[R] This interdisciplinary introduction to Black Studies combines the teaching of foundational texts in the field with instruction in reading and writing. The first half of the course employs How to Read a Book by Mortimer Adler and Charles Van Doren as a guide to the careful reading of books focusing on the slave trade and its effects in Africa, the Caribbean, and the United States. Important readings in this part of the course include Black Odyssey by Nathan Huggins, Racism: A Short History by George Frederickson, and The Black Jacobins by C. L. R.

Independent reading or research courses. Full course as arranged. Does not normally count toward the major.

Fall and spring semester.

Concentrating on reading and interpreting primary research, this course will focus on classic and soon-to-be classic neurophysiology papers. We will discuss the seminal experiments performed in the 1950s that led to our understanding of action potentials; experiments in the 1960s and 1970s that unlocked how synapses function; and more recent research that combines electrophysiology with optical methods and genetic techniques to investigate the role of many of the molecular components predicted by the work from the earlier decades.

The topic is the ecology and evolution of plant-animal interactions. Most animals on Earth obtain their energy from green plants, and thus it is not surprising that interactions between plants and animals have played a prominent role in our current understanding of how ecological processes such as predation, parasitism, and mutualism shape evolutionary patterns in plants and animals. In this course we will start our analysis with a consideration of how plant-animal relationships evolve by studying examples from both extant systems and the fossil record.

The majority of organisms on earth cause disease or are parasitic, and it could be said that a thorough understanding of biology should necessarily involve the study of infectious disease. Yet only within the past two decades has there been a realization that diseases may regulate populations, stabilize ecosystems, and be responsible for major biological features such as reproductive systems or genomic structures.

Reading and discussion of historical and contemporary scientific literature at the interface between physics and the life sciences.  Topics will include (1) how observations on human physiology contributed to the formulation of the laws of thermodynamics; (2) whether an intelligent being (a so-called Maxwell’s demon) could thwart the entropy increases called for in the second law of thermodynamics by sorting individual molecules using information about each molecule’s position or motion; and (3) to what extent non-classical physical phenomena such as quantum tunneling must

A study of the architecture and interactions of genetic systems. Advances in genomics are providing insights into a variety of important issues, from the structural limits of DNA-based inheritance to the discovery of novel infectious and genetic diseases. We will address how heritable information is organized in different groups of organisms. We will also cover a major challenge of this emerging field--the application of vast amounts of genetic data to understanding genomic integrity and regulation.