This course covers the fundamental concepts that determine the electrical, optical, magnetic and mechanical properties of metals, semiconductors, ceramics and polymers. The roles of bonding, structure (crystalline, defect, energy band and microstructure) and composition in influencing and controlling physical properties are discussed. Also included are case studies drawn from a variety of applications: semiconductor diodes and optical detectors, sensors, thin films, biomaterials, composites and cellular materials, and others.

This is an advanced course on modeling, design, integration and best practices for use of machine elements such as bearings, springs, gears, cams and mechanisms. Modeling and analysis of these elements is based upon extensive application of physics, mathematics and core mechanical engineering principles (solid mechanics, fluid mechanics, manufacturing, estimation, computer simulation, etc.). These principles are reinforced via (1) hands-on laboratory experiences wherein students conduct experiments and disassemble machines and (2) a substantial design project wherein students model, design, fabricate and characterize a mechanical system that is relevant to a real world application. Students master the materials via problems sets that are directly related to, and coordinated with, the deliverables of their project. Student assessment is based upon mastery of the course materials and the student’s ability to synthesize, model and fabricate a mechanical device subject to engineering constraints (e.g. cost and time/schedule).

This course provides an introduction to the fundamental principles and techniques of software development that have greatest impact on practice. Topics include capturing the essence of a problem by recognizing and inventing suitable abstractions; key paradigms, including state machines, functional programming, and object-oriented programming; use of design patterns to bridge gap between models and code; the role of interfaces and specification in achieving modularity and decoupling; reasoning about code using invariants; testing, test-case generation and coverage; and essentials of programming with objects, functions, and abstract types. The course includes exercises in modeling, design, implementation and reasoning.

This course is a computationally focused introduction to elliptic curves, with applications to number theory and cryptography. While this is an introductory course, we will (gently) work our way up to some fairly advanced material, including an overview of the proof of Fermat’s last theorem.

This course surveys the social, cultural, and political development of western Europe between 500 and 1350. A number of topics are incorporated into the broad chronological sweep of the course, including: the Germanic conquest of the ancient Mediterranean world; the rise of a distinct northern culture and the Carolingian Renaissance; the emergence of feudalism and the breakdown of political order; contact with the Byzantine and Islamic East and the Crusading movement; the quality of religious life; the vitality of the high medieval economy and culture; and the catastrophes of the fourteenth century.

This course will focus on providing students with the tools needed to practice responsible architecture in a contemporary context. It will familiarize students with the materials currently used in responsible practice, as well as the material properties most relevant to assembly. The course will also introduce students to materials that are untested but hold promise for future usage. Finally, the course will challenge students to refine their understanding of responsible or sustainable design practice by looking at the evolution of those ideas within the field of architecture.

This course is premised on the belief that emotions are a fundamental part of human nature. Accordingly, understanding emotions and incorporating emotions into our research can help us better explain variation in important political phenomena. Research on emotions and how emotions can influence decision-making has dramatically increased over the past two decades. This class aims to pick up on new findings from psychology and other disciplines and marshal this knowledge toward the most important issues of political science.

This course is an investigation of the Roman empire of Augustus, the Frankish empire of Charlemagne, and the English empire in the age of the Hundred Years War. Students examine different types of evidence, read across a variety of disciplines, and develop skills to identify continuities and changes in ancient and medieval societies. Each term this course is different, looking at different materials from a variety of domains to explore ancient and mideveal studies. This version is a capture of the course as it was taught in 2012, and does not reflect how it is taught currently.

This subject offers a broad survey of texts (both literary and philosophical) drawn from the Western tradition and selected to trace the growth of ideas about nature and the natural environment of mankind. The term nature in this context has to do with the varying ways in which the physical world has been conceived as the habitation of mankind, a source of imperatives for the collective organization and conduct of human life. In this sense, nature is less the object of complex scientific investigation than the object of individual experience and direct observation. Using the term “nature” in this sense, we can say that modern reference to “the environment” owes much to three ideas about the relation of mankind to nature. In the first of these, which harks back to ancient medical theories and notions about weather, geographical nature was seen as a neutral agency affecting or transforming agent of mankind’s character and institutions. In the second, which derives from religious and classical sources in the Western tradition, the earth was designed as a fit environment for mankind or, at the least, as adequately suited for its abode, and civic or political life was taken to be consonant with the natural world. In the third, which also makes its appearance in the ancient world but becomes important only much later, nature and mankind are regarded as antagonists, and one must conquer the other or be subjugated by it.

This course will explore how Americans have confronted energy challenges since the end of World War II. Beginning in the 1970s, Americans worried about the supply of energy. As American production of oil declined, would the US be able to secure enough fuel to sustain their high consumption lifestyles? At the same time, Americans also began to fear the environmental side affects of energy use. Even if the US had enough fossil fuel, would its consumption be detrimental to health and safety? This class examines how Americans thought about these questions in the last half-century. We will consider the political, diplomatic, economic, cultural, and technological aspects of the energy crisis. Topics include nuclear power, suburbanization and the new car culture, the environmental movement and the challenges of clean energy, the Middle East and supply of oil, the energy crisis of the 1970s, and global warming.

This course examines the choices and constraints regarding sources and uses of energy by households, firms, and governments through a number of frameworks to describe and explain behavior at various levels of aggregation. Examples include a wide range of countries, scope, settings, and analytical approaches.
This course is one of many OCW Energy Courses, and it is a core 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 explores the theoretical and empirical perspectives on individual and industrial demand for energy, energy supply, energy markets, and public policies affecting energy markets. It discusses aspects of the oil, natural gas, electricity, and nuclear power sectors and examines energy tax, price regulation, deregulation, energy efficiency and policies for controlling emission.

With increasing public awareness of the multiple effects of global environmental change, the terms water, energy, and food crisis have become widely used in scientific and political debates on sustainable development and environmental policy. Although each of these crises has distinct drivers and consequences, providing sustainable supplies of water, energy, and food are deeply interrelated challenges and require a profound understanding of the political, socioeconomic, and cultural factors that have historically shaped these interrelations at a local and global scale.

Understanding the energy needs and market opportunities in the specific off-grid community or region is the first step for effectively selecting and implementing the solutions to meet a community’s energy needs. MIT D-Lab has developed the Energy Assessment Toolkit to guide organizations through the process of gathering the information needed to make informed decisions about what technologies and business models are best suited to meet the specific needs of their community through market-based initiatives. 
This toolkit is designed for any organization that has an on­-the­-ground presence in an off­-grid community or region and has the ability to take action based on the opportunities identified. This community-­based assessment approach is not intended to replace studies that track energy access on a national level or to generate market intelligence reports for external organizations looking to expand their business or programs into new markets.

A survey of how America has become the world’s largest consumer of energy. Explores American history from the perspective of energy and its relationship to politics, diplomacy, the economy, science and technology, labor, culture, and the environment. Topics include muscle and water power in early America, coal and the Industrial Revolution, electrification, energy consumption in the home, oil and U.S. foreign policy, automobiles and suburbanization, nuclear power, OPEC and the 70’s energy crisis, global warming, and possible paths for the future.

This course proposes that most cities have neither the infrastructure nor the processes in place to support the demographically complex public in fulfilling its role in democracy. Through this course, participants will learn a set of design principles for creating public engagement practices necessary for building inclusive civic infrastructure in cities. Participants will also have the opportunity to review and practice strategies, techniques, and methods for engaging communities in demographically complex settings.

This course is a detailed technical and historical exploration of the Apollo project to “fly humans to the moon and return them safely to earth” as an example of a complex engineering system. Emphasis is on how the systems worked, the technical and social processes that produced them, mission operations, and historical significance. Guest lectures are featured by MIT-affiliated engineers who contributed to and participated in the Apollo missions. Students work in teams on a final project analyzing an aspect of the historical project to articulate and synthesize ideas in engineering systems.

This multidisciplinary seminar addresses fundamental issues in global health faced by community-based healthcare programs in developing countries. Students will broadly explore topics with expert lecturers and guided readings. Topics will be further illuminated with case studies from healthcare programs in urban centers of Zambia. Multidisciplinary teams will be formed to develop feasible solutions to specific health challenges posed in the case studies and encouraged to pursue their ideas beyond the seminar. Possible global health topics include community-based AIDS/HIV management, maternity care, health diagnostics, and information technology in patient management and tracking. Students from Medicine, Public Health, Engineering, Management, and Social Sciences are encouraged to enroll. No specific background experience is expected, but students should have some relevant skills or experiences.

This course provides students with an opportunity to conceive, design and implement a product, using rapid prototyping methods and computer-aid tools. The first of two phases challenges each student team to meet a set of design requirements and constraints for a structural component. A course of iteration, fabrication, and validation completes this manual design cycle. During the second phase, each team conducts design optimization using structural analysis software, with their phase one prototype as a baseline.
Acknowledgements
This course is made possible thanks to a grant by the alumni sponsored Teaching and Education Enhancement Program (Class of ‘51 Fund for Excellence in Education, Class of ‘55 Fund for Excellence in Teaching, Class of ‘72 Fund for Educational Innovation). The instructors gratefully acknowledge the financial support.
The course was approved by the Undergraduate Committee of the MIT Department of Aeronautics and Astronautics in 2003. The instructors thank Prof. Manuel Martinez-Sanchez and the committee members for their support and suggestions.

This course provides students with an opportunity to conceive, design and implement a product, using rapid prototyping methods and computer-aid tools. The first of two phases challenges each student team to meet a set of design requirements and constraints for a structural component. A course of iteration, fabrication, and validation completes this manual design cycle. During the second phase, each team conducts design optimization using structural analysis software, with their phase one prototype as a baseline.
Acknowledgements
This course is made possible thanks to a grant by the alumni sponsored Teaching and Education Enhancement Program (Class of ‘51 Fund for Excellence in Education, Class of ‘55 Fund for Excellence in Teaching, Class of ‘72 Fund for Educational Innovation). The instructors gratefully acknowledge the financial support. The course was approved by the Undergraduate Committee of the MIT Department of Aeronautics and Astronautics in 2003. The instructors thank Prof. Manuel Martinez-Sanchez and the committee members for their support and suggestions.