Capacitive Properties Research Articles

Electrochemical and Spectro-Microscopic Analyses of Charge Accumulation and Ion Migration in Dry Processed Perovskite Solar Cells under Electrical Biasing.

We study the influence of electrical biasing on the modification of the chemical composition and electrical performance of perovskite solar cells (PSCs) by coupling electrochemical impedance spectroscopy (EIS) and scanning transmission X-ray microscopy (STXM) techniques. EIS reveals the formation of charge accumulation at the interfaces and changes in the resistive and capacitive properties. STXM study on PSCs after applying a strong electric field for a long biasing time indicates the breakdown of methylammonium (MA+) cation, promoting iodide ions to migrate and create defects at the interface. This complementary EIS and STXM study allows the suggestion of a degradation mechanism that includes the migration of iodide ions that leads to interface defects and subsequent degradation of solar cell performance. In addition, we study the evolution of the performance of PSCs under air. We observe an increased hysteresis index on current-voltage curves and fill factor reduction of the perovskite solar cells with aging in air. EIS measurements show the formation of a capacitive layer resulting from the accumulation of iodide ions through modification of the mobile ion concentration and ion mobility.

Synergistic design and synthesis of O, N Co-doped hierarchical porous carbon for enhanced supercapacitor performance

Carbon-based supercapacitors have emerged as promising energy storage components for renewable energy applications due to the unique combination of various physicochemical characteristics in porous carbon materials (PCMs) that can improve specific capacitance (SC) properties. It is essential to develop a methodical approach that exploits the synergy of these effects in PCMs to achieve superior capacitance performance. In this study, machine learning (ML) provided a clear direction for experiments in the screening of key physicochemical features; SHapley Additive exPlanations analysis on ML indicated that specific surface area and specific doping species had a significant synergistic impact on SC enhancement. Utilizing these insights, an O, N co-doped hierarchical porous carbon (ONPC-900) was synthesized using a synergistic pyrolysis strategy through K2CO3-assisted in-situ thermal exfoliation and nanopore generation. This method leverages the role of carbon nitride (graphite-phase carbon nitride) as an in-situ layer-stacked template and the oxygen (O)-rich properties of the pre-treated lignite, enabling controlled synthesis of graphene-like folded and amorphous hybrid structures engineered for the efficient N and O doping sites and high specific surface area, resulting in an electrode material with enhanced structural adaptability, rapid charge transfer, and diffusion mass transfer capacity. Density functional theory (DFT) calculations further confirmed that pyrrole nitrogen (N-5), carboxyl (-COOH) active sites, and the defect structure formed by pores synergically enhanced the adsorption of electrolyte ions (K+) and electron transfer, improving the SC performance. The optimized ONPC-900 electrode exhibited impressive SC properties of 440 F g-1 (0.5 A g-1), outperforming most coal-based PCMs. This study provides a methodology for designing and synthesizing high SC electrode materials by optimizing the key characteristic parameters of synergism from complex structure-activity relationships through the combination of ML screening, experimental synthesis, and density functional theory validation.

W/WO3/TiO2 Multilayer Film with Elevated Electrochromic and Capacitive Properties.

Electrochromic capacitors, which are capable of altering their appearances in line with their charged states, are drawing substantial attention from both academia and industry. Tungsten oxide is usually used as an electrochromic layer material for electrochromic devices, or as an active material for high-performance capacitor electrodes. Despite this, acceptable visual aesthetics in electrochromic capacitors have almost never been achieved using tungsten oxide, because, in its pure form, this compound only displays a onefold color modulation from transparent to blue. Herein, we have designed W/WO3/TiO2 multilayer films by a magnetron sputtering device. The impact of TiO2 layer on the optical and electrochemical properties was investigated. The results show that the optimum thickness of the TiO2 layer is 10 nm. The as-prepared film displays a high coloration efficiency (CE) of 74.2 cm2 C-1, a high areal capacitance of 32.0 mF/cm2, an excellent rate performance (with the areal capacitance still retaining 87% of the maximum capacitance at a current density of 1 mA/cm2), and a high cycle life (with a capacity retention of 91% after 1000 cycles).

Bifunctional catalytic and capacitive properties of CoC and CoC/Zn derived from cobalt complex pyrolysis

Bifunctional catalytic and capacitive properties of CoC and CoC/Zn derived from cobalt complex pyrolysis

Bay-substituted perylene diimide-based donor–acceptor type copolymers: design, synthesis, optical and energy storage behaviours

Four bay-substituted perylene diimide (PDI) copolymers have been designed and synthesized successfully to demonstrate the effect of bay-substituent on the photo-physical and capacitive properties.

Study of super capacitive energy storage properties of VS2 electrode materials

Study of super capacitive energy storage properties of VS2 electrode materials

O- AND Zn-SELF-DUAL-DOPED POROUS CARBON DERIVED FROM FRUIT WASTE FOR BOOSTING SUPERCAPACITOR PERFORMANCE

Recent developments in supercapacitor devices have prompted an increasing demand for energy storage devices that operate at a micro-scale. Fabrication of such devices requires environmentally benign, compatible materials derived from waste-food industries. Therefore, this study aims to develop a carbon functional self-dual-doped from waste-food industries of mangosteen peel sources to optimize volumetric level supercapacitor. A simple integrated pyrolysis with ZnCl<sub>2</sub> assistance was applied to synthesize the self-dual-doped porous carbon. The precursor was designed as a thin-tubelike additive-free form at a constant density of 1.21 g cm<sup>-3</sup>. The optimized material (CNR-OZn-5) exhibited a unique morphology from a combination of short nanofibers and a unique reef-like architecture. Furthermore, it had a surface area of 670.569 m<sup>2</sup> g<sup>-1</sup> with O (6.00%) and Zn (0.31%) doped. In the two-configuration system, the measuring electrodes yielded capacitive properties of 261 F g<sup>-1</sup> and 315.81 F cm<sup>-3</sup> at 1 A g<sup>-1</sup>. At 10 A g<sup>-1</sup>, the coulombic efficiency and rate capability were 98% and 67.56% with an enhanced pseudo-capacitance contribution of 20.9% and low resistance of 0.05 Ω. The specific energy in the symmetrical supercapacitors system was 13.14 and 16.17 Wh L<sup>-1</sup> in 1 M H<sub>2</sub>SO<sub>4</sub> electrolyte. This new strategy, coupled with the use of waste-food-derived self-dual-doped carbon materials, holds significant potential for achieving high-level volumetric characteristics in sustainable energy storage system.

Statistical relationships between filtration and capacitance properties of reservoirs in Western Siberia based on a generalized model of capillary curves

The paper shows that the generalized mathematical model of capillary curves implicitly contains analytical connections between filtration and capacitive properties of productive layers. The method of determining the absolute permeability presented in this paper is based on the use of a generalized model. It does not require the preliminary construction of a geological model of the residual water saturation of oil and gas reservoirs. The proposed method uses correlations between current and residual water saturation at a fixed capillary pressure. The proposed statistical model makes it possible to significantly increase the reliability and accuracy of the estimation of absolute permeability according to capillarimetry data. Keywords: permeability; residual water saturation; capillary pressure; generalized model; analytical connections.

Preparation of self-supporting materials using room temperature stirring method NiMoO4@CoMoO4 research on core–shell nanocomposites and their capacitive properties

Preparation of self-supporting materials using room temperature stirring method NiMoO4@CoMoO4 research on core–shell nanocomposites and their capacitive properties

Novel Methodology of General Scaling-Approach Normalization of Impedance Parameters of Insertion Battery Electrodes – Case Study on Ni-Rich NMC Cathode: Part II. Detailed Analysis Using a Transmission Line Model

Abstract Here, we extend the general approach shown in PART-1 to a detailed analysis of the measured data using our previously published physics-based transmission line model (TLM). We construct general relationships between the TLM parameters and the electrode mass. We then systematically check the scaling properties of all model parameters by fitting the measured impedance responses of 8 NMC-NMC cells with different masses (thicknesses) of NMC cathodes ranging from 2.3 to 58.5 mg per 2 cm2 of geometric electrode surface. We consider in detail all deviations of the measured spectra from the idealized spectra predicted by the model. Among other things, we discuss the high-frequency inductive effects, the ambiguities in the analysis of the low-frequency diffusion phenomena, and the effects of non-ideal capacitive properties (the so-called constant-phase elements) on the shape of the measured spectra. We also report an unexpected additional feature observed in measurements on thin (light) electrodes: a diffusion arc due to the diffusion of lithium in the electrolyte in the micropores of the NMC aggregates in the material used. Finally, we present a detailed dependence of all model parameters on the mass (thickness) of the electrode and discuss the potential practical significance of such an analysis.

Synthesis of biochar and its metal oxide composites and application on next sustainable electrodes for energy storage devices

Biochar materials have been applied in energy storage due to their unique properties, such as high storage of ions, high conductivity, chemical stability and ease of production. Combining it with the high specific capacitance could be a promising strategy to develop devices and improve the properties. Through a hydrothermal technique the biochar powders were synthesized from sugarcane biomass. An acid pretreatment was carried out before and after the graphitization process aiming to obtain carbon materials with high surface area and porosity. The morphological characterization reveals powders with pores of submicrometer diameter. For the pure biochar it was determined a superficial area of 477.66 m2.g−1 with a median pore size of 42.92 Å and a pore volume of 0.21 cm3.g−1. A carbon-based paste was then prepared to deposit on nickel foam and obtain the electrodes. In a 3-electrode system characterization, biochar has showed higher specific capacitance than the metal oxide composites due to higher surface area and higher medium pore diameter. It was calculated a resistance of 2.7 Ω, a capacitance of 446 mF.g−1, a power density of 46.2 W.kg−1 and an energy density of 1.8 W.h.kg−1. These results indicate the potential use of biochar-based electrodes with high electrical conductivity and improved surface area to obtain higher capacitance properties for development of advanced devices.

Significantly improve capacitive properties of alicyclic polyimide dielectrics at high temperatures via hard/soft segment engineering

The demand for high energy storage density and efficiency of polymer film capacitors at high temperatures is urgently increasing in the electronics and electrical field. However, most traditional high temperature resistant polymers exhibit the low bandgap and high conductive loss because of the presence of conjugated aromatic structures, resulting in a significant decrease in the energy storage performance at high temperatures and high fields. In this paper, a series of alicyclic polyimide dielectric films containing hard segment of phenyl imide and soft segment of cyclohexyl imide are designed and prepared. On the one hand, the introduction of non-coplanar alicyclic ring into main-chain of polyimide can break long distance conjugation effect, weaken the intermolecular and intramolecular charge transfer interaction and improve the bandgap. On the other hand, the physical crossing point formed by the soft segments can sharply increase Young's modulus of the polyimide films. As a result, the terpolymer polyimide film (CPI90) with copolymerization ratio of phenyl/cyclohexyl dianhydride of 9:1 achieves a highest discharge energy density (Ud) of 5.59 J cm−3 at 150 °C. Importantly, the CPI90 film can obtain the Ud of 2.74 J cm−3 at 200 °C. In addition, the CPI90 film possesses a good self-healing ability attributing to a small ratio for the carbon to hydrogen and oxygen. This work offers a new strategy for synergistically promoting the bandgap and Young's modulus of polymer dielectrics via molecular and hard/soft segment engineering.

Enhanced electrochemical energy storage of binder-free ternary copper manganese selenide nanocomposite electrodes via polydopamine coating for quasi-solid-state hybrid supercapacitors

Owing to promising reliability, high energy storage capability, good stability, etc., nanostructured bimetallic selenides have attracted widespread interest in establishing supercapacitor devices with auspicious electrochemical properties. Focusing on this, herein, we proposed a novel polydopamine (PDA)-coated nanostructured copper manganese selenide (CuMn2Se4) on nickel foam via a hydrothermal method. The chemical composition of the cathode electrode was modified according to the chemical formula of CuxMn2-xSe4 (x = 0, 0.5, and 1) (CMS), and its effect on electrochemical properties as well as on surface morphology was investigated. The optimized CMS electrode exhibited an evenly spread petal-like lawn structure, offering rapid electron/ion kinetics, which results in improved capacitive properties. Furthermore, PDA as a redox-active neurotransmitter was evenly coated on the optimized CMS (i.e., PDA@CMS) to increase electron availability, thus enhancing energy storage capacity. The PDA@CMS electrode showed a superior specific capacitance of 3140 F g−1 at 3 A g−1 of current density. The quasi-solid-state hybrid supercapacitor was fabricated using PDA@CMS as a positive electrode and radish-derived carbon as a negative electrode with gel-type electrolyte, which delivered the power and energy densities of 7750 W kg−1 and 21.85 Wh kg−1, respectively with superior cycling stability (96.5 % capacitance retention over 10,000 cycles).

Revealing the Surface and In-Depth Operational Performances of Oxygen-Evolving Anode Coatings: A Guideline for the Synthesis of Inert Durable Anodes in Metal Electrowinning from Acid Solutions

The electrochemical performances of an oxygen-evolving anode produced by the reactivation of waste Ti substrate by a typical IrO2-Ta2O5 coating are correlated to the textural (non)uniformities of the coating and its exhaustion state. Coating degradation is considered operational loss of the activity in a metal electrowinning process. It was found that (pseudo)capacitive performances can vary over the coating surface by 20–30% and depend on the type of dynamics of the input perturbation: constant through cyclic voltammetry (CV) or discontinuous time-dependent through electrochemical impedance spectroscopy (EIS). CV-EIS data correlation enabled profiling of the capacitive properties through the depth of a coating and over its surface. The correlation was confirmed by the findings for the analysis of coating activity for an oxygen evolution reaction, finally resulting in the reliable proposition of a mechanism for the operational loss of the anode. It was found that the less compact and thicker coating parts performed better and operated more efficiently, especially at lower operational current densities.

Frequency-dependent and capacitive tissue electrical properties in spinal cord stimulation models.

Models of spinal cord stimulation (SCS) simulate the electric fields (E-fields) generated in targeted tissues, which in turn can predict physiological and then behavioral outcomes. Notwithstanding increasing sophistication and use in optimizing therapy, SCS models typically calculate E-fields using the quasi-static approximation (QSA). QSA, as implemented in neuromodulation models, neglects the frequency dispersion of tissue conductivity, as well as propagation, capacitive, and inductive effects on the E-field. The reliability of QSA specifically for SCS has not been considered in detail, especially for higher-frequency SCS. We implemented a frequency-dependent finite element method (FEM) and solved a high-resolution RADO-SCS model with voltage-controlled (VC) and current-controlled (CC) stimulation to assess the impact of frequency-dependent conductivity (dispersion) and permittivity of spinal tissues on E-fields generated at three different spinal column locations (epidural space, spinal cord, and root) for frequencies spanning from 1 Hz to 10 MHz. Results were compared with predictions of QSA method, with varied conductivity values of purely resistive tissues. We further assessed the impact of frequency-dependent and capacitive tissue properties on spinal heating and distortion of the E-field waveform. Tissue-specific electric properties around the energized leads and mode of stimulation-control impacted the magnitude of E-fields. In the spinal cord, the VC-SCS E-field generated with the frequency-dependent and capacitive properties was comparable to the QSA with 2X epidural fat conductivity, whereas the CC-SCS generated E-field was minimally impacted by frequency-dependent and capacitive properties up to 10 kHz. Spinal cord heating predicted by frequency-dependent and capacitive tissue properties was comparable to the QSA conditions with VC-SCS, whereas with CC-SCS, there was no impact of the frequency-dependent and capacitive tissue properties in spinal cord heating. E-field waveform distortion in the spinal cord, with CC-SCS at 1 kHz-specific electrical properties, was significant when fat capacitance (permittivity) was increased by 10X, whereas with VC-SCS, there was no effect of tissue capacitance. Regardless of the mode of SCS, QSA was still valid in predicting SCS-induced E-field and heating at the spinal tissues- across α and β dispersion region of spinal tissue's dielectric spectrum for VC-SCS and up to 10 kHz for CC-SCS.

Controlled Hierarchical Construction of Ultrahomogeneous Co9S8@CoAl-LDH/NF Layered Core-Shell Heterostructures for High-Performance Asymmetric Supercapacitors.

The rational collocation and construction of multiphase composite electrode materials with ingenious structures is a key strategic to enhance the electrochemical performance of supercapacitors (SCs). Within this project, a unique Co9S8@CoAl-LDH/NF core-shell heterostructure consisting of CoAl-LDH/NF ultrathin nanosheets sturdily attached to Co9S8/NF needle-like nanorods is grown in situ on self-supported conductive substrate nickel foam (NF) by an effortless and productive multistep hydrothermal method. The construction of the core-shell structure can effectively enhance the capacitive properties as well as the mechanical strength of the material. Compared with the single-component materials Co9S8/NF (1769.6 mF cm-2 and 91.6%) and CoAl-LDH/NF (858 mF cm-2 and 85.2%), the Co9S8@CoAl-LDH/NF composites have excellent capacitance properties (5052.4 mF cm-2) along with exceptional capacitance retention (5000 cycles) 98.5% even after undergoing charging and discharging. Furthermore, the asymmetric SCs fabricated with Co9S8@CoAl-LDH/NF and AC/NF exhibit an energy density of 0.17 mWh cm-2 at 3.20 mW cm-2. Therefore, the innovative core-shell heterostructure of Co9S8@CoAl-LDH/NF presented in this study holds immense practical potential as a groundbreaking electrode material in the realm of SCs.

Evaluation of the Dielectric Properties of Aluminum Conductive Polymer Solid Capacitors at High Temperatures

Aluminum capacitors have a unique combination of properties that highlight them as potential devices for power electronic applications, such as high capacitance, low cost, and high energy density. When combined with a polymeric conductive media, such as PEDOT:PSS, it outperforms traditional electrolytic capacitors in terms of thermal stability, showing a high ripple current with a low equivalent series resistance (ESR). The low breakdown voltage of commercially available devices (~100 V) has limited their applications in many fields of electronics. Nonetheless, current scientific research has found that crystalline coatings, with subsequent immersion in hot water (95 °C), are a good alternative to enhance the breakdown potential (≥ 600 V) of conductive polymer solid capacitors, especially when operated at room temperature; in addition, the leakage current can be effectively controlled through a re-anodizing procedure [1,2]. The current market needs capacitors that can reach high withstand potentials (≥ 600 V) in an operation range of up to 200 °C, and reports on solid polymer capacitor performance at high potentials and temperatures are scarce. Here, the performance at high temperatures (≤ 200 °C) of crystalline anodic coatings with subsequent hot water immersion was assessed, and the results were compared with a post-hydrated sample with a re-anodizing process at 400 V. Finally, a possible degradation mechanism at high temperatures was explored.The dielectric material was formed as follows. First, an electropolished high-purity aluminum sheet was immersed in hot water (95 °C) for 10 min to form a pseudo-boehmite layer. The anodization was conducted at 700 V in H3BO3 solution at 85 °C for 10 min, followed by immersion in hot water at 95 °C for 10 min. To control the dielectric defects, a re-anodizing process at 400 V was performed at 85 °C for 10 min in H3BO3 solution. The PEDOT:PSS conductive polymer was coated on the dielectric material using an aqueous dispersion solution of ~1% concentration. The dielectric properties were assessed by AC impedance spectroscopy and voltage sweeping in a model flat aluminum capacitor with a PEDOT:PSS conductive polymer as the cathode at high temperatures (≤ 200 °C).The thermal stability analysis evidenced that the aluminum capacitor with a subsequent immersion in hot water assessed with a PEDOT:PSS conductive polymer remained dielectrically invariable up to 100 ˚C, with a breakdown potential of ~790 V. Nonetheless, the breakdown potential was reduced when the temperature was increased to 200 °C with an average value of ~473 V. Analogous behavior was observed in the aluminum capacitor with re-anodization at 400 V, where the breakdown potential remained constant with a value of ~ 670 V up to 100 °C; however, an increase in the temperature to 200 °C reduced its value until ~550 V. Hence, thermal analysis revealed that the post-anodizing treatments aimed at enhancing the breakdown potential (˃600 V) of crystalline coatings at ambient temperature [2] fail to sustain the withstand voltage above 600 V as the temperature increases to a maximum value of 200°C. Furthermore, an in-parallel examination in which the dielectric layer without the PEDOT:PSS coating was heated to 200 °C showed that thermal degradation mostly affects the dielectric layer.Surface and cross-sectional analyses by SEM showed that a crucial aspect of the breakdown potential enhancement is on the PEDOT:PPS-dielectric layer interface. The formation of a nanovoid layer by immersion in hot water avoids the local current concentration at high voltages and modifies the electrical resistance in the PEDOT:PSS-dielectric material interface. SEM cross-sectional observations of the dielectric layer at high temperatures (≤ 200 °C) show that the nanovoid layer remains visible; nevertheless, a porosity analysis by pore-filling reveals that the porosity in the nanovoid layer increases with temperature, modifying the PEDOT:PSS-dielectric layer interaction. Although the reason for the low breakdown potential in solid polymer capacitors is still unclear, from the light of the present results, the PEDOT: PSS-dielectric layer interaction is shown to be an important factor.This work was supported by the MEXT-Program for Creation of Innovative Core Technology for Power Electronics Grant Number JPJ009777.

Nickel foam supported CuO/Co3O4/r-GO is used as electrode material for non-enzymatic glucose sensors and high performance supercapacitors

In order to solve the problem of glucose detection in medical development and meet the urgent demand for new energy storage devices, this paper proposes a new material suitable for glucose sensing and capacitive properties. The sensor was fabricated by depositing Co3O4 nanoparticles onto nickel foam with integrated r-GO via the hydrothermal method, followed by the synthesis of CuO nanoparticles using electroplating. The detection range of the sensor is 0.3–11.3 mM. The sensor's sensitivity is 1000.3 μA mM−1 cm−2, indicating its responsiveness to changes in analyte concentration. In electrochemical test systems, Signal-to-Noise Ratio (SNR) usually represents the relative intensity of the effective current signal and the background noise, reflecting the accuracy and reliability of the measurement. When the SNR is three, the minimum detection limit is 0.431 μM, highlighting its ability to reliably detect analytes at low concentrations amidst background noise. According to electrochemical workstation tests, the sensor demonstrates robust stability. Furthermore, the electrode material proves suitable for asymmetric supercapacitor devices, when the current density is 2 Ag−1, the specific capacitance is 660.5 Fg−1. At the same time, we also explore the cyclic stability of the device, which can retain 92.3 % of its initial specific capacitance after 5000 cycles, showing its remarkable long-term stability. In addition, the prepared nanocomposites can also light the red LED light. The results show that the synthesized CuO/Co3O4/r-GO/NF electrode can be used for electrochemical glucose sensing and supercapacitors, and plays an important role as a multi-functional material in the fields of medical, food, electronics, transportation and energy, providing key technical support for a variety of applications.

Effect of EDOT contribution on the electrochromic and capacitive properties of edot-carbazole based electrochromic polymer: Electrochromic and supercapacitor device applications

3,4-ethylenedioxythiophene (EDOT) based donor-acceptor-donor (DAD) type conjugated polymers generally have extraordinary electrochromic properties due to the excellent nature of the EDOT unit. This work investigates the electrochromic properties of such a system; EDOT-Carbazole-EDOT (ECE) based DAD type of conjugated polymer. Electrochemically synthesized homopolymer film (PECE) showed multichromic behavior with excellent optical properties such as 34 % of optical contrast, subsecond switching response (0.96 s at 478 nm), high coloration efficiency (519 cm2/C at 478 nm) and remarkable specific capacitance (3.04 F/cm2). Inserting more EDOT units into the polymer matrix of PECE via electrochemical synthesis altered the spectral and capacitive behaviors of the resulting copolymers. 2:1 (ECE:EDOT) feeded copolymer exhibited better electrochromic performance than equal feeded copolymer. On the other hand, the capacitive range and capacitance stability were significantly enhanced as the EDOT unit increased in the copolymer matrix.PECE and its copolymers were used to construct dual-type electrochromic devices with poly(3, 4-ethylenedioxythiophene) (PEDOT). ECDs of PECE and copolymers exhibited superior stability upon many switchings, with subsecond switching responses. Furthermore, ECDs can be switched effectively even at the scan rate of 500 mV/s without any loss in charge/discharge amounts. Finally, electrochromic supercapacitor device applications were performed, and a 1.5 V-LED was lighted for up to 25 s with the copolymer supercapacitor device.

Progress in MOFs and MOFs-Integrated MXenes as Electrode Modifiers for Energy Storage and Electrochemical Sensing Applications.

The global energy demand and environmental pollution are the two major challenges of the present scenario. Recently, researchers focused on the preparation and investigation of catalysts for their capacitive properties for energy storage devices. Thus, supercapacitors have received extensive interest from researchers due to their promising energy storage features and decent cyclic stability/performance. The performance of the supercapacitors are significantly influenced by the physicochemical properties of the electrocatalyst. In this review article, we have compiled the previous reports on the fabrication of MOFs-based composite materials with MXenes for energy storage and electrochemical sensing applications. The metallic and bimetallic MOFs and MOFs/MXenes materials for supercapacitor applications are reviewed. In addition, MOFs/MXenes-based hybrid composites are also compiled towards the determination of various toxic/hazardous materials, such as metal ions like copper ions, mercury ions, and picric acid. We believe that present review article may benefit the researchers working on the preparation of MOFs-based catalysts for supercapacitor and electrochemical sensing applications.