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This foundational class covers modes of reasoning used in quantitative sciences and mathematics. While learning the art of mathematical modeling, i.e. translating the physical systems/real-life situations into mathematics, we will apply problem solving and practice effective communication of mathematics.

Differential equations are a powerful and pervasive mathematical tool in the sciences and are fundamental in pure mathematics as well. Almost every system whose components interact continuously over time can be modeled by a differential equation, and differential equation models and analyses of these systems are common in the literature in many fields including physics, ecology, biology, astronomy, and economics.

I would (and will) argue that Newton's Principia is the most important book yet written. It is certainly the most important book that a vanishingly small number of people have actually read.

This course will serve as an introduction to working with circuits in a lab setting. We will learn about the relatively simple rules necessary for working with analog circuits and how those rules can be used to build objects of growing complexity. We will then move on to understanding how to build circuits that can measure properties of and interact with their surroundings.

Scanning electron microscopes are a fundamental tool in the physical and life sciences. When equipped with an X-Ray spectrometer, a SEM can provide rapid physical and chemical data of specimens on extremely small scales. This class with cover the theory and practical applications of SEM imaging and analysis for advanced science students who have their own research interests. Students will be expected to develop and conduct an independent research project through this class.

In this course, students will learn the fundamentals of observing the night sky with a telescope. This course will teach how to find the basic constellations and how to use both manual and computerized telescopes to point at celestial objects in the night sky. While there will be some classroom time to teach fundamental concepts, the vast majority of the class will consist of practical, hands-on time with telescopes at Stickney Observatory.

Physics is the study of what Newton called “the System of the World.” To know the System of the World is to know what forces are out there and how those forces operate on things. These forces explain the dynamics of the world around us: from the path of a falling apple to the motion of a car down the highway to the flight of a rocket from the Earth. Careful analysis of the forces that govern these motions reveal countless insights about the world around you and enable you to look at that world with new eyes.

Together with calculus, linear algebra is one of the foundations of higher-level mathematics and its applications. This is NOT just the algebra you know from high school. There are several perspectives one can take on linear algebra: it is a method for handling large systems of linear equations, it is a theory of linear geometry (including in dimensions larger than three), it is matrix algebra, and it is a theoretical structure that appears throughout mathematics, physics, computer science, and statistics.

In the eighteenth and nineteenth centuries, mathematics underwent a vast expansion, into new, exciting, and increasingly counter-intuitive realms. The subject risked mystification and mutual incomprehensibility between experts in different sub-fields. In the first part of the twentieth century, a group of French mathematicians, under the pseudonym Bourbaki, undertook an ultimately successful program to use the foundation of set theory to put all of mathematics onto a common conceptual and logical foundation.

The comforts and amenities of modern life require vast inputs of energy to power an industrial society. While the benefits of industrial society are significant, if unevenly shared, the environmental costs of energy extraction and production are significant. These environmental costs are also unevenly shared.

This is an introductory course to international public law and its relevance in today’s complex and interconnected world. 

This is an advanced improvisation class for students from all disciplines. We will learn the concepts of complexity and advance our skills in pattern recognition, self-organization, emergent structuring, and development of movement, verbal, visual and design vocabularies. Collaborative processes will be explored to further different forms of creative practices, both to address an artistic practice and a dialogic practice.

This class will examine the current diplomacy and process of a new Convention for the United Nations on Conserving the River Deltas. We will hear from some of the lead partners on the project: The Transboundary Water In-Cooperation Network (TWIN), co-founded by CAPA and the Institute for Environmental Diplomacy and Security at the University of Vermont, and the African Centre for Climate Action and Rural Development (ACCARD) directed by Freeman Oluohor.

In this class we will explore the practice of meditation as a physical and mental training exercise. In class meditation and discussion, as well as outside reading and writing assignments, will explore Eastern and Western persepctives on ourselves and the world.

Sustainable development has been defined as development that meets the needs of the present without compromising the ability of future generations to meet their own needs. It calls for concerted efforts towards building an inclusive, sustainable, and resilient future for people and planet. For sustainable development to be achieved, it is crucial to harmonize three core elements: economic growth, social inclusion, and environmental protection. Ending poverty in all forms is vital.