2014
DOI: 10.1002/ese3.51
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Engineering evaluation of direct methane to methanol conversion

Abstract: Investigations into direct methane to methanol conversion are justified based on the avoidance of synthesis gas generation, which accounts for around 60% of the capital cost of synthesis gas to methanol conversion. A significant body of information already exists on the process chemistry, but little has been reported on the engineering of such a process. An engineering evaluation of the process was performed and the potential of this process as a platform technology for small-scale gas-to-liquids (GTL) applica… Show more

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Cited by 43 publications
(15 citation statements)
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“…The American Chemical Council estimates that as many as 148 projects totaling over $100 billion dollars in new capital investments will be floated over the next 10 years to take advantage of the shale gas boom. Methane can also be used as a feedstock for the manufacture of hydrogen (for ammonia production), syngas, methanol, gasoline and electricity (Wolf 1992 ; Hackworth et al 1995 ; Lange and Tijm 1996 ; Rostrup-Nielsen et al 2000 ; Lange 2001 ; Rostrup-Nielsen 2002 ; de Klerk 2015 ); and this proposition is corroborated by a detailed assessment of the carbon and thermal efficiencies and capital costs for a suite of methane-to-chemicals processes (Fig. 8 ).…”
Section: The New Bioeconomymentioning
confidence: 99%
“…The American Chemical Council estimates that as many as 148 projects totaling over $100 billion dollars in new capital investments will be floated over the next 10 years to take advantage of the shale gas boom. Methane can also be used as a feedstock for the manufacture of hydrogen (for ammonia production), syngas, methanol, gasoline and electricity (Wolf 1992 ; Hackworth et al 1995 ; Lange and Tijm 1996 ; Rostrup-Nielsen et al 2000 ; Lange 2001 ; Rostrup-Nielsen 2002 ; de Klerk 2015 ); and this proposition is corroborated by a detailed assessment of the carbon and thermal efficiencies and capital costs for a suite of methane-to-chemicals processes (Fig. 8 ).…”
Section: The New Bioeconomymentioning
confidence: 99%
“…1,8,9 However, the low C 2 yield of OCM has long limited its economic feasibility. 1,10 The main reason is that highly efficient catalysts with high methane conversion and C 2 hydrocarbon selectivity have not been developed. 11 Methane is a highly symmetric and nonpolarized molecule, and the C−H bond dissociation energy is as high as 4.55 eV.…”
Section: Introductionmentioning
confidence: 99%
“…Natural gas consists mostly of methane, which is a valuable source of energy and industrial chemicals. , As such, conversion of methane to liquid derivatives like methanol is the target of many research efforts. Efficient and direct conversion of methane to methanol will likely be more cost-effective than current liquefaction techniques. , Of the various systems that are active toward the methane C – H bond, copper-exchanged zeolites have garnered great interest. The active sites for converting methane to methanol in these zeolites are known to be small copper-oxo species. There however is some debate about the exact nature of these species. Several monocopper, dicopper, and tricopper species have been proposed. , However, invocation of a unique tricopper tri-oxo, [Cu 3 O 3 ] 2+ , active site species complicates the established description of the Cu 2+ /Cu + redox couple as the driver for the conversion of methane to methanol .…”
Section: Introductionmentioning
confidence: 99%