Synergetic Effect of Binary ZnS:SnS Composites with Reduced Graphene Oxide and Carbon Nanotubes as Anodes for Sodium-Ion Batteries

Abstract: The development of innovative materials with excellent electrochemical properties is immediately needed to dispel the problems of battery performance. In the present study, the hydrothermal method was applied to synthesize bimetallic sulfides (ZnS:SnS), which were then anchored on reduced graphene oxide (rGO) to produce ZnS:SnS@rGO composites or combined with carbon nanotubes (CNTs) to achieve ZnS:SnS@CNT composites. These composites were then investigated as electrodes for sodium-ion batteries, and their char… Show more

“…[32,39] In the oxidation process of the CV curve, there is a wide peak at 1.77 V, which is associated with potassium ion extraction, and metallic Zn is reconverted into ZnS. [31,40] It is clearly that the CV curves show a high degree of similarity in subsequent cycles. It indicates the electrochemical stability of the material to some extent.…”

“…The following Equation ( 1) describes the mathematical relationship between peak current (i) and scanning rate (v). Equation ( 2) is obtained by mathematical conversion of Equation ( 1): [18,34,40] i ¼ av b…”

“…The following Equation (1) describes the mathematical relationship between peak current (i) and scanning rate (v). Equation (2) is obtained by mathematical conversion of Equation : [18,34,40] $$$\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr {\rm i}={\rm a}v{^{b}}\hfill\cr}}$$$ $$$\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr {\rm Logi}={\rm blog}v+{\rm log}a\hfill\cr}}$$$ …”

Trumpet‐Like ZnS@C Composite for High‐Performance Potassium Ion Battery Anode

“…[32,39] In the oxidation process of the CV curve, there is a wide peak at 1.77 V, which is associated with potassium ion extraction, and metallic Zn is reconverted into ZnS. [31,40] It is clearly that the CV curves show a high degree of similarity in subsequent cycles. It indicates the electrochemical stability of the material to some extent.…”

“…The following Equation ( 1) describes the mathematical relationship between peak current (i) and scanning rate (v). Equation ( 2) is obtained by mathematical conversion of Equation ( 1): [18,34,40] i ¼ av b…”

“…The following Equation (1) describes the mathematical relationship between peak current (i) and scanning rate (v). Equation (2) is obtained by mathematical conversion of Equation : [18,34,40] $$$\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr {\rm i}={\rm a}v{^{b}}\hfill\cr}}$$$ $$$\vcenter{\openup.5em\halign{$\displaystyle{#}$\cr {\rm Logi}={\rm blog}v+{\rm log}a\hfill\cr}}$$$ …”

Trumpet‐Like ZnS@C Composite for High‐Performance Potassium Ion Battery Anode

“…Furthermore, the use of bimetallic TMSs has been signified as compared to monometallic TMSs to rout sluggish electrochemical kinetics, improve cyclic stability, and cushion volumetric expansion in SIBs. − Moreover, the conducting carbon intermediaries can be introduced in the synthesis of bimetallic TMSs to solve the problem of capacity fading, structural deprivation, and pulverization of the electrode material. , Various monometallic and mixed MSs have been reported, such as SnS/ZnS@C, Fe 1– x S@SC (sulfur-doped carbon), hollow nanoboxes of SnS/ZnS@C rooted in graphene, nanosheets of NS@CNT film, CoS 2 –NiS 2 -implanted graphene two-dimensional (2D) nanosheets, binary ZnS/SnS composites with rGO and CNTs, addition of graphene nanosheets into Ni 3 S 4 nanorods, nanocrystals of NiS 2 rooted in nitrogen CNTs, heterogeneous nanowalls of NiS–SnS 2 /carbon cloth, SnS/MoS 2 /NS-CNs heterostructure (SnS/MoS 2 N, S co-doped carbon nanosheets), heterostructural self-assembled NiS/SnS, hybrid structures of SnS 2 /Ni 3 S 2 –NIF, Co 1– x S hollow polyhedrons anchored on MCFs (multichannel carbon nanofibers), and MoS 2 /SnS@C hollow hierarchical nanotubes …”

“…19−21 Moreover, the conducting carbon intermediaries can be introduced in the synthesis of bimetallic TMSs to solve the problem of capacity fading, structural deprivation, and pulverization of the electrode material. 22,23 Various monometallic and mixed MSs have been reported, such as SnS/ZnS@C, 24 Fe 1−x S@SC (sulfurdoped carbon), 25 hollow nanoboxes of SnS/ZnS@C rooted in graphene, 26 nanosheets of NS@CNT film, 27 CoS 2 −NiS 2implanted graphene two-dimensional (2D) nanosheets, 28 binary ZnS/SnS composites with rGO and CNTs, 29 addition of graphene nanosheets into Ni 3 S 4 nanorods, 30 nanocrystals of NiS 2 rooted in nitrogen CNTs, 31 heterogeneous nanowalls of NiS−SnS 2 /carbon cloth, 32 SnS/MoS 2 /NS-CNs heterostructure (SnS/MoS 2 N, S co-doped carbon nanosheets), 33 heterostructural self-assembled NiS/SnS, 34 hybrid structures of SnS 2 /Ni 3 S 2 −NIF, 35 Co 1−x S hollow polyhedrons anchored on MCFs (multichannel carbon nanofibers), 36 and MoS 2 / SnS@C hollow hierarchical nanotubes. 37 Herein, we report a simplistic hydrothermal route for the fabrication of pure heterostructural bimetallic anode Ni 3 S 4 / SnS (denoted as NTS) structure and its hybrid composite electrodes implanted in CNTs (NTS-CNTs) and rGO (NTS-rGO).…”

Ni₃S₄/SnS/Graphene Oxide/Carbon Nanotube Composites as Anodes for Na-Ion Batteries

Hydrothermal synthesis and photocatalytic application of ZnS-Ag composites based on biomass-derived carbon aerogel for the visible light degradation of methylene blue