Control of Hydrophobic Interactions between Gas Bubbles in Water and Their Role in Gas Hydrate Formation and Dissociation. Methane is a powerful greenhouse gas, and its release in deep oceans and permafrost regions due to decomposition of methane hydrate, an ice-like crystalline, could potentially pose devastating threat to mankind. On the other hand, methane hydrate represents a vast energy potential to Australia and the remainder of the world. Understanding the mechanism of gas hydrate formati ....Control of Hydrophobic Interactions between Gas Bubbles in Water and Their Role in Gas Hydrate Formation and Dissociation. Methane is a powerful greenhouse gas, and its release in deep oceans and permafrost regions due to decomposition of methane hydrate, an ice-like crystalline, could potentially pose devastating threat to mankind. On the other hand, methane hydrate represents a vast energy potential to Australia and the remainder of the world. Understanding the mechanism of gas hydrate formation and dissociation is of fundamental importance to methane extraction and capture. This project employs state-of-the-art surface analytical tools to explore the mechanism of gas hydrate formation. The outcomes will strengthen Australia's leading role in scientific and technological development in this field. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239920
Funder
Australian Research Council
Funding Amount
$195,000.00
Summary
Control of free/dissolved gas content in a cavitation tunnel. The proposed equipment is for increased productivity and enhancing research capability of the Tom Fink Cavitation Tunnel located at the Australian Maritime College.
The cavitation tunnel is used for investigating flows about ships and underwater bodies.
The proposed equipment permits the rapid control of gas content in the tunnel water either dissolved or free as bubbles which together control the nature of cavitation and other ....Control of free/dissolved gas content in a cavitation tunnel. The proposed equipment is for increased productivity and enhancing research capability of the Tom Fink Cavitation Tunnel located at the Australian Maritime College.
The cavitation tunnel is used for investigating flows about ships and underwater bodies.
The proposed equipment permits the rapid control of gas content in the tunnel water either dissolved or free as bubbles which together control the nature of cavitation and other two phase flows.
The equipment will significant enhance existing research programs in support of the high speed craft and defence sectors of the maritime industry both nationally and internationally.Read moreRead less