel α-MnO2-expanded graphite-PVDF composite cathode material based on FTO substrate

Applicability of the MoS2–aSiC Heterostructure for Durable Supercapacitance and NO2 Gas Sensing in a Harsh Environment

MnO2/PANI/SWCNT Nanokompozit Süperkapasitör Elektrot Geliştirilmesi ve Elektrokimyasal Performansının İncelenmesi

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Effect of graphite concentration on the electrochemical performance of a novel α-MnO₂-expanded graphite-PVDF composite cathode material based on FTO substrate

Effect of graphite concentration on the electrochemical performance of a novel α-MnO₂-expanded graphite-PVDF composite cathode material based on FTO substrate

Applicability of the MoS₂–aSiC Heterostructure for Durable Supercapacitance and NO₂ Gas Sensing in a Harsh Environment