This is the third and last term of the quantum field theory sequence. The course is devoted to the standard model of particle physics, including both its conceptual foundations and its specific structure, and to some current research frontiers that grow immediately out of it.

This course is the third and last term of the quantum field theory sequence. Its aim is the proper theoretical discussion of the physics of the standard model. Topics include: quantum chromodynamics; the Higgs phenomenon and a description of the standard model; deep-inelastic scattering and structure functions; basics of lattice gauge theory; operator products and effective theories; detailed structure of the standard model; spontaneously broken gauge theory and its quantization; instantons and theta-vacua; topological defects; introduction to supersymmetry.

This course, which concentrates on special relativity, is normally taken by physics majors in their sophomore year. Topics include Einstein’s postulates, the Lorentz transformation, relativistic effects and paradoxes, and applications involving electromagnetism and particle physics. This course also provides a brief introduction to some concepts of general relativity, including the principle of equivalence, the Schwartzschild metric and black holes, and the FRW metric and cosmology.

Relativity Lite is designed for the General Astronomy sequence (PH 361-2U, SCI 315-6U) whose primary book glosses over Special Relativity and General Relativity while trying to explain the Cosmology that is based on those subjects. Relativity Lite translates the mathematical equations conventional relativity texts rely upon into pictures that are readily understood and contain within them the mathematical essentials. This book provides the comprehensive coverage needed to understand, in sufficient depth, these three linked areas of our reality.

Readers seeking this knowledge on their own, and those in other courses for nonscientists, may also find it helpful.

This is a set of lecture notes for my course Relativity for Poets at Fullerton College. It's a nonmathematical presentation of Einstein's theories of special and general relativity, including a brief treatment of cosmology.

This introductory book on Remote Sensing is intended to be the equivalent of a textbook for an undergraduate-level university course. There is also a French version titled "Télédétection".

Open Educational Resources (OER)
Resources for finding open and sustainable teaching and learning materials.

STS.467 examines the intellectual foundations of archaeology in the deep sea. The course explores the current convergence of oceanography, archaeology, and engineering which allows scientists to discover, survey, and excavate shipwrecks in deep water with robots and submarines. The course seeks to address the following questions: How are new devices best employed for archaeological work? How do new capabilities (e.g. higher frequencies, higher resolution, all digital data output) change operations plans and research designs? What new technologies will be required? Area studies focus on the Aegean in Minoan times and western Sicily during Phoenician, Greek, and Roman hegemony.

Review of Body Physics: Motion to Metabolism
https://drive.google.com/open?id=16jrHD0riHntxhTOX2lCigZY9Ptqc20GsBQP4DXgaGAo

GIS Fundamentals, 6th Edition
https://www.paulbolstad.net/gisbook.html

Introduction to Ocean Science
https://reefimages.com/oceansci.php

Through five lessons, students are introduced to all facets of the rock cycle. Topics include rock and mineral types, material stresses and weathering, geologic time and fossil formation, the Earth's crust and tectonic plates, and soil formation and composition. Lessons are presented in the context of the related impact on humans in the form of roadway and tunnel design and construction, natural disasters, environmental site assessment for building structures, and measurement instrumentation and tools. Hands-on activities include experiencing tensional, compressional and shear material stress by using only hand force to break bars of soap; preparing Jeopardy-type trivia questions/answers for a class game that reinforces students' understanding of rocks and the rock cycle; creating "fossils" using melted chocolate; working within design constraints to design and build a model tunnel through a clay mountain; and soil sampling by creating tools, obtaining soil cores, documenting a soil profile log, and analyzing the findings to make engineering predictions.

This class focuses on chemical rocket propulsion systems for launch, orbital, and interplanetary flight. It studies the modeling of solid, liquid-bipropellant, and hybrid rocket engines. Thermochemistry, prediction of specific impulse, and nozzle flows including real gas and kinetic effects will also be covered. Other topics to be covered include structural constraints, propellant feed systems, turbopumps, and combustion processes in solid, liquid, and hybrid rockets.

Students learn how and why engineers design satellites to benefit life on Earth, as well as explore motion, rockets and rocket motion. Through six lessons and 10 associated hands-on activities, students discover that the motion of all objects everything from the flight of a rocket to the movement of a canoe is governed by Newton's three laws of motion. This unit introduces students to the challenges of getting into space for the purpose of exploration. The ideas of thrust, weight and control are explored, helping students to fully understand what goes into the design of rockets and the value of understanding these scientific concepts. After learning how and why the experts make specific engineering choices, students also learn about the iterative engineering design process as they design and construct their own model rockets. Then students explore triangulation, a concept that is fundamental to the navigation of satellites and global positioning systems designed by engineers; by investigating these technologies, they learn how people can determine their positions and the locations of others.

Learn from the experience of the Netherlands-based “Room for the River” program devising sustainable river and delta solutions in times of climate change.

With a long history of disasters and years of dealing with the challenges posed by water, the Netherlands has accumulated essential knowledge about water management and specifically of rivers. This course will share with you this knowledge gleaned over more than a decade under the Dutch government’s “Room for the River” program, started in 2007. The goal of this program was to manage higher water levels in rivers, while restoring the river’s natural flood plain in places where it is least harmful in order to protect those areas that need protection. All this in the context of the changing characteristics of rivers in times of climate change.

While the practical experience gained from this program is derived from cases in the Netherlands, it also applies to other countries that build their social, ecological and economic prosperity on what rivers bring them. It will be most beneficial for water managers, river engineers, landscape designers and policy makers who seek more knowledge surrounding analysis, design and development of river and delta solutions.

The specific skills gained in this course are in the design of engineering interventions; stakeholder analysis and balancing economic benefits with safe living conditions, ecological quality and attractive landscapes. You will also understand the impact of climate change and will be introduced to approaches to deal with the long-term dynamics and uncertainties that rivers bring.

We offer you the opportunity to learn from our experiences and apply it on your own river and we also aim to learn from you. The course is structured as an exchange, with a strong focus on analysis and design.

This project looks to combine the legacies of these three titans of American history, including Theodore Roosevelt, Franklin Roosevelt, and Eleanor Roosevelt, to develop policy priorities and an action plan that will enable us to move beyond the false choice of economic growth or environmental security.

How can we translate real-world challenges into future business opportunities? How can individuals, organizations, and society learn and undergo change at the pace needed to stave off worsening problems? Today, organizations of all kinds—traditional manufacturing firms, those that extract resources, a huge variety of new start-ups, services, non-profits, and governmental organizations of all types, among many others—are tackling these very questions. For some, the massive challenges of moving towards sustainability offer real opportunities for new products and services, for reinventing old ones, or for solving problems in new ways. The course aims to provide participants with access and in-depth exposure to firms that are actively grappling with the sustainability-related issues through cases, readings and guest speakers.

The Software Tools for Academics and Researchers (STAR) program at MIT seeks to bridge the divide between scientific research and the classroom. Understanding and applying research methods in the classroom setting can be challenging due to time constraints and the need for advanced equipment and facilities. The multidisciplinary STAR team collaborates with faculty from MIT and other educational institutions to design software exploring core scientific research concepts. The goal of STAR is to develop innovative and intuitive teaching tools for classroom use.
All of the STAR educational tools are freely available. To complement the educational software, the STAR website contains curriculum components/modules which can facilitate the use of STAR educational tools in a variety of educational settings. Students, teachers, and professors should feel welcome to download software and curriculum modules for their own use.
Online Publication