Spring 2026 Course Search

Historical Dress: The Park-McCullough Project Spring ‘26

Genesis is the first book in a compilation known collectively as the Bible. It is a text of enormous literary value, and one of our earliest historical chronicles, providing foundational material for Judaism, Christianity, and Islam. Yet how many of us know what it actually says?  How did it come together, what is the narrative, and how does it relate to ideas, cultures, and events in the ancient world? We will not be considering Genesis in terms of its status as scripture.

The aim of this course is to think about books. Not just books as objects, but books as the signifiers of a wealth of relationships – between reading and writing, between people and ideas, between people and people, between technologies and desires. For centuries, our ideas have been shaped by the rhythms and hierarchies inherent in the nature of print.  But the nature of the book itself has changed enormously over time – from the painstaking creation of ancient papyri and scrolls to Gutenberg and the fifteenth-century printing revolution.

This course covers the breadth of university calculus: differentiation, integration, infinite series, and ordinary differential equations. It focuses on concepts and interconnections. In order to cover this much material, computational techniques are de-emphasized. The approach is historically based and classical, following original texts where possible.

Multivariable calculus is one of the core parts of an undergraduate mathematics curriculum. Introductory calculus mostly concentrates on situations where there is one input and one output variable; multivariable extends differentiation, integration, and differential equations to cases where there are multiple input and output variables. In this way, multivariable calculus combines calculus and linear algebra; the subject can also be called vector and matrix calculus.

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.

In this course, we will focus on developing the statistical skills needed to answer questions by collecting data, designing experimental studies, and analyzing large publicly available datasets. The skills learned will also help students to be critical consumers of statistical results. We will use a variety of datasets to develop skills in data management, analysis, and effective presentation of results.

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.

How does influence travel from one thing to another? In Newton’s mechanics of particles and forces, influences travel instantaneously across arbitrarily far distances. Newton himself felt this to be incorrect, but he did not suggest a solution to this problem of “action at a distance.” To solve this problem, we need a richer ontology: The world is made not only of particles, but also of fields. As examples of the field concept, we study the theory and applications of the electric field and the magnetic field.

Throughout history, people have played games — games of chance and games of skill. Many of us grew up playing all kinds of different games, and most of those are infused with the core tenets of statistical reasoning and understanding: probability, risk assessment, expected value, and game theory. This course will look at statistics and probability through this lens. We will consider dice, cards, and several ‘classic’ board games. We will consider situations with both complete and hidden information and how to analyze those.

All but a handful of the objects you see in the night sky are stars in our Galaxy, the Milky Way. Although we know about these stars only from studying their light, we know today that they are not just points of light, but large, gravitationally‐bound balls of plasma governed by the laws of physics. Stars, together with dust, gas, and dark matter, are found in larger structures – galaxies. In turn, galaxies, are located in even larger structures called galaxy groups and galaxy clusters.

The physics of light and color initially appears simple: light is a wave and the wavelength of light determines color. While this basic physical description of light is easy to state, going deeper quickly opens up large range of questions. How do different wavelengths of light combine to make colors? How does light from different sources interfere? How does light change path when it travels through different materials? How do humans sense light both in and outside of the visible spectrum? How does our perception of color affect how we interpret our world?

Physically, sound is simply the compression of air around us. However, this relatively simple description obscures a much richer understanding of sound. From how different sounds are generated and perceived to how different sounds can combine to make something new to how to design acoustically pleasant spaces, the physics of sound plays a key role. This course is about the fundamentals that underlie sound and is designed to serve as an introduction to those who are interested in going further.

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). 

Historical Dress: The Park-McCullough Project Spring '26

Working in collaboration with the local Park-McCullough Historic Governor’s Mansion, students will create a new archive of the historic dress collection.

This advanced seminar offers students the opportunity to pursue a term-long project in history.  Asking the historian’s three basic questions – why this? why here? and why now? – each student will be able to do a deep dive into their chosen piece of the past.  For some, this will be the venue for writing their SCT senior theses.  For others, this will be the place where they can produce a historical project appropriate to their Plan. Writing will take place throughout term, and all students in this seminar will receive weekly feedback.

This course is an introductory survey course of U.S. history that pays particular attention to changing norms around gender and sexuality, and how people contested or subverted those norms. Topics include: same-sex intimacy in Early America, turn of the century panics around miscegenation and white slavery, the invention of hetero and homosexuality, cross-dressing in the American West, and the HIV/AIDS crisis.

This course examines the history of immigration to the United States. How did this country become a “nation of immigrants”? How did immigration become so central to American national identity? What are this country’s purported ideals on the subject and has it ever lived up to them?  

The Holocaust is one of the most ethically challenging, traumatic, and consequential occurrences in modern history. This seminar aims to give students a granular understanding of the mass oppression, enslavement, and genocide that occurred in Europe in the 1930s and 1940s, in order to then consider how it has been represented in poetry, drama, fiction, and nonfiction both by survivors of the this historical humanitarian crisis and those who've followed.

Students will observe using the telescopes at Stickney Observatory for a series of astronomical observing projects. After a range of initial assigned projects designed to acquaint students with the capabilities of the observing equipment and astrophysically interesting observations, students will propose and carry out their own observing projects looking at astrophysical phenomena of interest to them. As this is a projects class, it is expected that students will be able to devote significant time (mostly at night) observing on their own or in small teams.