Preparation of reduced graphene oxide@nickel oxide nanosheets composites with enhanced lithium-ion storage performance

“…[50,51]. As for NiO@graphene electrode, there is a different peak at about 0.47 V in the cathodic part of the first sweep, which also can be in agreement with formation of a SEI film and reduction of NiO to Ni, and Li x C (C + xLi + + xe − → Li x C) [15]. Besides, a main peak at 0.93 V is designated to the reduction of NiO [52].…”

“…It is especially noteworthy that the reversible capacity of NiO@graphene can reach up to 1560 mAh g −1 at the 70th cycle, corresponding to 143.3% capacity retention of the first cycle. This fascinating upward tendency may be derived from two aspects: (1) the inevitable formation of a gel-like polymer layer and the slight degradation of SEI film during the reduction process of NiO to Ni [29] and (2) graphene nanosheets that cannot only retard the structure expansion of NiO but also relieve the aggregation of active materials [1,15]. Then, the NiO@graphene material also displays a decreased reversible capacity of Fig.…”

“…Remarkably, NiO is regarded as a promising candidate among TMOs for the favorable theoretical capacity (718 mAh g −1 ), environmental friendliness, low price, natural abundance and safety [12][13][14]. Nevertheless, there are some inevitable weaknesses, such as poor conductivity and large volume changes in pure NiO anodes during the cycling process, which leads to the partial pulverization of electrode materials and the fast decline in capacity [15][16][17]. To overcome these challenges, a variety of nanostructured NiO anode materials, such as nanoparticle [18], nanorod [19], nanosheet [20] and nanotube [21], have been successfully synthesized, and all of them make an outstanding breakthrough in the electrochemical performances.…”

Facile Preparation of NiO@graphene Nanocomposite with Superior Performances as Anode for Li-ion Batteries

“…[50,51]. As for NiO@graphene electrode, there is a different peak at about 0.47 V in the cathodic part of the first sweep, which also can be in agreement with formation of a SEI film and reduction of NiO to Ni, and Li x C (C + xLi + + xe − → Li x C) [15]. Besides, a main peak at 0.93 V is designated to the reduction of NiO [52].…”

“…It is especially noteworthy that the reversible capacity of NiO@graphene can reach up to 1560 mAh g −1 at the 70th cycle, corresponding to 143.3% capacity retention of the first cycle. This fascinating upward tendency may be derived from two aspects: (1) the inevitable formation of a gel-like polymer layer and the slight degradation of SEI film during the reduction process of NiO to Ni [29] and (2) graphene nanosheets that cannot only retard the structure expansion of NiO but also relieve the aggregation of active materials [1,15]. Then, the NiO@graphene material also displays a decreased reversible capacity of Fig.…”

“…Remarkably, NiO is regarded as a promising candidate among TMOs for the favorable theoretical capacity (718 mAh g −1 ), environmental friendliness, low price, natural abundance and safety [12][13][14]. Nevertheless, there are some inevitable weaknesses, such as poor conductivity and large volume changes in pure NiO anodes during the cycling process, which leads to the partial pulverization of electrode materials and the fast decline in capacity [15][16][17]. To overcome these challenges, a variety of nanostructured NiO anode materials, such as nanoparticle [18], nanorod [19], nanosheet [20] and nanotube [21], have been successfully synthesized, and all of them make an outstanding breakthrough in the electrochemical performances.…”

Facile Preparation of NiO@graphene Nanocomposite with Superior Performances as Anode for Li-ion Batteries

“…A straightforward hydrothermal reaction combined with heat treatment was adopted to synthesize a nanocomposite of cross-linked rGO/NiO nanosheet [ 123 ]. This material as an anode of LIB exhibited outstanding results in terms of high discharge capacity, stable cyclic performance and remarkable rate capability.…”

“…( c , d ) Cyclic performance of nanocomposite at 100 and 400 mA g −1 current density. Adapted with permission from [ 123 ].…”

A Review on Recent Advancements of Ni-NiO Nanocomposite as an Anode for High-Performance Lithium-Ion Battery

Recent Progress on Nanostructured Transition Metal Oxides As Anode Materials for Lithium-Ion Batteries