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Catalyzing the Intercalation Storage Capacity of Aqueous Zinc-Ion Battery Constructed with Zn(II) Preinserted Organo-Vanadyl Hybrid Cathode

Radha Nagaraj, Srimanta Pakhira, Kanakaraj Aruchamy, Prahlada Thippeswamy, Dibyendu Mondal, Kalpana Dharmalingm, S.K. Nataraj, Debasis Ghosh

2020ACS Applied Energy Materials40 citationsDOI

Abstract

This article reports the first instance of exploring a chemically Zn(II) preinserted organic–inorganic hybrid material [vanadyl ethylene glycolate or VEG, (VO(CH2O)2)] as an efficient cathode for rechargeable zinc-ion batteries (ZIBs). The control VEG electrode synthesized by a glycothermal process showed a modest specific capacity of 157 mAh/g at 0.1 A/g current density, however, suffered from poor rate capability and cycle stability due to structural dissolution. Chemically Zn(II) preinsertion into VEG (Zn-VEG) catalyzed the Zn2+ intercalation in the Zn-VEG cathode with a significantly decreased charge transfer resistance, resulting in high discharge capacity of 217 mAh/g (at 0.1 A/g) accompanied by excellent rate capability with ∼50% capacity retention on increasing the current by 50 times. A first-principles-based hybrid density-functional theory (DFT) study revealed that the electronic structure of the Zn-intercalated VEG is thermodynamically stable, indicating an energetically favorable Zn-ion intercalation process. The Zn(II) preinserted VEG cathode allowed faster ionic diffusion (DZn2+ in the order of 10–9 cm2/s), and the diffusion controlled process was the major contributor (∼66.9%) to the overall capacity at low scan rate (0.1 mV/s) and remained significant (43.8%) even at high scan rate of 0.8 mV/s. Furthermore, the Zn(II) preinsertion in the VEG could act as a bridge to hold the VEG layers firmly. This provides the desired structural stability to the Zn-VEG cathode during a continuous Zn2+ insertion/deinsertion process, resulting in excellent cycle stability with only ∼0.005% capacity loss per cycle over 2000 cycles (at 4 A/g) while maintaining a high columbic efficiency of 99.9% throughout the cycles. The high capacity accompanied by excellent rate capability and cycle stability supports the as-prepared Zn(II) preinserted organo-vanadyl hybrid electrode to be a potential cathode material for ZIBs.

Topics & Concepts

CathodeIntercalation (chemistry)Materials scienceDiffusionCapacity lossDissolutionInorganic chemistryChemical engineeringElectrochemistryElectrodeChemistryPhysical chemistryThermodynamicsPhysicsEngineeringAdvanced battery technologies researchAdvancements in Battery MaterialsAdvanced Battery Technologies Research
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