Nanofluid Boiling - Sadaghiani, Ali; Ozbey, Arzu; Karimzadehkhouei, Mehrdad; Ko&
137,99 €
inkl. MwSt.
Versandkostenfrei*
Versandfertig in über 4 Wochen
payback
69 °P sammeln
  • Broschiertes Buch

Nanofluid Boiling presents valuable insights into boiling heat transfer mechanisms, offering state-of-the-art techniques for overcoming obstacles against nanofluid applications. In addition, the book points out emerging industrial applications and guides researchers and engineers in their research and design efforts. In addition, recommendations on future research directions and the design of systems involving nanofluids are presented at the end of each chapter. The book's authors comprehensively cover mechanisms, parametric effects and enhancement techniques in the boiling of nanofluids,…mehr

Andere Kunden interessierten sich auch für
Produktbeschreibung
Nanofluid Boiling presents valuable insights into boiling heat transfer mechanisms, offering state-of-the-art techniques for overcoming obstacles against nanofluid applications. In addition, the book points out emerging industrial applications and guides researchers and engineers in their research and design efforts. In addition, recommendations on future research directions and the design of systems involving nanofluids are presented at the end of each chapter. The book's authors comprehensively cover mechanisms, parametric effects and enhancement techniques in the boiling of nanofluids, providing updated, detailed information about recent developments and findings.
Autorenporträt
Ali Sadaghiani (Assistant Professor, Faculty of Engineering and Natural Sciences, Sabanci University, Istanbul, Turkey) specializes in interfacial transport and phase change phenomena. His research primarily focuses on heat and mass transfer in boiling, condensation, evaporation, and surface modification for energy and water systems. He is notably recognized for his parametric studies on mixed wettable and micro/nanostructured surfaces. His research has significantly advanced the understanding of liquid/vapor phase change mechanisms on these surfaces. His work has been instrumental in developing more efficient thermal management systems with applications in various industrial processes. His research has been published in several high-impact journals and has received considerable attention in thermal sciences. He employs theoretical, numerical, and experimental methods to enhance the efficiency of multiphase systems, addressing critical global challenges such as climate change, water scarcity, and energy efficiency.