A consideration of theory and methods directed at understanding those characteristics of the person related to individually distinctive ways of experiencing and behaving. Prominent theoretical perspectives will be examined in an effort to integrate this diverse literature and to determine the directions in which this field of inquiry is moving. These theories will also be applied to case histories to examine their value in personality assessment.

Requisite: PSYC 100 or consent of the instructor. Limited to 40 students. Fall semester. Professor Demorest.

The individual’s behavior as it is influenced by other people and by the social environment. The major aim of the course is to provide an overview of the wide-ranging concerns characterizing social psychology from both a substantive and a methodological perspective. Topics include person perception, attitude change, interpersonal attraction, conformity, altruism, group dynamics, and prejudice. In addition to substantive issues, the course is designed to introduce students to the appropriate research data analysis procedures.

This course will examine how brain function regulates a broad range of mental processes and behaviors. We will discuss how neurons work and how the brain obtains information about the environment (sensory systems), regulates an organism’s response to the environment (motor systems), controls basic functions necessary for survival such as eating, drinking, sex, and sleep, and mediates higher cognitive function such as memory and language. We will also consider the consequences of brain malfunction as manifested in various forms of disease and mental illness.

An introduction to and critical consideration of experimental methodology in psychology. Topics will include the formation of testable hypotheses, the selection and implementation of appropriate procedures, the statistical description and analysis of experimental data, and the interpretation of results. Articles from the experimental journals and popular literature will illustrate and interrelate these topics and provide a survey of experimental techniques and content areas.  

(Offered as PHYS 400, BIOL 400, BCBP 400, and CHEM 400.) How do the physical laws that dominate our lives change at the small length and energy scales of individual molecules? What design principles break down at the sub-cellular level and what new chemistry and physics becomes important? We will answer these questions by looking at bio-molecules, cellular substructures, and control mechanisms that work effectively in the microscopic world. How can we understand both the static and dynamic shape of proteins using the laws of thermodynamics and kinetics?

A development of Maxwell’s electromagnetic field equations and some of their consequences using vector calculus. Topics covered include: electrostatics, steady currents and static magnetic fields, time-dependent electric and magnetic fields, and the complete Maxwell theory, energy in the electromagnetic field, Poynting’s theorem, electromagnetic waves, and radiation from time-dependent charge and current distributions. Three class hours per week.

Requisite: PHYS 117 or 124 and PHYS 227 or consent of the instructor. Fall semester. Professor Hunter.

This course begins with the foundation of classical mechanics as formulated in Newton’s Laws of Motion. We then use Hamilton’s Principle of Least Action to arrive at an alternative formulation of mechanics in which the equations of motion are derived from energies rather than forces. This Lagrangian formulation has many virtues, among them a deeper insight into the connection between symmetries and conservation laws.

The course will present the mathematical methods frequently used in theoretical physics. The physical context and interpretation will be emphasized. Topics covered will include vector calculus, complex numbers, ordinary differential equations (including series solutions), partial differential equations, functions of a complex variable, and linear algebra. Four class hours per week.

Requisite: MATH 121 and PHYS 117/124 or consent of the instructor. Fall semester.  Professor Loinaz.

The theories of relativity (special and general) and the quantum theory constituted the revolutionary transformation of physics in the early twentieth century. Certain crucial experiments precipitated crises in our classical understanding to which these theories offered responses; in other instances, the theories implied strange and/or counterintuitive phenomena that were then investigated by crucial experiments.

The idea that the same simple physical laws apply equally well in the terrestrial and celestial realms, called the Newtonian Synthesis, is a major intellectual development of the seventeenth century. It continues to be of vital importance in contemporary physics. In this course, we will explore the implications of this synthesis by combining Newton’s dynamical laws with his Law of Universal Gravitation. We will solve a wide range of problems of motion by introducing a small number of additional forces.