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Department Overview

The Department of Physics has a strong tradition of graduate study and research in astrophysics; atomic, molecular, and optical physics; condensed matter physics; high energy and particle physics; plasma physics; quantum computing; and string theory. There are many facilities for carrying out world-class research. We have a large professional staff: 45 full-time faculty members, affiliated faculty members holding joint appointments with other departments, scientists, senior scientists, and postdocs. There are over 175 graduate students in the department who come from many countries around the world. More complete information on the graduate program, the faculty, and research groups is available at the department website

Research specialties include:

Theoretical Physics

Astrophysics; atomic, molecular, and optical physics; condensed matter physics; cosmology; elementary particle physics; nuclear physics; phenomenology; plasmas and fusion; quantum computing; statistical and thermal physics; string theory.

Experimental Physics

Astrophysics; atomic, molecular, and optical physics; biophysics; condensed matter physics; cosmology; elementary particle physics; neutrino physics; experimental studies of superconductors; medical physics; nuclear physics; plasma physics; quantum computing; spectroscopy.

MS Degrees

The department offers the master science degree in physics, with two named options: Research and Quantum Computing. The MS Physics-Research option is non-admitting, meaning it is only available to students pursuing their PhD. The MS Physics-Quantum Computing option (MSPQC Program) is a professional master's program in an accelerated format designed to be completed in one calendar year.  

Admissions

Students apply to the Master of Science in Physics through the named option or the PhD:

Funding

Graduate School Resources

Resources to help you afford graduate study might include assistantships, fellowships, traineeships, and financial aid. Further funding information is available from the Graduate School. Be sure to check with your program for individual policies and processes related to funding.

Minimum Graduate School Requirements

Review the Graduate School minimum academic progress and degree requirements, in addition to the program requirements listed below.

Major Requirements

Curricular Requirements

Minimum Credit Requirement 30 credits
Minimum Residence Credit Requirement See Named Options for policy information.
Minimum Graduate Coursework Requirement 15 credits must be graduate-level coursework. Refer to the Graduate School: Minimum Graduate Coursework (50%) Requirement policy: https://policy.wisc.edu/library/UW-1244.
Overall Graduate GPA Requirement 3.00 GPA required. Refer to the Graduate School: Grade Point Average (GPA) Requirement policy: https://policy.wisc.edu/library/UW-1203.
Other Grade Requirements n/a
Assessments and Examinations See Named Options for policy information.
Language Requirements n/a

Required Courses

Select a Named Option for courses required.

Named Options

A named option is a formally documented sub-major within an academic major program. Named options appear on the transcript with degree conferral. Students pursuing the Master of Science in Physics must select one of the following named options:

 
 

Policies

Students should refer to one of the named options for policy information:

Professional Development

Graduate School Resources

Take advantage of the Graduate School's professional development resources to build skills, thrive academically, and launch your career. 

Program Resources

Students are encouraged to attend Graduate School sponsored Professional Development events and participate in Graduate School Professional Development resources, such as the Individual Development Plan (IDP).

Learning Outcomes

  1. Mastery of the core physical concepts (classical mechanics, electricity and magnetism, quantum mechanics, and statistical mechanics).
  2. Articulates, critiques, or elaborates the theories, research methods, and approaches to inquiry or schools of practice in physics.
  3. Evaluates or synthesizes information pertaining to questions or challenges in physics.
  4. Gains rudimentary awareness of physics research execution.
  5. Communicates clearly in ways appropriate to the field of physics.