Online courses directory (2511)
This course examines different types of violent political conflict. It compares and contrasts several social science approaches (psychological, sociological, and political) and analyzes their ability to explain variation in outbreak, duration and outcome of conflict. Incidents such as riots in the U.S. during the 1960's, riots in India, the Yugoslav wars, and the Russian Revolution, as well as current international events are discussed.
This is the third course in the core physics curriculum at MIT, following 8.01 Physics I: Classical Mechanics and 8.02 Physics II: Electricity and Magnetism. Topics include mechanical vibrations and waves, electromagnetic waves, and optics. Students will learn about musical instruments, red sunsets, glories, coronae, rainbows, haloes, X-ray binaries, neutron stars, black holes and Big Bang cosmology.
Course Components
- Lecture Videos by MIT Physics Professor Walter Lewin
- Viewing Notes aligned with the lecture videos
- Concept Questions to gauge your understanding
- Problem Sets and Exams with Solutions
- Problem Solving Help Videos by MIT Physics Professor Wit Busza
This course is an intensive introduction to the U.S. law of intellectual property with major emphasis on patents, including what can be patented, the process of patent application, and the remedies for patent infringement.
This course links clean energy sources and storage technology to energy consumption case studies to give students a concept of the full circle of production and consumption. Specifically, photovoltaic, organic photovoltaic, piezoelectricity and thermoelectricity sources are applied to electrophoresis, lab on a chip, and paper microfluidic applications–relevant analytical techniques in biology and chemistry. Hands-on experimentation with everyday materials and equipment help connect the theory with the implementation. Complementary laboratories fabricating LEDs, organic LEDs and spectrometers introduce the diagnostic tools used to characterize energy efficiency.
This course is one of many OCW Energy Courses, and it is an elective subject in MIT’s undergraduate Energy Studies Minor. This Institute-wide program complements the deep expertise obtained in any major with a broad understanding of the interlinked realms of science, technology, and social sciences as they relate to energy and associated environmental challenges.
This course will begin with brief overview of what important current research topics are in oceanography (physical, geological, and biological) and how acoustics can be used as a tool to address them. Three typical examples are climate, bottom geology, and marine mammal behavior. Will then address the acoustic inverse problem, reviewing inverse methods (linear and nonlinear) and the combination of acoustical methods with other measurements as an integrated system. Last part of course will concentrate on specific case studies, taken from current research journals. This course is taught on campus at MIT and with simultaneous video at Woods Hole Oceanographic Institution.
This course describes how electronic, optical and magnetic properties of materials originate from their electronic and molecular structure and how these properties can be designed for particular applications. It offers experimental exploration of the electronic, optical and magnetic properties of materials through hands-on experimentation and practical materials examples.
This undergraduate course is a broad, theoretical treatment of classical mechanics, useful in its own right for treating complex dynamical problems, but essential to understanding the foundations of quantum mechanics and statistical physics.
This class provides a space for medical students and MD/PhD students, as well as HASTS (History, Anthropology, Science, Technology, and Society) PhD students to discuss social and ethical issues in the biosciences and biotechnologies as they are being developed. Discussions are with course faculty and with leading figures in developing technologies such as George Daley or George Church in stem cell or genomics research, Bruce Walker or Pardis Sabeti in setting up laboratories in Africa, Paul Farmer and Partners in Health colleagues in building local support systems and first world quality care in Haiti, Peru, and Rwanda, and Amy Farber in building patient-centered therapeutic-outcome research for critical but "orphan" diseases. Goals include stimulating students to think about applying their learning in Boston to countries around the world, including using the experiences they have had in their home countries or research experience abroad. Goals also include a mix of patient-doctor care perspectives from medical anthropology, and moving upstream in the research chain to questions of how to move discoveries from basic research through the pipelines into clinical and bedside care.
