Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
7917255 | Energy Procedia | 2017 | 17 Pages |
Abstract
Hydrogen and nanocarbon were produced by the catalytic decomposition of electrocracking gas obtained by the pyrolysis of liquid organic waste via electric arc discharge. The GIAP-16 (NiO-Al2O3) industrial catalyst was used to reduce the maximum decomposition temperature to 700 °C. In a fixed-bed reactor, under atmospheric pressure, reasonable amounts of high-purity hydrogen were produced, accompanied by deposits of nanocarbon by-product. The NiO-Al2O3 catalyst showed excellent catalytic activity. X-ray powder diffraction analysis of the NiO-Al2O3 composite revealed the presence of cubic NiO and rhombohedral Al2O3, which were chemically stable. However, above 500 °C, NiAl2O4 began to appear. The specific surface area of the catalyst was determined to be 65.45 m2/g, and highly dispersed, with a pore size distribution centred around 4 nm. The morphologies of GIAP-16 and the nanocarbon were investigated by scanning electron microscopy; the catalyst contained an agglomeration of particles with thin well-formed filaments among much wider nanofibres and soot.
Related Topics
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Energy (General)
Authors
Ali S. Ismail, Ahmed H. Shukker, Amina A. Fayad,