This curriculum provides an in-depth exploration of the core principles, methodologies, and cutting-edge innovations within the field of materials science and engineering, with a particular emphasis on the microelectronics industry. Techniques for Electronic Devices Fabrication introduces students to the practical processes involved in creating electronic devices, focusing on the methods used to fabricate components such as semiconductors, sensors, and integrated circuits. Human Centered Design Methods I applies user-centered principles to the design and development of technology, ensuring that electronic devices and systems are not only functional but also accessible and responsive to user needs. Electronic Properties of Materials delves into the fundamental properties of materials that are critical to the design of electronic components, covering topics such as conductivity, band structure, and charge transport mechanisms. Introduction to Structural Materials provides a foundation in the mechanical properties of materials, teaching students how structural materials are chosen and tested for their strength, durability, and performance in various engineering applications. Development of Modern Materials for the Microelectronics Industry examines the advancements in materials science that have revolutionized the microelectronics field, including the development of advanced semiconductors, nanomaterials, and other innovative materials that enable faster, more efficient electronic devices. Optimization of Engineering Systems focuses on the mathematical and computational techniques used to improve the performance and efficiency of engineering systems, offering students tools to optimize design, manufacturing processes, and device functionality. Quantum Physics for Semiconductor Engineers explores the quantum mechanical principles that underlie semiconductor behavior, essential for the understanding and development of modern electronic devices like transistors, lasers, and quantum computing components. Finally, the Development of Modern Materials for the Microelectronics Industry course revisits the role of material science in microelectronics, emphasizing the ongoing innovations in materials research that continue to drive advancements in device miniaturization, power efficiency, and speed. Collectively, these courses equip students with the knowledge and practical skills necessary to tackle the challenges of developing and optimizing materials and devices for the rapidly evolving microelectronics industry.

This curriculum provides a comprehensive foundation in the core principles and advanced techniques essential for innovation and optimization in materials science and engineering, particularly within the context of the microelectronics industry. Techniques for Electronic Devices Fabrication focuses on the hands-on processes and technologies used to create and manufacture electronic devices, with a special emphasis on semiconductor fabrication, device assembly, and integration into electronic systems. Human Centered Design Methods I applies user-centered design principles to technology development, ensuring that devices and systems are not only functionally efficient but also meet the needs and expectations of end users, considering accessibility, usability, and human interaction. An Introduction to Continuum Mechanics and Modern Applications explores the behavior of materials under various forces, introducing students to key concepts in mechanics, stress, strain, and material deformation, which are critical for understanding the physical properties of materials used in engineering applications. Introduction to Structural Materials provides foundational knowledge of the materials used in structural applications, focusing on their properties such as strength, flexibility, and durability, and how these characteristics influence the choice of materials in different engineering sectors. Manufacturing in a Climate Emergency addresses the pressing challenges posed by climate change on manufacturing processes, examining sustainable practices, energy efficiency, and the role of green technologies in minimizing the environmental impact of industrial production. Development of Modern Materials for the Microelectronics Industry delves into innovations in materials science that have transformed microelectronics, with an emphasis on advanced semiconductors, nanomaterials, and other cutting-edge materials that enable the development of high-performance, energy-efficient electronic devices. Quantum Physics for Semiconductor Engineers provides students with an understanding of the quantum mechanical principles that govern the behavior of semiconductors, essential for designing and optimizing electronic devices such as transistors and integrated circuits. The repetition of Development of Modern Materials for the Microelectronics Industry emphasizes the continued importance of material innovation in pushing the boundaries of electronic devices, focusing on next-generation materials for applications ranging from microchips to quantum computing. Together, these courses equip students with a well-rounded and up-to-date understanding of the materials, processes, and design principles required to address the complexities of modern engineering challenges, especially within the context of sustainable and efficient technologies for the microelectronics sector.

This curriculum offers a broad and interdisciplinary exploration of key topics in engineering, emphasizing sustainable practices and the management of natural and engineered systems in the context of modern challenges. Principles of Modern Ocean Engineering introduces students to the fundamental concepts and technologies used in the design, construction, and operation of structures and systems in marine environments. The course covers topics such as hydrodynamics, coastal engineering, and offshore energy systems, which are essential for addressing the increasing demands for ocean-based industries and renewable energy solutions. Engineering a Net-Zero Carbon Future examines the technologies, systems, and strategies required to achieve a carbon-neutral society, focusing on the integration of renewable energy, energy efficiency, and carbon capture technologies to reduce global greenhouse gas emissions. Manufacturing in a Climate Emergency explores sustainable manufacturing practices, addressing the urgent need for industries to reduce their environmental impact and contribute to climate change mitigation. The course examines alternative manufacturing processes, resource efficiency, and the role of innovative materials in reducing the carbon footprint of industrial production. Nuclear Energy and the Environment delves into the role of nuclear energy as a low-carbon energy source, evaluating its potential to address global energy needs while considering its environmental impact, safety concerns, and long-term sustainability. Earthquake-Induced Soil Liquefaction focuses on the study of soil behavior under seismic forces, particularly the phenomenon of soil liquefaction, which can cause catastrophic damage to infrastructure and communities during earthquakes. The course emphasizes the importance of understanding and mitigating the risks associated with this geotechnical issue. Introduction to Structural Materials provides a foundational understanding of the properties, selection, and application of materials used in structural engineering, with a focus on ensuring safety, durability, and efficiency in construction. Renewable Energy Systems explores various forms of renewable energy, including wind, solar, hydro, and bioenergy, with a focus on their integration into existing energy grids, technological advancements, and the challenges of scaling renewable energy solutions to meet global demand. Finally, Wildland Fire Engineering addresses the unique engineering challenges posed by wildfires, including fire behavior, risk assessment, and mitigation strategies for protecting communities, infrastructure, and ecosystems in fire-prone areas. This comprehensive set of courses prepares students to tackle some of the most pressing global challenges, from sustainable energy production to disaster resilience, with a strong emphasis on innovative engineering solutions and environmental responsibility.

This diverse set of engineering courses provides students with a comprehensive understanding of modern technological advancements, focusing on both the theoretical foundations and practical applications of emerging systems. Human Centered Design Methods I introduces students to the principles of designing technology with the end-user in mind, emphasizing user experience and interface design. Flying Robots explores the rapidly evolving field of aerial robotics, covering everything from small drones to futuristic concepts like aerial taxis, while examining the underlying technologies and control systems that enable these machines to fly safely and efficiently. The course on Analysis and Control of Nonlinear Systems tackles complex systems behavior, focusing on the mathematical techniques required to analyze and control systems that do not exhibit linear characteristics, a crucial skill for engineering applications in various fields. Legged Robots takes a deep dive into the design and control of robots capable of walking and running, exploring the challenges of movement, stability, and efficiency in robotic locomotion. Optimization of engineering systems teaches students to apply mathematical models and algorithms to improve the performance and efficiency of engineering systems, a key skill in various industries, including manufacturing, transportation, and energy. The Digital Transformation in Industry addresses how the fourth industrial revolution is reshaping industries through the adoption of digital technologies, automation, and smart systems, preparing students for the future of manufacturing and services. Applied Data Science for Engineers equips students with the tools and techniques needed to analyze and interpret complex data, enabling them to make data-driven decisions in engineering contexts. Finally, Python for Engineers provides a hands-on introduction to programming in Python, a versatile language used for a wide range of engineering applications, from data analysis to automation and machine learning. Together, these courses provide a robust framework for students to navigate and excel in the rapidly evolving fields of robotics, data science, and industrial technology.