Share
Industrial Chemistry Reactions: Kinetics, Mass Transfer and Industrial Reactor Design
Santacesaria, Elio ; Tesser, Riccardo ; Russo, Vincenzo (Author)
·
Mdpi AG
· Hardcover
Industrial Chemistry Reactions: Kinetics, Mass Transfer and Industrial Reactor Design - Santacesaria, Elio ; Tesser, Riccardo ; Russo, Vincenzo
Choose the list to add your product or create one New List
✓ Product added successfully to the Wishlist.
Go to My Wishlists
Origin: U.S.A.
(Import costs included in the price)
It will be shipped from our warehouse between
Tuesday, July 02 and
Friday, July 12.
You will receive it anywhere in United Kingdom between 1 and 3 business days after shipment.
Synopsis "Industrial Chemistry Reactions: Kinetics, Mass Transfer and Industrial Reactor Design"
Nowadays, the impressive progress of commercially available computers allows us to solve complicated mathematical problems in many scientific and technical fields. This revolution has reinvigorated all aspects of chemical engineering science. More sophisticated approaches to catalysis, kinetics, reactor design, and simulation have been developed thanks to the powerful calculation methods that have recently become available. It is well known that many chemical reactions are of great interest for industrial processes and must be conducted on a large scale in order to obtain needed information in thermodynamics, kinetics, and transport phenomena related to mass, energy, and momentum. For a reliable industrial-scale reactor design, all of this information must be employed in appropriate equations and mathematical models that allow for accurate and reliable simulations for scaling up purposes. The aim of this proposed Special Issue was to collect worldwide contributions from experts in the field of industrial reactor design based on kinetic and mass transfer studies. The following areas/sections were covered by the call for original papers: Kinetic studies on complex reaction schemes (multiphase systems); Kinetics and mass transfer in multifunctional reactors; Reactions in mass transfer-dominated regimes (fluid-solid and intraparticle diffusive limitations); Kinetic and mass transfer modeling using alternative approaches (ex. stochastic modeling); Simulations in pilot plants and industrial-sized reactors and scale-up studies based on kinetic studies (lab-to-plant approach).