Litcius/Paper detail

Hierarchical Mn<sub>3</sub>O<sub>4</sub>/NiSe<sub>2</sub>–MnSe<sub>2</sub>: A Versatile Electrode Material for High-Performance All-Solid-State Hybrid Pseudocapacitors with Supreme Working Durability

Siddhant Srivastav, Shilpa Singh, Sumanta Kumar Meher

2023Langmuir17 citationsDOI

Abstract

As highly efficient electrochemical energy storage devices are in indispensable demand for numerous modern-day technologies, herein sluggish precipitation followed by an anion exchange procedure has been developed to synthesize an oxide-selenide mixed phase (Mn 3 O 4 /NiSe 2 –MnSe 2 ) novel electrode material with high surface area and porosity for high-performance all-solid-state hybrid pseudocapacitors (ASSHPC). Mn 3 O 4 /NiSe 2 –MnSe 2 shows a rich Tyndall effect (in H 2 O) and possesses randomly arranged low-dimensional crystallites of nearly similar size and uniform shape. The electrochemical analyses of Mn 3 O 4 /NiSe 2 –MnSe 2 corroborate good electrochemical reversibility during charge transfer, superior pseudocapacitive charge-storage efficiency, and very low charge transfer and series resistance, ion-diffusion resistance, and relaxation time, which endorse the quick pseudocapacitive response of the material. The Mn 3 O 4 /NiSe 2 –MnSe 2 ||N-rGO ASSHPC device demonstrates excellent charge-storage physiognomies suggestive of rich electrochemical and electromicrostructural compatibility between the electrode materials in the fabricated assembly. The Mn 3 O 4 /NiSe 2 –MnSe 2 ||N-rGO ASSHPC device delivers high mass and area specific capacitance/capacity, very low charge-transfer resistance (∼0.74 Ω), total series resistance (∼0.76 Ω), diffusion resistance, and a relaxation time constant, which endorse the quick pseudocapacitive response of the device. The device delivers higher energy and power density (∼34 W h kg –1 at ∼2994 W kg –1 ), rate efficiency (∼17 W h kg –1 at ∼11,995 W kg –1 ), and cyclic performance (∼97.2% specific capacity/capacitance retention after 9500 continuous GCD cycles). The superior Ragone and cyclic efficiencies of the ASSHPC device are ascribed to the multiple redox-active Ni and Mn ions which lead to the supplemented number of redox reactions; “electroactive-ion buffering pool”-like physiognomics of Mn 3 O 4 /NiSe 2 –MnSe 2, which facilitate the electrolyte ion dissemination to the electroactive sites even at high rate redox condition; and ideal electro-microstructural compatibility between the electrode materials, which leads to assisted charge transfer and absolute ion dissemination during the charge-storage process.

Topics & Concepts

PseudocapacitorElectrodeSolid-stateMaterials scienceChemistryElectrochemistryPhysical chemistrySupercapacitorSupercapacitor Materials and FabricationAdvancements in Battery MaterialsElectrocatalysts for Energy Conversion