Development of an Amorphous Nickel Boride/Manganese Molybdate Heterostructure as an Efficient Electrode Material for a High-Performance Asymmetric Supercapacitor

Abstract: The exploration of heterostructure materials with unique electronic properties is considered a desirable platform for fabricating electrode/surface interface relationships for constructing asymmetric supercapacitors (ASCs) with high energy density. In this work, a heterostructure based on amorphous nickel boride (Ni X B) and crystalline square bar-like manganese molybdate (MnMoO4) was prepared by a simple synthesis strategy. The formation of the Ni X B/MnMoO4 hybrid was confirmed by powder X-ray diffraction (p… Show more

“…The increase in capacity value is due to the increase in surface wettability of AC and the synergic effect between both porous electrode materials during the charge–discharge cycle. Due to that, the asymmetric device (LNC3@Ni-foam//AC@Ni-foam) exhibits an increment in specific capacity . After 6000 cycles, the specific capacity remains the same for long cycles; hence, this device is suitable for long charge–discharge applications.…”

“…Due to that, the asymmetric device (LNC3@ Ni-foam//AC@Ni-foam) exhibits an increment in specific capacity. 51 After 6000 cycles, the specific capacity remains the same for long cycles; hence, this device is suitable for long charge−discharge applications. The specific capacity value is maintained at 97.1% after 10,000 cycles at the current density of 10 A g −1 .…”

Tailoring the Perovskite Structure to Acquire an Inorganic La₂NiCrO₆ Double Perovskite as an Efficient Energy Storage Application by Varying Molar Concentrations of Citric Acid

“…The increase in capacity value is due to the increase in surface wettability of AC and the synergic effect between both porous electrode materials during the charge–discharge cycle. Due to that, the asymmetric device (LNC3@Ni-foam//AC@Ni-foam) exhibits an increment in specific capacity . After 6000 cycles, the specific capacity remains the same for long cycles; hence, this device is suitable for long charge–discharge applications.…”

“…Due to that, the asymmetric device (LNC3@ Ni-foam//AC@Ni-foam) exhibits an increment in specific capacity. 51 After 6000 cycles, the specific capacity remains the same for long cycles; hence, this device is suitable for long charge−discharge applications. The specific capacity value is maintained at 97.1% after 10,000 cycles at the current density of 10 A g −1 .…”

Tailoring the Perovskite Structure to Acquire an Inorganic La₂NiCrO₆ Double Perovskite as an Efficient Energy Storage Application by Varying Molar Concentrations of Citric Acid

“…Furthermore, the ASC exhibits a specific capacity retention ratio of 59.4%, after 20 000 cycles at 10 A g −1 (Figure 6h). In Figure 6i, the NiCoP@NiCo−B-70// AC ASC reaches an energy density of 40.8 Wh kg −1 at a power density of 400.0 W kg −1 , and the energy density of 21.3 Wh kg −1 can be retained even at a maximum power density of 4000.0 W kg −1 , which outperforms other reported asymmetric energy storage devices, such as Ni x B/MnMoO 4 //AC (32.5 Wh kg −1 and 750 W kg −1 ), 38 CoMoO 4 /Co−B//AC (23.18 Wh kg −1 and 200.5 W kg −1 ), 72 Ni 2 B/RGO//AC (22.1 Wh kg −1 and 724.9 W kg −1 ), 28 Ni−B//AC (26.04 Wh kg −1 and 2.08 kW kg −1 ), 73 and NiCoP@CoS//AC (35.8 Wh kg −1 and 748.9 W kg −1 ). 60 The successful construction of NiCoP@NiCo−B-70//AC ASC provides inspiration for designing aqueous alkaline electrolyte devices with higher energy/power density.…”

“…70// AC ASC reaches an energy density of 40.8 Wh kg −1 at a power density of 400.0 W kg −1 , and the energy density of 21.3 Wh kg −1 can be retained even at a maximum power density of 4000.0 W kg −1 , which outperforms other reported asymmetric energy storage devices, such as Ni x B/MnMoO 4 //AC (32.5 Wh kg −1 and 750 W kg −1 ),38 CoMoO 4 /Co−B//AC (23.18 Wh kg −1 and 200.5 W kg −1 ),72 Ni 2 B/RGO//AC (22.1 Wh kg −1 and 724.9 W kg −1 ),28 Ni−B//AC (26.04 Wh kg −1 and 2.08 kW kg −1 ),…”

“…More importantly, in comparison to crystalline materials, the amorphous materials have a random network arrangement of atoms with a short-range ordering structure, which can facilitate the electrolyte ion diffusion and supply more reaction sites as a result of a large number of surface defects and the isotropic nature of amorphous materials. 32−34 Logically, the rational design of core−shell heterostructures by integrating a crystalline core with an amorphous shell, such as crystalline−amorphous core−shell heterostructures Ni 3 P@Ni x (PO y ) z , 35 NiSe 2 − Fe 3 Se 4 @NiCoB, 36 Ni 9 S 8 @Ni 2 B, 37 MnMoO 4 /Ni x B, 38 and NiMoO 4 @Co−B, 39 should be an attractive strategy for further enhancing the electrochemical performance of electrodes, because the crystalline core can provide stable mechanical support and the amorphous shell can improve the electrochemical active area. 40 Encouraged by the mentioned considerations, the crystalline/ amorphous NiCoP@NiCo−B-70 core−shell nanospheres are synthesized, where the nanosheet-assembled NiCoP hollow nanospheres and amorphous NiCo−B serve as the core and shell, respectively.…”

Constructing Crystalline NiCoP@Amorphous Nickel–Cobalt Boride Core–Shell Nanospheres with Enhanced Rate Capability for Aqueous Supercapacitors and Rechargeable Zn-Based Batteries

A hybrid supercapacitor assembled by reduced graphene oxide encapsulated lollipop-like FeNi2S4@Co9S8 nanoarrays