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Ion transport dynamics and cation mobility in hydrothermally synthesized MXene-NiWO <sub>4</sub> composite electrodes for advanced energy storage

Sana Ullah Asif, Aqsa Nadeem, Sk. Nuslin Bibi, Muhammad Ehsan Mazhar, Abdul Shakoor, Majed M. Alghamdi, Shahid Atiq, Asma Rasheed, Adel A. El–Zahhar, Farooq Ahmad, Muhammad Ahmed Khan

2025RSC Advances5 citationsDOIOpen Access PDF

Abstract

crystal planes and the ion transport dynamics, indicating that the structural modulation directly influences cation mobility and overall charge transport. These findings demonstrate that careful tuning of the material's structure can effectively enhance ion transport in composite electrode materials.

Topics & Concepts

SupercapacitorElectrochemistryMaterials scienceEnergy storageCapacitanceElectrodeCyclic voltammetryComposite numberChronoamperometryPower densityPseudocapacitorChemical engineeringIonFaraday efficiencyNanotechnologyCurrent densityRenewable energyRedoxConductivityCrystal (programming language)OptoelectronicsCarbon fibersHydrothermal circulationEnvironmental pollutionSupercapacitor Materials and FabricationMXene and MAX Phase MaterialsAmmonia Synthesis and Nitrogen Reduction
Ion transport dynamics and cation mobility in hydrothermally synthesized MXene-NiWO <sub>4</sub> composite electrodes for advanced energy storage | Litcius