Spring 2026 Course Search

Building on structural and reactivity insights developed in Chemistry 1, this course delves into molecular structure and modern theories of bonding, especially as they relate to the reaction patterns of functional groups. We will focus on the mechanisms of reaction pathways and develop an understanding for how those mechanisms are experimentally explored. There will be numerous readings from the primary literature, including some classic papers that describe seminal experiments.

For students doing work-study or internships, we will focus on three core areas of professionalization. First, each week will journal our work weeks, discussing and sharing our work experiences in a round-table. Second, we will build our professionalization skills, especially networking (in person and on LinkedIn), resume writing, and doing practice interviews. Finally, we will work on writing 5-year plans, to help us figure out where we’d like to be a few years after graduation. More specifically

Following up on the fall course on web3, this course helps students learn to track transactions and actions across blockchains, which are large distributed censorship resistant databases. The course starts by exploring the fundamental nature of the blockchain: how data is stored, accessed, and traversed. It then introduces common patterns and software used for blockchain analytics.

An herbarium is a museum of pressed plants, a record of flora following a system that dates back to the 16th century. Large herbaria at institutions like D.C.’s Smithsonian National Museum of Natural History, Chicago’s Field Museum, Cambridge’s Harvard University, and London’s Kew Gardens contain millions of specimens, collected from around the world. But, most herbaria are small herbaria, with less than 10,000 specimens.

How can we create machines that think, learn, and solve problems? This course explores the fascinating field of artificial intelligence (AI), introducing the fundamental concepts, techniques, and ethical considerations that drive this rapidly evolving discipline.

Building upon your programming knowledge, you will explore key AI paradigms including search algorithms, evolutionary algorithms, swarm intelligence, and machine learning.  You will implement AI solutions to real-world problems, and gain an understanding of how to think about contemporary AI development.

The cell is the fundamental organizational unit of all living organisms on Earth. In this class we will investigate cell structure and function, learn about DNA replication and transcription, find out how proteins are synthesized, folded, localized, and regulated, ultimately coming to understand how interfering with cell biological processes can result in disease.  In the lab, students will gain experience with tools and methodologies pertinent to cell biology concepts, as well as techniques used in resear

The cells in our bodies need to grow and divide in order to make new tissue, and to repair or replace damaged tissue.  The processes that govern cell growth and division are tightly regulated. When the cells that comprise the tissues of our bodies lose the ability to properly regulate their growth and proliferation, cancer is the result.  This introductory level course will provide an overview of the basic mechanisms and genetics underlying human cancers, as well as explore current diagnostic and therapeutic strategies.

Theoretical Ethics aims to uncover the sources of moral knowledge and the foundations of moral obligation. You will engage in a detailed reading of two classical moral theories and study contemporary interpretations and applications of these theories. You will be expected to contribute substantially to class discussion, write two essays and present a draft of your final essay to the class.

Everything is geometry! This class is about two things: first, about how mathematicians have extended the concept of "geometry" beyond triangles and circles, into higher-dimensional spaces, curved spaces, spaces of functions, discrete spaces, and more. Second, about how this extension of "geometry" can allow us to apply our powerful geometric intuition to a wide range of problems that might not initially seem geometric, both within mathematics, and in physics, computer science, and elsewhere.

Discrete mathematics studies problems that can be broken up into distinct pieces. Some examples of these sorts of systems are letters or numbers in a password, pixels on a computer screen, the connections between friends on Facebook, and driving directions (along established roads) between two cities. In this course we will develop the tools needed to solve relevant, real-world problems. Topics will include: combinatorics (clever ways of counting things), number theory and graph theory. Possible applications include probability, social networks, optimization, and cryptography.

Feminism imagines a world free of gender-based oppression and injustice. But what exactly does such freedom involve? In this course, we’ll investigate the interplay between gender, feminist theory, and philosophical views about freedom. Some prompting questions include: Is individual freedom enough? What does ubiquitous pornography mean for sexual freedom? How does politics shape desire? (How) should we rethink the family and work? Does feminist freedom require freedom from gender?

Why would a forest ecology course include an assignment to knit a wool hat? In this class we will explore the lasting impact of sheep on the Vermont landscape, from the earliest settler-colonizers through today’s small batch fiber mills and second growth forests studded with stone walls. Sheep, and especially a 19th century boom in merino sheep, radically altered Vermont’s forests and inspired early writing on conservation and sustainable land management.

In this course, students will gain experience with using simple programmable robots and how they can be utilized in STEM education. The focus of this class will be on learning and designing lessons for K-12 students utilizing these robots. This class is accessible for students at all levels of computer programming experience (including none). 

Introduction to Computer Science 2 continues the design-recipe approach started in Introduction to Computer Science 1. We extend our toolkit from structural recursion into generative recursion, abstraction, and algorithmic problem-solving. Students move beyond simple data definitions to work with more sophisticated structures (trees, graphs, sets, maps) while beginning to reason about program efficiency and resource use.

Hannah Arendt (1906-1975) was a political theorist whose work has become increasingly influential in recent years. A student of Martin Heidegger and Karl Jaspers, her extensive writings cover such topics as the nature of power, the meaning of the political, and the problem of revolution. This course is a detailed exploration of some of her major works, including The Human Condition, On Revolution, and Eichmann in Jerusalem: A Report on the Banality of Evil, as well as an engagement with some of the critical literature on her work.

This course is an introduction to the theory of knowledge in the analytical tradition. We will engage with topics such as skepticism about the external world, the nature of belief, truth, and justification, as well as foundationalism and coherentism,, internalism versus externalism, along with other topics.

John Rawls (1921-2003) was arguably the most important and influential political philosopher of the twentieth century. His first major work, A Theory of Justice (1971) transformed the field of political philosophy and his ideas and arguments remain at the center of the philosophical debate on the question of justice. This course consists of a careful study of the main arguments in his early and late work as well as a consideration of some of the critical literature.

The Tuning in the Trees is an advanced seminar in microtonality that treats tuning systems as both technical structures and living landscapes. Students will explore how musical intervals emerge from natural patterns—such as tree bifurcations, harmonic ratios, and number sequences—while engaging deeply with Just intonation, Meantone, Bohlen–Pierce, and other non-Western tunings.

Aristocles (known to us as "Plato") lived and wrote in Athens in the 5th c. BCE. More than 2400 years later, Alfred North Whitehead’s famous remark still resonates: “The safest general characterization of the European philosophical tradition is that it consists of a series of footnotes to Plato…the wealth of general ideas scattered through them…have made [Plato’s] writings an inexhaustible mine of suggestion” (Process and Reality, 1929).