Synthesis and methane storage of binder-free porous graphene monoliths_中国颗粒学会

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Partic. vol. 11 no. 4 pp. 415-420 (August 2013)
doi: 10.1016/j.partic.2012.10.006

Synthesis and methane storage of binder-free porous graphene monoliths

Guoqing Ning*, Hao Wang, Xiaoxin Zhang, Chenggen Xu, Guangjin Chen, Jinsen Gao

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ngq@cup.edu.cnninggq@qq.com

Highlights

    • Nanomesh graphene (NMG) was synthesized by template chemical vapor deposition. • Binder-free graphene monoliths were prepared from loosely stacking NMG by tablet pressing. • Graphene monoliths have obvious elasticity and a porous structure. • Methane capacity of the graphene monolith was up to 236 (v/v) at 9 MPa.

Abstract

Nanomesh graphene (NMG) obtained by template chemical vapor deposition was used to synthesize the binder-free graphene monoliths by simple tablet pressing. The stacking manner of the NMG sheets was crucial to the cohesion interaction between the graphene sheets, only the NMG materials with a loosely stacking manner could be pressed into binder-free monoliths. At the tableting pressure of 2–8 MPa, both the bulk densities and the specific surface areas of the monoliths keep nearly constant as the tableting pressure increases, indicating that the NMG monoliths have obvious elasticity and a porous structure due to the large corrugations and the mesh structures of the graphene sheets. As a result, an extraordinary methane storage capacity of 236 (v/v) at 9 MPa was obtained in the graphene monolith prepared by tableting at 4 MPa.

Graphical abstract

Nanomesh graphene synthesized and graphene monoliths prepared.

Image for unlabelled figure

Keywords

Binder-free; Graphene; Monoliths; Methane storage



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