Materials Science
In a world that consistently depends on scientific innovation to drive new technologies and services, it is impossible to ignore the necessity of new materials and fabrication techniques. Our Master of Science in materials science delivers an interdisciplinary background in the behavior and construction of materials rooted in engineering, chemistry and physics. Students develop a deep understanding of specializations within the field, with coursework branching into such topics as composites and nanomaterials.
To complement the coursework portion of the degree, students may undertake research to explore various topics within the major, working closely with faculty to examine new techniques and develop a deep understanding of the challenges inherent in materials fabrication. With your master's in hand, you'll be prepared to tackle research and development in a variety of engineering fields. You'll also be well-positioned to begin a PhD-level course of study if a career in academia is your goal.
In a world that consistently depends on scientific innovation to drive new technologies and services, it is impossible to ignore the necessity of new materials and fabrication techniques. Our MS in materials science delivers an interdisciplinary background in the behavior and construction of materials rooted in engineering, chemistry and physics. In addition to the breadth of our degree, students will have the chance develop a deep understanding of individual specializations within the field, with coursework branching into topics like composites and nanomaterials.
To complement the coursework portion of the degree, students may undertake research to explore various topics within the major, working closely with faculty to examine new techniques and develop a deep understanding of the challenges inherent in materials fabrication. An increasing number of technological fields are becoming materials-limited. With your master's in hand, you'll be prepared to tackle research and new materials development in a wide variety of those fields. You'll also be well-positioned to begin a PhD-level course of study if a career in academia is your goal.
Featured Courses
ENME 4400
Fatigue
About this Course
A detailed overview of fatigue. Topics include: stress life and strain life approaches, fracture mechanics, constant amplitude and spectrum loading, life prediction, fatigue at notches, microstructural effects, environmentally assisted fatigue, retardation and acceleration, multi-axial fatigue, design against fatigue and reliability. Cross listed with ENME 3400.
ENGR 4200
Introduction to Nanotechnology
About this Course
The most important recent accomplishments so far in the application of nanotechnology in several disciplines are discussed. Then a brief overview of the most important instrumentation systems used by nanotechnologists is provided. The nature of nanoparticles, nanoparticle composites, carbon nanostructures, including carbon nanotubes and their composites is subsequently discussed. The course also deals with nanopolymers, nanobiological systems, and nanoelectronic materials and devices. The issues of modeling of nanomaterials and nanostructures is also covered. Multiscale modeling based on finite element simulations, Monte Carlo methods, molecular dynamics and quantum mechanics calculations are briefly addressed. Most importantly, students should obtain appreciation of developments in nanotechnology outside their present area of expertise. Cross listed with ENGR 3200.
MTSC 4010
Mechanical Behavior of Materials
About this Course
Effects of microstructure on mechanical behavior of material; emphasis on recent developments in materials science, fracture, fatigue, creep, wear, corrosion, stress rupture, deformation and residual stress. Cross listed with MTSC 3010.
Application Information
Take the first step toward your academic career at the Ritchie School and start your application today.
Winter 2024 Final Deadline
