Grain boundary and curvature enhanced lithium adsorption on carbon

Pang, Zhenqian; Shi, Xinghua; Wei, Yujie; Fang, Daining

doi:10.1016/j.carbon.2016.06.035

Cited by 19 publications

(21 citation statements)

References 39 publications

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“…We found that, adsorption kinetic parameters of calcium ion on our oxidized graphene sheets agree with the adsorption nature of the other graphene oxide. Which is produced by another process with increasing adsorption capacity of our graphene oxidized sheets toward calcium ions respecting to other ions in the same rank, so a pseudosecond demand model can be considered (Pang et al 2016, Liu et al 2016aTan et al 2016). The latter is shown that the rate determining step may be chemical adsorption one through the exchange of electrons amidst adsorbent and adsorbate.…”

Section: Effect Of Contact Time and Adsorption Kineticsmentioning

confidence: 99%

Absorption of calcium ions on oxidized graphene sheets and study its dynamic behavior by kinetic and isothermal models

et al. 2016

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Sorption of calcium ion from the hard underground water using novel oxidized graphene (GO) sheets was studied in this paper. Physicochemical properties and microstructure of graphene sheets were investigated using Raman spectrometer, thermogravimetry analyzer, transmission electron microscope, scanning electron microscope. The kinetics adsorption of calcium on graphene oxide sheets was examined using Lagergren first and second orders. The results show that the Lagergren secondorder was the best-fit model that suggests the conception process of calcium ion adsorption on the Go sheets. For isothermal studies, the Langmuir and Freundlich isotherm models were used at temperatures ranging between 283 and 313 K. Thermodynamic parameters resolved at 283, 298 and 313 K indicating that the GO adsorption was exothermic spontaneous process. Finally, the graphene sheets show high partiality toward calcium particles and it will be useful in softening and treatment of hard water.

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Section: Effect Of Contact Time and Adsorption Kineticsmentioning

confidence: 99%

Absorption of calcium ions on oxidized graphene sheets and study its dynamic behavior by kinetic and isothermal models

et al. 2016

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“…As expected, the adsorption energies on different curvature models are gradually reduced as the number of adsorbed Li atoms increases ( Figure 5 d), which mainly originates from the Li–Li Coulombic repulsion. 11 The values of the adsorption energies are still negative, indicating an exothermic and stable reaction. 33 Importantly, even though the Li–Li distance (LiC 2 ) on NEGS is shorter relative to that (LiC 6 ) in the graphene, the adsorption energies of NEGS for LiC 2 remain stronger than that of graphene for LiC 6 with the increase of Li atoms.…”

Section: Resultsmentioning

confidence: 99%

“…In particular, theoretical calculations suggested that the positive and negative curvature structures of the carbon materials not only show a positive effect on Li + adsorption but also lead to three-dimensional Li-ion diffusion paths with relatively low energy barriers. 10 , 11 In fact, the geometric architecture is essentially derived from the transformation of the hybridized orbital types of carbon atoms to generate the response of chemical bonds to bending deformations, 12 thereby resulting in the regulation of the geometric and electronic structures within the atomic-scale scope. 8 , 13 − 16 However, the underlying reasons for extra capacity have not been uncovered deeply, especially the level of the electronic structure, much less to construct the relationship between non-coplanar sp 2 /sp 3 hybridized orbital and their corresponding Li-ion storage properties.…”

Section: Introductionmentioning

confidence: 99%

sp²/sp³ Hybridized Carbon as an Anode with Extra Li-Ion Storage Capacity: Construction and Origin

Gao

Ding

et al. 2020

ACS Cent. Sci.

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Doping in carbon anodes can introduce active sites, usually leading to extra capacity in Li-ion batteries (LIBs), but the underlying reasons have not been uncovered deeply. Herein, the dodecahedral carbon framework (N-DF) with a low nitrogen content (3.06 wt %) is fabricated as the anode material for LIBs, which shows an extra value of 298 mA h g –1 during 250 cycles at 0.1 A g –1 . Various characterizations and theoretical calculations demonstrate that the essence of the extra capacity mainly stems from non-coplanar sp 2 /sp 3 hybridized orbital controlling non-Euclidean geometrical structure, which acts as new Li-ion active sites toward the excess Li + adsorption. The electrochemical kinetics and in situ transmission electron microscope further reveal that the positive and negative curvature architectures not only provide supernumerary Li + storage sites on the surface but also hold an enhanced (002) spacing for fast Li + transport. The sp 2 /sp 3 hybridized orbital design concept will help to develop advanced electrode materials.

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“…First-principle calculations [158] based on density functional theory (DFT) revealed that the lithium adsorption on graphene could be enhanced by topological defects including divacancy (5-8-5 rings) and Stone-Wales defect (5-7-5-7 rings) due to the increased charge transfer between the adatom and defected sites in graphene. Later theoretical studies found that not only topological defects like 5-, 7-and 8-rings (Fig 14a-c), but curvatures (Fig 14d) of the graphene sheet could also enhance lithium adsorption resulting in better lithium storage property [159].…”

Section: Topologically Designed Graphene For Novel Energy Related Appmentioning

confidence: 99%

Topological Design of Graphene

Zhang

et al. 2019

Handbook of Graphene

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Topological defects (e.g. pentagons, heptagons and pentagon-heptagon pairs) have been widely observed in large scale graphene and have been recognized to play important roles in tailoring the mechanical and physical properties of two-dimensional materials in general. Thanks to intensive studies over the past few years, optimizing properties of graphene through topological design has become a new and promising direction of research. In this chapter, we review some of the recent advances in experimental, computational and theoretical studies on the effects of topological defects on mechanical and physical properties of graphene and applications of topologically designed graphene. The discussions cover out-of-plane effects, inverse problems of designing distributions of topological defects that make a graphene sheet conform to a targeted three-dimensional surface, grain boundary engineering for graphene strength, curved graphene for toughness enhancement and applications in engineering energy materials, multifunctional materials and interactions with biological systems. Despite the rapid developments in experiments and simulations, our understanding on the relations between topological defects and mechanical and physical properties of graphene and other 2D materials is still in its infancy.The intention here is to draw the attention of the research community to some of the open questions in this field.

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Grain boundary and curvature enhanced lithium adsorption on carbon

Cited by 19 publications

References 39 publications

Absorption of calcium ions on oxidized graphene sheets and study its dynamic behavior by kinetic and isothermal models

Absorption of calcium ions on oxidized graphene sheets and study its dynamic behavior by kinetic and isothermal models

sp²/sp³ Hybridized Carbon as an Anode with Extra Li-Ion Storage Capacity: Construction and Origin

Topological Design of Graphene

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Grain boundary and curvature enhanced lithium adsorption on carbon

Cited by 19 publications

References 39 publications

Absorption of calcium ions on oxidized graphene sheets and study its dynamic behavior by kinetic and isothermal models

Absorption of calcium ions on oxidized graphene sheets and study its dynamic behavior by kinetic and isothermal models

sp2/sp3 Hybridized Carbon as an Anode with Extra Li-Ion Storage Capacity: Construction and Origin

Topological Design of Graphene

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Product

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sp²/sp³ Hybridized Carbon as an Anode with Extra Li-Ion Storage Capacity: Construction and Origin