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Enhancing the electrochemical performance of manganese oxide thin film electrodes via borax incorporation: Experimental and theoretical insights

A. Pramitha, Shreeganesh Subraya Hegde, Badekai Ramachandra Bhat, Vikash Mishra, Y.N. Sudhakar, Sajan D. George, Y. Raviprakash

2026Journal of Power Sources7 citationsDOIOpen Access PDF

Abstract

As global energy demand continues to rise, high-performance supercapacitors emerge as a key focus due to their superior power density and rapid charge-discharge efficiency. To this end, the study explores the synthesis of Mn 3 O 4 thin film electrodes incorporated with borax via the spray pyrolysis technique. Structural characterizations reveal that the borax incorporated films preserve the tetragonal Mn 3 O 4 phase, indicating its successful integration into the Mn 3 O 4 matrix. Surface analysis reveals significant morphological changes, showing dense wrinkles and sodium agglomerations along with increased surface roughness and decreased contact angle after borax incorporation. X-ray photoelectron spectroscopy confirms boron incorporation at interstitial sites, along with oxygen imbalance and changes in the oxidation states of manganese. Electrochemical investigations demonstrate a significant improvement in the specific capacitance and charge-discharge stability of borax-incorporated Mn 3 O 4 electrodes, attributed to the enhanced conductivity and optimized electronic structure induced by boron doping. This is again reflected in impedance spectroscopy where a reduced charge transfer resistance is observed in borax-incorporated electrodes. The highest electrochemical performance is observed at an optimal B/Mn ratio of 15 at%, highlighting the potential of boron modification as a promising strategy for next-generation supercapacitors. Further, this is supported by density functional theory, which explains the observed increment in quantum capacitance value of borax incorporated Mn 3 O 4 electrodes. The predicted quantum capacitance using density functional theory agrees well with experimental results. This work not only underscores the viability of borax-incorporated Mn 3 O 4 thin films as high-performance electrode materials but also opens new avenues for further research into doped transition metal oxides for sustainable energy storage applications. • Borax incorporated Mn 3 O 4 electrodes were prepared by spray pyrolysis technique. • Boron occupied the interstitial sites causing an oxygen imbalance. • Electrode with 15 % borax showed 3-fold greater specific capacitance than pristine. • DFT predicts increased quantum capacitance, aligning well with experimental result.

Topics & Concepts

Materials scienceDielectric spectroscopyBoraxX-ray photoelectron spectroscopyCapacitanceBoronThin filmElectrodeChemical engineeringSupercapacitorElectrolyteElectrochemistryAnalytical Chemistry (journal)Density functional theoryDouble-layer capacitanceManganesePseudocapacitanceOxideSurface roughnessInorganic chemistryPower densitySpectroscopyCyclic voltammetryConductivitySupercapacitor Materials and FabricationAdvancements in Battery MaterialsAerogels and thermal insulation