Your search keyword '"Soong Ho Um"' showing total 152 results

151. Effect of copper surface area and acidic sites to intrinsic catalytic activity for dimethyl ether synthesis from biomass-derived syngas

Author

Ki-Won Jun, Soong Ho Um, Jong Wook Bae, Pil J. Yoo, Ji Woo Jung, Dong Hyun Lee, and Yeong Jun Lee

Subjects

Process Chemistry and Technology, Inorganic chemistry, chemistry.chemical_element, Copper, Catalysis, Bifunctional catalyst, chemistry.chemical_compound, Ferrierite, chemistry, Dimethyl ether, Methanol, Bifunctional, General Environmental Science, Syngas

Abstract

The crucial effects of copper surface area and acidic sites to intrinsic catalytic activity on the bifunctional catalysts such as Cu-ZnO/Al 2 O 3 and Cu-ZnO-Al 2 O 3 /Zr-modified ferrierite catalysts have been investigated to find out the correlation between these two characteristics for the direct synthesis of dimethyl ether (DME) from biomass-derived syngas. The well-dispersed copper particles with a high reducibility as well as a large amount of weak acidic sites on bifunctional catalysts are responsible for their high catalytic performance. The high activity for methanol synthesis could be obtained by designing a high surface area of metallic copper with a low aggregation character, however, the quantity of the acidic sites on solid-acid components is also crucial factor for a high DME yield than the surface area of copper, which could be obtained by preparing proper bifunctional catalysts. It is mainly due to the fast reaction rate of methanol dehydration to DME compared to CO hydrogenation to methanol. The two important characteristics of the metallic surface area of copper and the amount of acidic sites are well correlated with the intrinsic catalytic activity on this consecutive reaction. The intrinsic activity for the direct DME synthesis from syngas on bifunctional catalysts initially decreases and maintains at constant value with the increase of the values of the copper surface area multiplied by the amount of acidic site.

152. Dynamics of squeezing fluids: Clapping wet hands.

Author

Gart, Sean, Brian Chang, Slama, Brice, Goodnight, Randy, Soong Ho Um, and Sunghwan Jung

Subjects

*DROPLETS, *LUBRICATION & lubricants, *APPLAUSE, *SURFACE tension, *INERTIA (Mechanics), *GRAVITY

Abstract

Droplets splash around when a fluid volume is quickly compressed. This phenomenon has been observed during common activities such as kids clapping with wet hands. The underlying mechanism involves a fluid volume being compressed vertically between two objects. This compression causes the fluid volume to be ejected radially and thereby generate fluid threads and droplets at a high speed. In this study, we designed and performed laboratory experiments to observe the process of thread and drop formation after a fluid is squeezed. A thicker rim at the outer edge forms and moves after the squeezing, and then becomes unstable and breaks into smaller drops. This process differs from previous well-known examples (i.e., transient crown splashes and continuous water bells) in aspects of transient fluid feeding, expanding rim dynamics, or sparsely distributed drops. We compared experimental measurements with theoretical models over three different stages; early squeezing, intermediate sheet-expansion, and later break-up of the liquid thread. In the earlier stage, the fluid is squeezed and its initial velocity is governed by the lubrication force. The outer rim of the liquid sheet forms curved trajectories due to gravity, inertia, drag, and surface tension. At the late stage, drop spacing set by the initial capillary instability does not change in the course of rim expansion, consequently final ejected droplets are very sparse compared to the size of the rim. [ABSTRACT FROM AUTHOR]

Published

2013