Materials Science and Engineering
Depletion of traditional fuels and the exponential increase in energy demand will make energy resources an important issue worldwide. The interactions between the human activities in the field of energy had become crucial. Excessive consumption of energy requires innovation and development of systems to utilize the available energy resources efficiently. This will ensure the optimal utilization of available resources, preserve the environment, and create new investment opportunities. Tools for addressing such situations include, but not limited to, Renewable Energy Systems, Alternative Fuels with appropriate developments in combustion systems, Fuel Cells Technologies, Energy Storage Systems and Energy Conversions and Management. The program offered by Department of Energy Recourses Engineering is a unique direction among Egyptian Universities and will contribute to the understanding of the above subjects and the national income.
The vision for the Department of Energy Resources Engineering is to be a national and international pioneering and referential offered program in innovation, adaptation, and development of energy conversion technologies through advanced working systems with high efficiency. Graduates of this program will meet the challenges of the growing energy demands without jeopardizing the environment.
The mission of the Department of Energy Resources Engineering is to prepare students well acquainted with the basics and the advances in theoretical and practical knowledge, research tools and acquiring professional skills development to tackle the current energy crisis with high efficient systems. This is to build an advanced collaborative system for adapting, developing energy technologies through promoting an effective research and development culture. Moreover, is to formulate comprehensive and competitive solutions, developing expertise, and high-qualified human resources. This will lead to the support of the national green economy and sustainable development , Renewable Energy Systems, Alternative Fuels with appropriate developments in combustion systems, Fuel Cells Technologies, Energy Storage Systems and Energy Resources Conversion and Management.
To prepare graduates able to interact with the community towards more utilization of new and renewable sources of energy with efficient systems.
To prepare creative graduates to design, manage, build, operate, and maintain energy converting equipment and energy utilization systems without harm to the environment.
To prepare qualified graduates that can apply latest technologies for the improvement of life quality. By considering and addressing energy resources with emphasis on national and international resources with associated problems.
To give an equal opportunity for students from any country to enroll into that unique energy resources engineering program.
To establish strong and effective co-operation with different national and international research institutes, centers, universities and industries relevant to energy and its applications.
To develop an integrated teamwork interacting with other members from different E-JUST programs (Interdisciplinary research work).
M.Sc. students must complete a total of at least 36 credit hours, within the following guidelines:
Course work of 18 credit hours, including 6-credit hours core courses, 9-credit hours elective courses and 3-credit hours Project-Based Learning course.
Thesis work of 18 credit hours .
M.Sc. students have to pass successfully six courses with three credit hours each.
MSE 501 – Materials Properties and Chemical Changes
MSE 502 – Phase Equilibrium and Transformation
The student has to select three courses from the following group or from any other graduate program, according to the recommendations of the academic advisor.
MSE 503 – Microstructural Analysis of Solids
MSE 504 – Electronic and Photonic Properties of Materials
MSE 505 – Polymers Science and Engineering
MSE 506 – Advanced Dynamics of Materials
MSE 507 – Advanced Testing and Characterization Techniques
MSE 508 – Modelling and Simulation
MSE 509 – Advanced Mechanics of Materials I
MSE 510 – Finite element Modelling and Simulation
MSE 511 – Thin Film materials Technology.
MSE 512 – Applied Physical Metallurgy
Project-Based Learning Courses:
M.Sc. students have to participate in the following team work project which is based on self-learning; Students have to present innovative concepts and competitive solutions. The total credits of the course are three.
MSE 701- Project Based Learning in Materials Development, Characterization and Integration in Engineering Systems.
The M.Sc. candidate should prepare and defend a Thesis based on a high-valued research work in one research topic in the fields of Materials Science and Engineering.
MSE 801 – M. Sc. Thesis
Ph.D. students must complete a total of at least 48 credit hours, within the following guidelines:
– Course-work of 18 credit hours, including four elective courses of 12 credit hours, selected from the following group or from any other graduate program, according to the recommendations of the academic advisor and research seminar courses of 6 credit hours.
– Thesis work of 30 credit hours.
Ph.D. students have to pass successfully six courses with three credit hours each.
The student has to select four courses (3 – credit hours each) from the following group or from any other graduate program, according to the recommendations of the principal supervisor.
MSE 601 – Composite and Fiber Materials
MSE 602 – Surface Science and Corrosion
MSE 603 – High Performance Ceramics and Glasses
MSE 604 – Advanced Semiconductors
MSE 605 -Solid-state and Thin-film Reaction Kinetics
MSE 606 – Nano-materials and Nanotechnology
MSE 607- Biomedical Materials
MSE 608 – Materials for Photovoltaic Devices
MSE 609 – Magnetic and Superconducting Materials
MSE 610 -Active and Sensing Materials
MSE 611 – Fuel Cells, Batteries and Supercapacitors
MSE 612 – Advanced Mechanics of Materials II
MSE 613- Advanced Materials Thermodynamics
MSE 614 – Strength, Fracture, and Fatigue of Materials
MSE 615- Multi-Scale Analysis and Multi-physics Constitutive Modelling
Advanced Research Seminar Courses:
Ph.D. students have to participate in two of the following seminars activities which are based on self-learning and presentations of new advanced topics in her/his discipline. The total credit hours of the seminars are six.
MSE 702- Seminar on Advanced topics of Materials Science and Technology.
MSE 703 -Seminar on Advanced topics and progress in the research project of the students.
The Ph.D. candidate should prepare and defend a Thesis based on a high-valued research work in one research topic in the fields Materials Science and Engineering.
The Thesis should present a new contribution (s) in the respective field of research.
MSE 802 – Ph.D. Thesis