An atomic force microscopy study of coal nanopore structure 被引量：31

An atomic force microscopy study of coal nanopore structure

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摘要 Coal nanopore structure is an important factor in understanding the storage and migration of absorbed gas in coal. A new method for studying coal nanopore structures is proposed. This idea is based on the nano-level resolution of atomic force microscopy, which can be employed to observe the structural features of coal nanopores clearly, conduct quantitative three-dimensional measurements and obtain structural parameters. Analysis results show that coal nanopores are mainly metamorphic pores and intermolecular pores. The metamorphic pores are commonly rounded and elliptical, increasing quantitatively with the coalification degree. The forms of intermolecular pores change markedly. The average pore size of low-rank coal is bigger than high-rank coal, and the number of intermolecular pores decreases as the coal rank increases. Section analysis effectively characterizes the coal pore microstructure, bearing analysis is a vital approach to measure microporosity, and grain analysis can be employed to study the pore size distribution. Atomic force microscopy is a tool for the in-depth research of coal pore microstructure and the coal-bed methane adsorption mechanism. Coal nanopore structure is an important factor in understanding the storage and migration of absorbed gas in coal. A new method for studying coal nanopore structures is proposed. This idea is based on the nano-level resolution of atomic force microscopy, which can be employed to observe the structural features of coal nanopores clearly, conduct quantitative three-dimensional meas- urements and obtain structural parameters. Analysis results show that coal nanopores are mainly metamorphic pores and intermo- lecular pores. The metamorphic pores are commonly rounded and elliptical, increasing quantitatively with the coalification degree The forms of intermolecular pores change markedly. The average pore size of low-rank coal is bigger than high-rank coal, and the number of intermolecular pores decreases as the coal rank increases. Section analysis effectively characterizes the coal pore microstructure, bearing analysis is a vital approach to measure microporosity, and grain analysis can be employed to study the pore size distribution. Atomic force microscopy is a tool for the in-depth research of coal pore microstructure and the coal-bed methane adsorption mechanism.

作者 YAO SuPing JIAO Kun ZHANG Ke HU WenXuan DING Hai LI MiaoChun PEI WenMing

机构地区 State Key Laboratory for Mineral Deposits Research

出处《Chinese Science Bulletin》 SCIE EI CAS 2011年第25期2706-2712,共7页

基金 supported by the National Natural Science Foundation of China (40973051)

关键词原子力显微镜纳米孔结构煤炭纳米级分辨率微观结构煤孔隙分子间三维定量 coal nanopore, atomic force microscopy, coal-bed methane, pore size distribution, porosity

分类号 TB383.1 [一般工业技术—材料科学与工程]

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