Course Descriptions
Below is the list of the courses offered by the Physics Department. Courses are offered鈥痓ased
on demand unless indicated next to the course title.
PHYS 104. Astronomy (3 Credits)
Three hours per week. A study of the behavior of astronomical systems. Topics include
understanding observations made from a moving reference frame such as the earth, the
development of modern astronomy, telescopes, the solar system, stars and stellar evolution,
galaxies, cosmology and life in the universe.
PHYS 111. Principles of Physics I (4 Credits; Offered Every Fall)
Six hours of integrated lecture/laboratory per week. Co-requisite: MATH 110 or MATH
112. Measurement and error analysis. An algebra-based treatment of classical mechanics,
including kinematics and dynamics of translational and rotational motion, oscillations,
waves and fluids.
PHYS 112. Principles of Physics II (4 Credits; Offered Every Spring)
Six hours of integrated lecture/laboratory per week. Prerequisite: PHYS 111. An algebra-based
treatment of electricity and magnetism, AC and DC circuits and geometrical optics.
PHYS 116. Astronomy Laboratory (1 Credit)
Three hours laboratory per week. Co-requisite: PHYS 104. Selected experiments in astronomy,
optics, radiation, and orbital mechanics.
PHYS 125. Aviation Physics (4 credits; Offered Every Fall and Spring)
Six hours of integrated lecture/laboratory per week. Co-requisite: MATH 110 or MATH
112.鈥This course will not serve as a prerequisite for PHYS 112 or PHYS 152.鈥疉n algebra/trigonometry-based treatment of principles of physics relevant to aviation
science, including mechanics, thermodynamics, fluid dynamics,
and electromagnetism, with application to pneumatic, hydraulic, electric, and mechanical
instrumentation and controls.
PHYS 151. General Physics: Mechanics (4 Credits)
Six hours of integrated class and laboratory per week. Co-requisite: MATH 140. This
calculus-based course introduces students to the major themes and principles of mechanics
(forces, energy, linear and angular momentum, and conservation laws) and their applications
in the context of
translational motion, rotational motion, and thermodynamics. Students will be guided
in the basics of computational, experimental, and/or theoretical physics practice.
PHYS 152. General Physics: Electricity & Magnetism (4 Credits)
Six hours of integrated class and laboratory per week. Prerequisites: MATH 140 and
a 鈥淐鈥 or better in PHYS 151. Co-requisite: MATH 141. This calculus-based course introduces
students to the major themes and principles of electricity and magnetism (fields,
potentials, and Maxwell鈥檚 equations) and their applications in the context of charge
distributions, current distributions, circuits, and optics. Students will be guided
in the basics of computational, experimental, and /or theoretical physics practice.
PHYS 200 General Physics: Modern Physics (4 Credits)
Six hours of integrated class and laboratory per week. Prerequisites: a 鈥淐鈥 or better
in PHYS 152. This calculus-based course provides students with an introduction to
the key themes and principles of wave phenomena, the special theory of relativity,
and quantum mechanics and nuclear physics.
PHYS 306. Thermodynamics and Statistical Mechanics (3 Credits)
Three hours per week. Prerequisites: PHYS 152. Co-requisite: MATH 331. Students will
learn about the principles of thermodynamics and statistical mechanics such as equipartition
theorem, heat capacities, entropy, free energies and phase transition in systems involving
ideal gas, two-state systems, and solids. PHYS306 is cross-listed with CHEM407.
PHYS 310. Electromagnetic Theory I (3 Credits)
Three hours per week. Prerequisites: PHYS 101, PHYS 152, and MATH 331. Co-requisite:
One of MATH 315, MATH 316, MATH 320, MATH 351, MATH 354, MATH 411, MATH 412, or MATH
423. Static electric fields and solution of electrostatic problems using vector analysis
and differential equations. Electric currents and electrical properties of materials.
PHYS 351RI. Computational Research Methods in Physics (3 Credits)
Three hours per week. Prerequisite: PHY152, CS307 Co-requisite: MATH141. This course
focuses on scientific programming, utilizing languages like Python, and assumes an
entry-level programming background. Students will gain a deeper understanding of mathematical
and physical principles through a range of computational projects. This course is
research-intensive and fulfills the experiential learning requirement. PHYS351RI will
be cross listed with MATH341RI.鈥
PHYS 352. Experimental Research Methods in Physics (3 Credits)
Three hours per week. Prerequisites: CHEM104/205. Students will learn skills and methods
used in experimental physics research, including the use of primary literature. Students
will practice these skills and methodologies in projects throughout the course. PHYS352
will be cross-listed with CHEM351.
PHYS 353RI. Theoretical Research Methods in Physics (3 Credits)
Three hours per week. Prerequisites: MATH 331 and PHYS 152. This course is designed
to provide students with a foundation in the mathematical techniques needed in advance
physics courses and in the physics literature. Specific topics that will be covered
include: ordinary and partial differential equations, special functions, Green鈥檚 functions,
vector analysis, complex analysis and Hilbert space. Students will obtain a deeper
understanding of mathematics and physics principles through a variety of research
projects. This course is research-intensive and satisfies the experiential learning
requirement. PHYS353RI will be cross listed with MATH343RI.鈥
PHYS 354. Introduction to Quantum Computing (3 Credits)
Three hours per week. Prerequisite: PHYS200. This course offers students a comprehensive
introduction to the rapidly developing field of quantum computing. The course offers
an overview, essential background knowledge, and practical hands-on experience in
quantum computing. Students will acquire a grasp of the fundamental physical principles
and essential mathematical tools required for quantum computing. Throughout the course,
students will gain the skills to write programs and engage in quantum computing using
both simulators and real quantum computers.
PHYS 413. Quantum Mechanics I (3 Credits)
Three hours per week. Prerequisites: MATH 300, and MATH 331, and a 鈥淐鈥 or better in
PHYS 203 or consent of instructor. The Schrodinger equation. Wave packets and free
particle motion. The linear harmonic oscillator. Constant potential in one dimension.
Central forces and the hydrogen atom. Angular momentum. Fermi-Dirac and Bose-Einstein
statistics. PHYS413 is cross-listed with CHEM408.
PHYS 481WS. Senior Project (3 Credits)
Three hours per week per credit hour. Prerequisite: PHYS200, PHY351, PHY353, MATH331.
The student will plan, implement, and evaluate original computational, educational,
experimental, or theoretical physics research under the guidance of a designated physics
faculty. Students are required to make multiple oral presentations, updating on their
research progress. These presentations account for a minimum of 40% of the final grade.
Formal scientific manuscript of research will be required, minimal 6000 words. This
is a writing and speech intensive course.
PHYS 495. Research Participation (var. 1-3 Credits; max. 3 Credits)
Prerequisite: Consent of instructor. May be taken for credit more than once, but only
three credit hours will be counted toward satisfying the departmental degree requirements.
Student participation directed by a member of the sciences or engineering faculty.
A Physics Major also requires the following courses from Mathematics/Computing Science Department:
MATH 140鈥疌alculus I (3 Credits)
Prerequisite: MATH-110, Rates of change, polynomial, exponential functions, models
of growth. Differential calculus and its applications. Simple differential equation
and initial value problems. A graphing calculator is required.
MATH 141鈥疌alculus II (3 Credits)
Prerequisite: MATH-140. The definite integral, the Fundamental Theorem of Calculus,
integral calculus and its application uses. An introduction to series including Taylor
series and it convergence. A graphing calculator is required.
MATH 240鈥疌alculus III (3 Credits)
Functions of several variables, vectors, partial derivatives, double and triple integrals,
non-Cartesian coordinate systems, vector fields and line integrals. A graphing calculator
is required.
MATH 320鈥疞inear Algebra (3 Credits)
Systems of linear equations, matrix algebra, linear transformations, determinants,
vector spaces, eigenvectors and eigenvalues, and applications.
MATH 331鈥疍ifferential Equations (3 Credits)
Qualitative and analytic study of ordinary differential equations. Study of first
and second order equations, first order systems and qualitative analysis of linear
and nonlinear systems. Modeling of real world phenomena with ordinary differential
equations.
CS 307鈥疨ython Programming (3 Credits)
This course focuses on development of practical Python programming skills through
project-based application. The course discusses powerful features of the Python programming
language itself, which allow students to quickly and easily manipulate data in ways
not found in other languages. Application of modules to solve domain-specific challenges,
such as in scientific computation, data visualization and analysis, application development,
and machine learning.
CS 405鈥疉rtificial Intelligence (3 Credits)
This course introduces the basic ideas and techniques underlying the design of intelligent
computer systems. A specific emphasis will be on the methodology used to treat knowledge
representation, formal logic (classical propositional logic, first order predicate
logic, automated theorem proving), pattern recognition; natural and programming language
processing.