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To provide engineers with a working knowledge of the economic evaluation of the investment in R&D projects related to engineering or technological development.
The goal of this course is to provide engineers with a working knowledge of the economic evaluation of the investment in R&D projects related to engineering or technological development. Three main topics concerni+C27:C28ng economic evaluation of R&D project are covered, evaluation of R&D project with deterministic cash flow, evaluation of R&D considering uncertaity, and R&D project selection. In particular, this course addresses on applications to case studies of industrial R&D projects.
As the issue of climate change emerges, IMO strengthens GHG (greenhouse gas) emissions regulations. The environment-friendly ship cannot be achieved by one or two technologies, various technologies are in discussion at the same time.
This class reviews various existing fuel systems and the need for next-generation alternative fuel supply systems for ships including LNG, hydrogen, ammonia, bio-fuels, and e-fuels, combined with carbon dioxide capture, utilization, and storage (CCUS) technologies.
Students learn the history of IMO regulation to reduce the GHG(greenhouse gas) emissions from ships, and how to estimate the GHG intensity. Also, students study the need for alternative fuels and the facing problems.
Covering the fundamental properties of organic semiconductors for attaining aptitude for the recent research developments in the field.
Organic semiconductors have significantly different electronic structure and transport properties due to a large degree of structural and energetic disorder. In this course, we will cover the optical and transport properties of organic materials and how these determine the resulting device properties, which will be extended to the current material & device research developments in the field.
This course covers variety types of geophysical inversion method from linear to non-linear inversion and the course is fundamentally designed for graduate students. After studying the inversion theory, a practical application of stochastic inversion (Markov-chain Monte Carlo) will be examined during the hands-on training session. In short, this course covers both theory and application of the geophysical inverse problem. For the demonstration of the inversion application, we are to use the Sleipner CCS dataset released by the Sleipner joint venture (Equinor, Exxonmobil, etc.). The hands-on training session includes 1) seismic interpretation, 2) well log analysis and upscaling, 3) petrophysical property modeling, and 4) volumetric analysis.
The key goal of the course is to acquire the theoretical background about the inverse problem and to understand how the inversion result (i.e., impedance inversion) can be used as a guide data for the petrophysical modeling. The workflow which will be introduced in this course can be applied to both oil & gas exploration and CCS projects.
This course will introduce distinct mechanical properties of nanostructural materials.
The course provides a theoretical basis of unique mechanical properties of nanostructural materials and their application. The course will also discuss the diverse methodologies of nanomechanical testing, simulation and characterization.
We aim to equip the skill for structural analysis and design of local structural elements in Marine Structures such as beam-column, unstiffened- and stiffened panel. Elastic and plastic analysis concepts and buckling behaviour of the local elements will be discussed. The characteristics of the vibration of local elements will also be covered in brief. This module may help ship structural engineers access the strength and safety of local structural elements of marine structures.
The objective of this modulue is to produce the structural engineers and researchers who are interested in the advanced marine structural design.
Attention: Students who have received credit for the following courses offered in 2021 do not receive credit for this course. Auditing is permitted.
Introduce linear and nonlinear water surface wave theories and applications.
To introduce linear and nonlinear wave theories based on firmly established mathematics and to apply to engineering problems.
As the challenge of achieving carbon neutrality has become a global trend, the research and development (R&D) of small modular reactors (SMRs) and micro modular reactors (MMRs) has been vigorously promoted in many countries around the world due to their excellent safety, easy manufacturing controllability, and high flexibility in terms of location, operation, and utilization. This lecture will provide students with an opportunity to get an overall picture of the social and technological factors that are important for understanding SMR and MMR R&D. Specifically, as an introduction, the attractiveness of SMR and the challenges for its successful development are discussed starting from the review of its utility requirements. The development strategy and status of Korean innovative SMR is introduced. Subsequently, the MMR development status is reviewed and its competitiveness is discussed. Potential applications of the reactors including space applications is introduced. Finally, we will discuss what kind of changes SMR can bring about with regard to the social aspects of nuclear power utilization. Specifically, economics, social acceptance, and proliferation resistance will be compared with those of conventional large reactors. In addition, we will discuss in what kind of implementation environment SMR can be a competitive or more attractive option to conventional large reactors, introducing several specific evaluation cases from the literature.
Participants will be able to understand the current status of SMR and MMR development and their significance. They will also be able to learn how SMR and MMR R&Ds are conducted. Through these, we hope to stimulate students' interest in the R&Ds on the small reactors.
Introduce advanced marine structural mechanics theories and application.
This short course aims to equip the skill for structural analysis and design of local structural elements in Marine Structures such as beam-column, unstiffened- and stiffened panel. Elastic and plastic analysis concepts and buckling behaviors of the local elements will be discussed. The characteristics of the vibration of local elements will also be covered in brief. This module may help ship structural engineers access the strength and safety of local structural elements of marine structures.
Introduce linear and nonlinear water surface wave theories and applications.
To introduce linear and nonlinear wave theories based on firmly established mathematics and to apply to engineering problems.
To provide engineers with a working knowledge of the economic evaluation of the investment in R&D projects related to engineering or technological development.
The goal of this course is to provide engineers with a working knowledge of the economic evaluation of the investment in R&D projects related to engineering or technological development. Three main topics concerning economic evaluation of R&D project are covered, evaluation of R&D project with deterministic cash flow, evaluation of R&D considering uncertaity, and R&D project selection. In particular, this course addresses on applications to case studies of industrial R&D projects.
Nuclear fuel cladding is a crucial structural material that largely affects the design, operation, and safety of a nuclear reactor. This short-term graduate discusses behavior of Zircaloy in Light Water Reactors (LWRs) and its implications in reactor design, operation, and spent fuel behavior. Along with in-depth discussion of Zircaloy behavior and microstructural characteristics, this course introduces notable research trends and key remaining unknowns of Zr-based fuel cladding materials.
This graduate course introduces in-depth discussion of Zircaloy cladding material's behavior during both steady states and accidents. The course is designed to equip graduate students with essential knowledge and skills to comprehensively understand integral aspects of nuclear fuel behavior and its implications on reactor design, operation, and safety.
This course will introduce distinct mechanical properties of nanostructural materials.
The course provides a theoretical basis of unique mechanical properties of nanostructural materials and their application. The course will also discuss the diverse methodologies of nanomechanical testing, simulation and characterization.
To learn the design, construction and analysis of post-tensioned concrete structures in a brief manner
The design and construction of post-tensioned structures are quite different from RC, steel, composite, timber or masonry structures. In this class, both pre-tensioned and post-tensioned concrete will be dealt with more of a focus on post-tension.
Fundamental understanding of 2D materials and their potential in electronic applications
This course is designed to provide background knowledge of two-dimensional (2D) nanomaterials, such as graphene, hexagonal boron nitride, and transition metal dichalcogenides, and introduce the related advanced researches and applications. The topics include fundamental properties, crystal structure, electronic band structure, growth mechanisms of 2D materials, analytical methods, and various device applications.
