Microwaves in Chemistry Applications: Fundamentals, Methods and Future Trends offers a number of benefits over conventional heating technologies, including acceleration of reaction rates, milder reaction conditions, higher chemical yields, lower energy usage and different reaction selectivity, all of which can improve the sustainability of processes. The book provides valuable insights into the underlying chemistry at play in microwave-assisted processes, introducing fundamental concepts, discussing the modeling of reactions in such processes, and also highlighting a range of key methods and…mehr
Microwaves in Chemistry Applications: Fundamentals, Methods and Future Trends offers a number of benefits over conventional heating technologies, including acceleration of reaction rates, milder reaction conditions, higher chemical yields, lower energy usage and different reaction selectivity, all of which can improve the sustainability of processes. The book provides valuable insights into the underlying chemistry at play in microwave-assisted processes, introducing fundamental concepts, discussing the modeling of reactions in such processes, and also highlighting a range of key methods and applications of microwaves in chemistry for improved sustainability.
Beginning with an introduction to microwave chemistry, Part One discusses foundational principles, equipment and approaches for modeling reactions and assessing the outputs of those models. Methods in microwave chemistry are then the focus of Part Two, with microwave-assisted synthesis, catalysis, reduction and reactions all explored in detail. Part Three reflects on the practical usage of these methods to address specific issues, covering a number of interesting applications.
Aparna Das obtained her PhD degree in Material science/nanophysics from?Joseph Fourier University based upon the?work on "Semiconductor Quantum Dots for Opto-chemical Sensor Application? at French Alternative Energies and Atomic Energy Commission (CEA), France. Her postdoctoral experiences include working as a research scientist at the California Nano Systems Institute and Electric Engineering Department, University of California, Los Angeles (UCLA), USA, and as an experienced researcher at the Nanowiring-Marie Curie Initial Training Network, Georg August Universität Göttingen, Germany. Dr Das's research interests include Computer-assisted Physico-chemical methods, quantum mechanical calculations, interdisciplinary science (Biology, Chemistry, and Physics) for drug development,?computer-aided drug design, microwave applications, photochemical reactions, III-Nitride based chemical sensors, solar cells, optoelectronic devices, synthesis of thin layers and nanostructures including Qu
antum wells, quantum dots, and nanowires. She is the author of two books and received the young women researcher award, European microscopy society (EMS) outstanding paper awards, and several international fellowships such as the Marie-Curie fellowship, CEA-CNRS research fellowship, and Brain Korea 21 fellowship.
Inhaltsangabe
1. Foundational principles of microwave chemistry
2. Microwave equipment for chemistry
3. Modelling and interpreting microwave effects
4. Microwave-assisted synthesis of oxygen and sulphur heterocycles
5. Microwave-assisted synthesis of nitrogen heterocycles
6. Microwave-Assisted Oxidation and Reduction Reactions
7. Microwave-Assisted Enzymatic Reactions
8. Microwave-Assisted Sterilization
9. Microwave-enhanced CVD processes for diamond synthesis
10. Future trends in microwave chemistry and biology
