Climate change. Renewable energy. Smart grids. Clean vehicles. Long-lasting batteries. By incorporating theory and applied engineering training this collaborative program is resourced through six School of Engineering departments and the Graduate School-New Brunswick, along with the Edward J. Bloustein School of Planning and Public Policy and the Rutgers Business School. Students are trained to solve real-life engineering problems in energy-related fields.
The Ph.D. curriculum balances directed research with coursework to prepare our graduates for careers in industry and academia whereas the M.S. program is designed to serve the needs of industrial chemists seeking to broaden and enrich their knowledge base.
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The graduate program is designed to give students a broad understanding of classical and modern physics, with intensive training in one of the frontier areas of modern research. A thesis of original research is required for Ph.D. students, to give the students experience in advancing themselves to the leading edge of an important area of physics. Students are encouraged to study several sub-disciplines of physics so that they will be prepared to apply their fundamental knowledge beyond the field of their thesis work.
The Master of Business and Science (MBS) degree Life Sciences track combines business courses with a concentration within Personal Care Science, Drug Discovery and Development, Biotechnology and Genomics, Global Food Technology and Innovation, and more.
In addition to a uniquely blended degree, students have the opportunity to take advantage of executive coaching, networking events, mentorships, internships and externships, and hands-on experiential learning.
The Biomedical Engineering Graduate Program is intended for promising students aiming to make original contributions to the field of biomedical engineering. We offer degrees that reflect individual student goals from career advancement to research-intensive. Our students receive outstanding graduate-level training from among six critical areas of biomedical engineering and technology, including:
• Biomaterials and Tissue Engineering
• Biomechanics and Rehabilitation Engineering