Sustaining Tomorrow with Minimal Entropy Generation : Proceedings of Eco-Friendly Engineering 2025 Symposium and Industry Summit (Springer Proceedings in Energy)

Ting, David S.-K. (EDT)/ Vasel-Be-Hagh, Ahmadreza (EDT)

Springer Nature Switzerland AG（2026/04発売）

• 製本 Hardcover:ハードカバー版／ページ数 236 p.
• 商品コード 9783032133564

Description

This book contains the Proceedings of Eco-Friendly Engineering 2025 Symposium and Industry Summit "Sustaining Tomorrow with Minimal Entropy Generation". Engineering may be defined as improving the human living standard via the appropriate application of science and mathematics. Bettering the quality of life must encompass the lives of both current and, at least, their seven future generations. As such, eco-friendly engineering is the only way to forge ahead. Gro Harlem Brundtland put this eloquently when she proclaimed, Sustainable development is the development that meets the needs of the present without compromising the ability of future generations to meet their own needs. Eco-Friendly Engineering 2025 is about sustaining a pleasant living standard with reduced entropy production. While all processes faithfully follow the second law of thermodynamics in producing entropy, much can be engineered in lessening the amount of entropy generated. This symposium provides a venue for experts from diverse backgrounds to exchange knowledge about their respective state-of-the-art progress to foster interdisciplinary collaboration to solidify eco-friendly engineering. Topics of interest include sustainable living, tenable development, and waste and pollution reduction and management.

Sustain what? For who? Survival needs, food for thought?- Design and analysis of an integrated solar-assisted supercritical CO2 Brayton cycle for power and cooling application: Enhancing efficiency through waste heat recovery.- Adsorption-based thermal energy storage units integrated with HVAC systems to facilitate the electrification of heating.- Exergy analysis for a hyperbolic-shape thermoelectric generator.- An overview of recent advances in using direct air capture for removing indoor carbon dioxide.- Energy and emission implications of battery-electric container ships operating from Los Angeles Harbor.- Flow friction reduction via slippering surface texturing.- Quantifying the impact of flow speed on flame initiation and propagation in lean methane combustion.- Schlieren visualization for complementing pressure trace combustion analysis.

Dr. David S-K. Ting is the founder of the Turbulence and Energy Laboratory, University of Windsor. As a professor in the Department of Mechanical, Automotive and Materials Engineering, he supervises students primarily on energy and flow turbulence. To date, he has co/supervised over ninety graduate students, co-authored more than one hundred and ninety journal papers, authored five textbooks, and co-edited more than thirty volumes.

Dr. Ahmad Vasel-Be-Hagh is an associate professor in the Department of Mechanical and Aerospace Engineering at University of South Florida. He serves as the founding principal investigator of the Thermofluids Discovery Laboratory. Dr. Vasel-Be-Hagh's research pursuits include analytical, computational, and experimental thermofluids, specifically focusing on their applications in environmental and atmospheric sciences, thermal power plants, wind and solar energy, and aerospace. He has published over 40 journal articles and edited three books, seven proceedings, and multiple special issues.