Introduces natural and artificial nanomachines with an emphasis on their structure and design, mechanisms of operations, and function.
This course covers the fundamental properties and characterization techniques of nanomaterials, linking these scientific principles to real-world applications in fields like biomedicine, electronics, and the environment. It provides a translational perspective on nanoscience, preparing students for industry opportunities by connecting their studies to everyday technologies and future careers.
This course presents the fundamental techniques used in nanotechnology, including methods for nanofabrication, nanocharacterization and nanomanipulation with an emphasis on nanobiotechnology, biomedical and nanobiological application.
Initial research experience for all incoming nanoscience Ph.D. students. The goal of this course is to provide training in laboratory safety, basic laboratory techniques, oral and written communication, and review and criticism of scientific literature.
Covers the fundamental concepts in physics, chemistry and biology that are central to the interdisciplinary field of Nanoscience.Â
This course introduces the fundamental properties of nanomaterials and the techniques used to synthesize and characterize them. Students will learn how these unique properties enable a wide range of real-world applications in biomedicine, electronics, and environmental science.
This course explores the fundamental properties of nanomaterials, such as quantized energy levels and high surface-to-volume ratios and how they enable real-world applications in biomedicine, electronics, and environmental science. Students will also learn the essential techniques for synthesizing nanostructures and characterizing them using methods like electron microscopy.