Removal of Pollutants from Saline Water: Treatment Technologies provides a comprehensive understanding of technologies that are currently adopted in the treatment of pollutants present in saline water systems. It provides information on the treatment technologies for saline water systems, including seawater, brackish water, oil-produced water, and other industrial saline wastewaters. FEATURES Presents information exclusively for saline water pollutant removal Introduces current treatment technologies and addresses why and how the techniques differ between fresh and salt water Offers an inclusive overview of physicochemical, biological, membrane, and advanced oxidation treatment technologies Features various perspectives and case studies from relevant global experts Provides a comprehensive one-stop source for the treatment of pollutants in all saline water systems Aimed at students, academicians, researchers, and practicing engineers in the fields of chemical, civil, marine, and environmental engineering who wish to be acquainted with the most recent developments in the treatment of pollutants present in saline water systems. Prof. Dr. Shaik Feroz works at Prince Mohammad Bin Fahd University, Kingdom of Saudi Arabia. He has 30 years of experience in teaching, research, and industry. He has more than 190 publications to his credit in journals and conferences of international repute. He was awarded "Best Researcher" by Caledonian College of Engineering for the year 2014. Prof. Dr. Detlef W. Bahnemann is Head of the Research Unit, Photocatalysis and Nanotechnology at Leibniz University Hannover (Germany), Director of the Research Institute "Nanocomposite Materials for Photonic Applications" at Saint Petersburg State University (Russian Federation), and Distinguished Professor at Shaanxi University of Science and Technology in Xi'an (People's Republic of China). His research topics include photocatalysis, photoelectrochemistry, solar chemistry, and photochemistry focused on synthesis and physical-chemical properties of semiconductor and metal nanoparticles. His 500-plus publications have been cited more than 65,000 times (h-index: 100).

The aim of this text is to provide a comprehensive set of calculations relating to mass and energy balances for an entire process plant. An ammonia synthesis plant will be taken as a calculation model to develop the relevant mass and energy balances necessary for the design and subsequent production, as the production of ammonia synthesis gas is an internationally used process. Instead of teaching the basics of mass and energy balances, the text aims to give a detailed series of process integrated and illustrated calculations to help readers develop and design a process plant. * Details complete mass and energy calculations related to a manufacturing plant and includes stepwise procedures for mass and energy balances * Demonstrates how the series of integrated calculations will lead to the production of a specified amount of final product * Features "teaching" appendices that lay out applications of prior-assumed knowledge, which can be used in conjunction with the main text where more detailed explanation may be needed * Contains problems linked to various manufacturing sections covered in the text to help readers consolidate their knowledge This book will serve undergraduate Chemical Engineering students as a teaching aid in capstone design and related courses and gives useful insights to advanced students, researchers, and industry personnel within the Chemical Engineering field.

The aim of this text is to provide a comprehensive set of calculations relating to mass and energy balances for an entire process plant. An ammonia synthesis plant will be taken as a calculation model to develop the relevant mass and energy balances necessary for the design and subsequent production, as the production of ammonia synthesis gas is an internationally used process. Instead of teaching the basics of mass and energy balances, the text aims to give a detailed series of process integrated and illustrated calculations to help readers develop and design a process plant. * Details complete mass and energy calculations related to a manufacturing plant and includes stepwise procedures for mass and energy balances * Demonstrates how the series of integrated calculations will lead to the production of a specified amount of final product * Features "teaching" appendices that lay out applications of prior-assumed knowledge, which can be used in conjunction with the main text where more detailed explanation may be needed * Contains problems linked to various manufacturing sections covered in the text to help readers consolidate their knowledge This book will serve undergraduate Chemical Engineering students as a teaching aid in capstone design and related courses and gives useful insights to advanced students, researchers, and industry personnel within the Chemical Engineering field.

Describes nanomaterials for use in photovoltaic cells, solid state lighting, fuel cells, electrochemical batteries, electrochemical capacitors, superconductors, hydrogen storage, and photocatalysts. Focuses on commercial and economic aspects. Includes case studies drawn from practical research.