This module emphasizes problem-solving techniques in heterogeneous reactions. Students will engage in exercises and case studies to apply their understanding of the concepts learned throughout the course.
This introductory module outlines the objectives and scope of the course, giving students a foundational understanding of what to expect. It serves as an overview of the topics covered in subsequent modules.
This module delves into the basic concepts of representing chemical reactions. Students learn the essential terminologies and notations used in chemical reaction engineering, establishing a solid foundation for understanding subsequent complex topics.
This module introduces the thermodynamic principles relevant to chemical reactions. Students will examine concepts such as free energy, equilibrium, and reaction spontaneity, which are critical for understanding how chemical reactions proceed.
This module continues to explore thermodynamics, providing deeper insights into the energy changes in chemical reactions. It emphasizes the application of these principles to chemical engineering processes.
This module provides an overview of chemical reaction kinetics. Students will learn about rate laws, reaction orders, and the factors affecting reaction rates, which are essential for reactor design and optimization.
This module integrates reaction kinetics with reactor design principles. Students will explore how kinetic data is used in the design and analysis of reactors, enhancing their understanding of practical applications in chemical engineering.
This module focuses on the principles of chemical reactor design. Students will learn about different reactor types and their design considerations, including material selection, configuration, and operational conditions.
This module emphasizes problem-solving techniques in thermodynamics and kinetics. Through practical examples and exercises, students will apply learned concepts to solve real-world engineering problems.
This module introduces complex reactions, focusing on the various types and their implications for chemical engineering. It lays the groundwork for more advanced discussions on reaction networks and kinetics.
This module discusses yield and selectivity in complex reactions. Students will learn to analyze reaction outcomes and optimize conditions to achieve desired product distributions.
This module focuses on quasi-steady state and quasi-equilibrium approximations in complex reactions. Understanding these concepts allows students to simplify the analysis of reaction systems significantly.
This module explores the kinetics of chain reactions and polymerization processes. Students will analyze the mechanisms and dynamics that govern these complex reaction types.
This module introduces catalytic reactions, discussing their significance in chemical processes. Students will learn about the various types of catalysts and their roles in enhancing reaction rates.
This module discusses adsorption and desorption phenomena in catalytic reactions. Understanding these processes is crucial for optimizing catalyst performance and efficiency in real-world applications.
This module delves into the kinetics of catalytic reactions. It covers the principles governing catalyst activity, selectivity, and reaction rates, providing students with a thorough understanding of catalyst behavior.
This module focuses on the concept of monomolecular reaction networks and lumping analysis. Students will learn how to simplify complex reaction systems for analysis and design purposes.
This module emphasizes problem-solving techniques applied to complex reactions. Students will engage in practical exercises to reinforce their understanding and application of theoretical concepts.
This module explores gas-solid catalytic reactions, focusing on external diffusion processes. Students will understand how diffusion affects reaction rates and overall reactor performance.
This module discusses transport phenomena in catalyst pellets during gas-solid catalytic reactions. Understanding these processes is critical for optimizing reactor design and operational efficiency.
This module examines diffusion and reaction kinetics in gas-solid catalytic reactions. Students will analyze how these factors interact to influence overall reaction rates and effectiveness.
This module continues to explore diffusion and reaction kinetics in gas-solid catalytic reactions, focusing on the complexities of various operational conditions and their effects on performance.
This module further examines diffusion and reaction kinetics, emphasizing the importance of understanding these concepts in the context of catalyst performance and reactor efficiency.
This module discusses nonisothermal effects in gas-solid catalytic reactions. Students will learn how temperature variations influence reaction rates and the design of reactors.
This module focuses on gas-solid non-catalytic reactions, discussing their mechanisms, kinetics, and implications for reactor design. Students will analyze how these reactions differ from catalytic processes.
This module covers gas-liquid reactions, focusing on the interaction between phases and their implications for reactor design. Students will learn about mass transfer, reaction kinetics, and system stability.
This module emphasizes problem-solving techniques in heterogeneous reactions. Students will engage in exercises and case studies to apply their understanding of the concepts learned throughout the course.
This module introduces mass and energy balances in chemical reactor design. Students will learn to apply these principles to various reactor types, enhancing their analytical skills.
This module focuses on mass and energy balances specifically for heterogeneous reactions. Students will explore unique considerations for these systems and how to optimize reactor performance.
This module covers nonisothermal reactor operations, discussing the impact of temperature changes on reaction kinetics and overall reactor performance. Students will analyze case studies to understand practical applications.
This case study module focuses on ethane dehydrogenation processes. Students will analyze reactor design, performance metrics, and optimization strategies relevant to this industrial application.
This case study explores the hydrogenation of oil processes. Students will evaluate the design considerations and operational parameters necessary for effective reactor performance in this context.
This module focuses on ammonia synthesis, discussing the design and operational challenges associated with this critical chemical process. Students will analyze various reactor types and optimization techniques.
This module examines autothermal reactors, discussing their design, operational principles, and applications. Students will evaluate the advantages and challenges associated with this reactor type in various chemical processes.
This module discusses parametric sensitivity analysis in reactor design. Students will learn to evaluate how changes in parameters affect reactor performance and stability, enhancing their analytical skills.
This module examines multiple steady states in Continuous Stirred Tank Reactors (CSTRs). Students will analyze the conditions that lead to multiple equilibria and their implications for reactor operation.
This module covers the basics of stability analysis in chemical reactors. Students will learn about various techniques to assess reactor stability and the factors influencing it.
This module provides examples of stability analysis in real-world reactor scenarios. Students will analyze case studies to reinforce their understanding of stability principles and applications.
This module focuses on nonideal flow in reactors and its impact on performance. Students will learn how deviations from ideal flow conditions can affect reaction kinetics and reactor design.
This module continues the discussion on nonideal flow, delving deeper into its effects on various reactor types and their operational efficiencies. Students will evaluate strategies to mitigate these effects.
This module emphasizes problem-solving techniques in reactor design. Students will engage in practical exercises to apply theoretical principles in designing efficient and effective reactors.