This module covers the principles of mixing in microfluidic systems, highlighting the importance of effective mixing for chemical reactions and biological assays. Topics include:
Students will engage in practical exercises to understand mixing dynamics in microfluidics.
This introductory module sets the foundation for understanding microscale transport processes. It covers the basic concepts and significance of these processes in various engineering applications. Emphasis is placed on defining key terms, the relevance of microscale phenomena in real-world applications, and the course outline.
This module continues the introduction to microscale transport processes, emphasizing the applications and importance of understanding these principles in various engineering fields. Students will discuss real-world case studies where microscale phenomena play a crucial role, enhancing their comprehension of the course material.
This module introduces the concept of Lab on Chip (LoC) technology, which integrates multiple laboratory functions onto a single chip. Students will learn about the design and application of microfluidic devices in biological and chemical analyses. The course will cover topics such as:
Overall, this module emphasizes the significance of LoC in advancing modern analytical techniques.
This module continues the exploration of Lab on Chip technology, delving deeper into the specific microfluidic processes and components. Students will be introduced to methodologies for the integration of various functions into microfluidic systems, including:
Students will analyze case studies showcasing the application of microfluidics in healthcare and environmental monitoring.
This module covers the practices involved in microscale manufacturing, focusing on the various techniques used to create microstructures and devices. Key topics include:
Students will gain insights into how these manufacturing practices impact the performance of microscale devices.
This module introduces photolithography, a critical technique used in the fabrication of microdevices. Photolithography involves patterning a substrate using light-sensitive materials. Students will learn about:
By the end of this module, students will understand the significance of photolithography in microscale device manufacturing.
This module continues the discussion on photolithography, focusing on advanced techniques and improvements in the process. Students will explore:
The module aims to equip students with knowledge about cutting-edge advancements in photolithography.
This module addresses the deposition techniques used in the formation of thin films and structures in microscale devices. Key topics include:
Students will analyze the role of deposition in enhancing the functionality of microscale components.
This module explores plastic microfluidic devices, emphasizing the benefits of using polymers in microfluidics. Students will learn about:
By the end of this module, students will appreciate the advantages of plastic microfluidics in various applications.
This module covers the principles of mixing in microfluidic systems, highlighting the importance of effective mixing for chemical reactions and biological assays. Topics include:
Students will engage in practical exercises to understand mixing dynamics in microfluidics.
This module continues the exploration of mixing in microfluidic systems, focusing on advanced mixing techniques such as chaotic advection and their applications. Key points include:
Students will also participate in hands-on activities to visualize chaotic mixing effects.
This module further investigates mixing processes in microfluidics, emphasizing modeling approaches to predict mixing performance. Key topics include:
Students will gain practical skills in using CFD tools to analyze mixing in microdevices.
This module introduces micro heat pipes, essential components for thermal management in microscale applications. Students will explore:
By the end of this module, students will understand the critical role of micro heat pipes in maintaining optimal operating temperatures.
This module continues the discussion on micro heat pipes, focusing on advanced designs and performance optimization techniques. Key topics include:
Students will learn how to optimize micro heat pipe designs for specific applications.
This module further explores mixing processes in microfluidics, focusing on more complex mixing phenomena and their implications. Students will delve into:
Practical examples will illustrate the complexities involved in achieving effective mixing at the microscale.
This module covers dispersion in microfluidic systems, discussing the importance of particle dispersion in various applications. Key topics include:
Students will engage in case studies that highlight dispersion's role in enhancing process efficiency.
This module continues the exploration of dispersion in microfluidic systems, focusing on advanced modeling techniques to predict dispersion behavior. Topics include:
Students will develop skills to create models that simulate dispersion phenomena in microfluidics.
This module further investigates dispersion, emphasizing the effects of flow characteristics on dispersion efficiency. Students will analyze:
Case studies will illustrate effective dispersion strategies in various fields.
This module introduces electrowetting, a phenomenon that alters the wettability of surfaces using an electric field. Key topics covered include:
Students will learn how electrowetting can be utilized to achieve precise control in microfluidic systems.
This module continues the discussion on electrowetting, focusing on the principles of electro-osmosis. Key topics include:
Students will explore how electro-osmosis facilitates fluid movement and enhances performance in microfluidic applications.
This module further investigates electrowetting, delving into applications and implications in microfluidic systems. Students will examine:
Students will gain insights into how electrowetting can enhance microfluidic functionalities.
This module covers dielectrophoresis, the movement of particles in a non-uniform electric field. Key topics include:
Students will explore how dielectrophoresis can be applied to microfluidic technologies for effective particle control.
This module continues the discussion on dielectrophoresis, emphasizing advanced applications and recent research developments. Key areas include:
Students will gain insights into cutting-edge research efforts and applications in the field.
This module further investigates dielectrophoresis, focusing on the manipulation of complex particle systems and interactions. Key topics include:
Students will analyze how particle interactions can be leveraged for enhanced microfluidic applications.
This module explores scaling dimensions and issues in microscale transport processes. Students will learn about:
Real-world examples will illustrate the challenges faced in microscale designs.
This module continues the discussion on scaling dimensions, focusing on slip flow phenomena in microscale applications. Key topics include:
Students will gain insights into the significance of slip flow in enhancing device performance.
This module introduces microstructured reactors, emphasizing their design and application in chemical processes. Topics covered include:
Students will explore how microreactors can revolutionize chemical engineering practices.
This module continues the exploration of microstructured reactors, focusing on advanced materials and innovative designs. Key points include:
Students will gain practical insights into designing and implementing effective microreactor systems.
This module covers immiscible flow in microchannels, discussing the challenges and techniques for managing two-phase flows. Key topics include:
Students will learn how to effectively manipulate immiscible fluids in microfluidic systems.
This module continues the exploration of immiscible flow in microchannels, focusing on complex flow patterns and their effects. Key topics include:
Students will engage in case studies to illustrate the challenges and solutions in managing immiscible flows.
This module further investigates immiscible flow in microchannels, focusing on advanced applications and recent research findings. Key topics include:
Students will analyze how these advancements can enhance performance in various industries.
This module explores the scaling dimensions and issues associated with immiscible flow in microfluidic systems. Topics include:
Students will learn how to navigate scaling challenges in their designs.
This module continues the discussion on immiscible flow, focusing on additional complexities and challenges faced in microchannels. Key topics include:
Students will explore innovative solutions to manage these complexities effectively.
This module covers plastic device making, highlighting the advantages of using plastic materials in microscale applications. Key topics include:
Students will analyze case studies showcasing successful plastic device implementations.
This module explores transport processes and their descriptions in microscale systems. Key topics include:
Students will learn to relate transport processes to real-world microscale applications.
This module investigates convective fluid dynamics in microchannels, focusing on the unique challenges and characteristics of fluid flow at microscale. Key topics include:
Students will analyze case studies to illustrate the complexities of convective dynamics in microfluidics.
This module covers microfluidic networks, emphasizing their design and application in various engineering fields. Key topics include:
Students will explore how microfluidic networks can enhance laboratory efficiency and accuracy.
This module introduces electrohydrodynamic atomization, a technique for generating fine droplets using electric fields. Key topics include:
Students will learn how electrohydrodynamic atomization can enhance performance in various applications.
This module continues the exploration of electrohydrodynamic atomization, focusing on advanced techniques and recent research findings. Key topics include:
Students will analyze case studies and discuss future trends in electrohydrodynamic atomization.
This module covers interfacial phenomena in thin liquid films, emphasizing their importance in microscale applications. Key topics include:
Students will explore how interfacial phenomena can impact device performance and functionality.