![]() ![]() A working knowledge of both integral and differential calculus is assumed. Selected topics from upper-division undergraduate courses in electricity and magnetism, thermodynamics, and quantum mechanics will be reviewed as required. A basic familiarity with topics usually covered in a two-semester college course in introductory physics is assumed. energy bands, density-of-states, Fermi functions, doping etc.). No familiarity with thermoelectric theory or technology is assumed, but an introductory level understanding of solid-state physics is necessary (e.g. This course follows the nanoHUB-U philosophy of aiming to be as broadly accessible as possible to those with a background in the physical sciences or engineering. The course should be useful for advanced undergraduates, beginning graduate students as well are researchers and practicing engineers and scientists seeking an understanding of basic concepts and how these concepts are translated into practical devices. Thermoelectric devices are being used in a growing number of applications such as energy harvesting and precision cooling. The course also provides experts on thermoelectric science and technology with a new perspective. The course is taught at the level of a Purdue University course for undergraduate seniors or first year graduate students. System requirements for electronics cooling and for large scale direct heat to electricity conversion in waste heat recovery and topping cycle applications, and trade-offs beyond material’s thermoelectric figure-of-merit, in terms of the heat sink requirements, thermal stress, material usage and overall cost will be briefly introduced. ![]() Online simulations using nanoHUB will illustrate transport in realistic TE materials and energy balance in thermoelectric devices. The following 3 units introduce latest nanoscale and macroscale characterization techniques, the design of thermoelectric systems, and recent advances in nanoengineered thermoelectric materials and physics. Landauer formalism provides a unified framework to study both electron and phonon transport. The first two units of the course introduce this new perspective and connects it to the traditional treatment of thermoelectric science. Intuition about thermoelectric relations and efficiency limits are obtained by studying a single atom. He is a 2013 Henry Crown Fellow and a member of the Aspen Global Leadership Network.This self-paced course aims to introduce students to the thermoelectric theory and applications using a unique, “bottom up” approach to carrier transport that has emerged from research on molecular and nanoscale electronics. Mark earned his Economics MPhil from Oxford, as a Rhodes Scholar, and an MBA from MIT's Sloan School as a Leaders for Manufacturing Fellow. Mark is a former ski racer and pilot and has sixteen patents. Mark served on the Board of Directors of MIT and today he serves on the advisory board of the Columbia University Center on Global Energy Policy and is a member of the Council on Foreign Relations. He was on the start-up team at Teledesic, building the world's first satellite- based global broadband internet, and worked at NASA/JPL and Boeing. Mark also founded wireless software provider Ripcord Systems (SoftBank). (CYMI), which made piezoelectric systems to control vibrations. Prior to BioScale, Mark co-founded Active Control eXperts, Inc. Previously, Mark founded BioScale, which is transforming chronic disease management through novel bioclinical analytics and digital health technologies. Radia is building global energy projects using GigaWind. Most recently, Mark founded and is CEO of Radia, Inc. Mark is a serial cross-industry entrepreneur, having co-founded companies in material science, satellite communications, software, bioscience, energy/environment, and aerospace.
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