Abstract
Herein, we report a simple yet efficient self-sacrifice template protocol to smartly fabricate hollow hetero-Ni7S6/Co3S4 nanoboxes (Ni-Co-S NBs). Uniform nickel cobalt carbonate nanocubes are first synthesized as the precursor via solvothermal strategy, and subsequently chemically sulfidized into hollow heter-Ni-Co-S NBs through anion-exchange process. When evaluated as electrode for electrochemical capacitors (ECs), the resultant hetero-Ni-Co-S NBs visually exhibit attractive pesudo-capacitance in KOH just after continuously cyclic voltammetry (CV) scanning for 100 cycles. New insights into the underlying energy-storage mechanism of the hollow hetero-Ni-Co-S electrode, based on physicochemical characterizations and electrochemical evaluation, are first put forward that the electrochemically induced phase transformation gradually occurrs during CV sweep from the hetero-Ni-Co-S to bi-component-active NiOOH and CoOOH, which are the intrinsic charge-storage phases for the appealing Faradaic capacitance (~677 F g−1 at 4 A g−1) of hollow Ni-Co-S NBs at high rates after cycling. When further coupled with negative activated carbon (AC), the AC//hetero-Ni-Co-S asymmetric device with extended electrochemical window of 1.5 V demonstrates high specific energy density of ~31 Wh kg−1. Of significance, we strongly envision that hollow design concept and new findings here hold great promise for enriching synthetic methodologies, and electrochemistry of complex metal sulfides for next-generation ECs.
Highlights
We report a simple yet efficient self-sacrifice template protocol to smartly fabricate hollow heteroNi7S6/Co3S4 nanoboxes (Ni-Co-S NBs)
It is still greatly challengable to explore and develop facile yet effective approaches to constructing hollow/mesoporous hetero-nanoarchitectures with homogenerous interface/chemical distribution at the nanoscale. With these considerations mentioned above in mind, in the contribution, we sucessfully fabricated the precursor of solid-solution nickel cobalt carbonate nanocubes by solvothermal approach, designed an efficient self-sacrifice template strategy to construct hollow hetero-Ni7S6/Co3S4 nanoboxes via shape-preserved anion exchange reaction (AER)
All the diffraction peaks can be successfully indexed to a solid-solution phase of NiCO3 (JCPDS card, #78-0210) and CoCO3 (JCPDS card, #11-0692), which should be rationally ascribed to their same Rhombohedral structure (R-3c (167)) and close lattice constants (4.6117 × 14.735 for NiCO3; 4.659 × 14.957 for CoCO3)
Summary
We report a simple yet efficient self-sacrifice template protocol to smartly fabricate hollow heteroNi7S6/Co3S4 nanoboxes (Ni-Co-S NBs). We strongly envision that hollow design concept and new findings here hold great promise for enriching synthetic methodologies, and electrochemistry of complex metal sulfides for next-generation ECs. In recent years, electrochemical capacitors (ECs) are emerging as promising energy-storage devices with numerous appealing electrochemical merits such as long-life span, fast charge/discharge rates, and safe operational mode, and so on. Electrochemical capacitors (ECs) are emerging as promising energy-storage devices with numerous appealing electrochemical merits such as long-life span, fast charge/discharge rates, and safe operational mode, and so on They have attracted tremendous attentions for potential applications in electric vehicles (EVs) and hybrid EVs in combination with rechargable batteries and/or fuel cells[1,2]. It is still greatly challengable to explore and develop facile yet effective approaches to constructing hollow/mesoporous hetero-nanoarchitectures with homogenerous interface/chemical distribution at the nanoscale
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