Japanese Developments

 
We present this Japanese research as additional confirmation of the validity of West Virginia University's focus on direct coal liquefaction techniques, and some specific components of those techniques, as opposed to indirect, i.e. the Fischer-Tropsch, Bergius, Karrick, etc., processes, for converting coal into crude liquids suitable for refining into petroleum substitutes.
 
The excerpt:
 
"Coal hydroliquefaction using highly dispersed catalyst precursors 

Naoki Ikenaga, Shusaku Kan-nan, Takahiro Sakoda and Toshimitsu Suzuki

Department of Chemical Engineering, Faculty of Engineering, Kansai University, Suita, Osaka 564, Japan 

Abstract

In order to discuss the hydrogen transfer process in coal liquefaction with a catalyst in the presence of a donor solvent, hydroliquefaction of Yallourn, Wyoming, Illinois No. 6, and Mi-ike coals and cracking of benzyl phenyl ether (BPE) were carried out in tetralin or tetralin/naphthalene mixed solvent under a hydrogen atmosphere with highly dispersed catalyst precursors such as Fe(CO)5---S, Mo(CO)6---S, and Ru3(CO)12.

In the absence of the catalyst, more than 70% of hydrogen was transferred from tetralin, as determined by the formation of naphthalene. In the presence of Mo(CO)6---S and Ru3(CO)12, however, the amount of hydrogen transferred from tetralin decreased to 15–40% of the total hydrogen and that from gas phase increased to 60–85% of the hydrogen required to stabilize coal fragment radicals even with an excess amount of tetralin. When the reaction was carried out in the tetralin/naphthalene mixed solvent, little hydrogenation of naphthalene occurred even with the active catalyst.

This strongly supports the assertion that a decrease in the amount of naphthalene in the catalyzed liquefaction of coal in tetralin with a catalyst can be ascribed to the direct hydrogen transfer from molecular hydrogen to coal fragment radicals. In the presence of coal or benzyl phenyl ether, little or no hydrogenation of naphthalene occurred."

This Japanese effort might seem unnecessary for us to report, even though it does seem to confirm WVU, and other, research results into catalyst specifics. However, it's important, we think, to continue making note of the fact that this kind of detailed effort is underway in various places throughout the world that are pretty far removed from each other. It's further confirmation of the solid reality that we can convert coal into perfectly acceptable replacements for petroleum-based fuels - just as the ancestors of these contemporary Japanese scientists did for Imperial Japan, at Kobe, in WWII, as we've documented.