Newtonian Physics
This course examines motion as it occurs throughout the universe. Topics covered include inertia, force, Newton's laws of motion, work and energy, linear momentum, collisions, gravitation, rotational motion, torque, angular momentum, and oscillatory motion. Emphasis is on practical applications in physics, engineering, the life sciences, and everyday life. Laboratory work and lecture demonstrations illustrate basic physical principles. (Students in PHYS 0109 should be enrolled concurrently in MATH 0121 or MATH 0122 or have completed a high school or college calculus course.) 3 hrs. lect., 3 hrs. lab.

Newtonian Physics
This course examines motion as it occurs throughout the universe. Topics covered include inertia, force, Newton's laws of motion, work and energy, linear momentum, collisions, gravitation, rotational motion, torque, angular momentum, and oscillatory motion. Emphasis is on practical applications in physics, engineering, the life sciences, and everyday life. Laboratory work and lecture demonstrations illustrate basic physical principles. (Students in PHYS 0109 should be enrolled concurrently in MATH 0121 or MATH 0122 or have completed a high school or college calculus course.) 3 hrs. lect., 3 hrs. lab.

Newtonian Physics
This course examines motion as it occurs throughout the universe. Topics covered include inertia, force, Newton's laws of motion, work and energy, linear momentum, collisions, gravitation, rotational motion, torque, angular momentum, and oscillatory motion. Emphasis is on practical applications in physics, engineering, the life sciences, and everyday life. Laboratory work and lecture demonstrations illustrate basic physical principles. (Students in PHYS 0109 should be enrolled concurrently in MATH 0121 or MATH 0122 or have completed a high school or college calculus course.) 3 hrs. lect., 3 hrs. lab.

Newtonian Physics
This course examines motion as it occurs throughout the universe. Topics covered include inertia, force, Newton's laws of motion, work and energy, linear momentum, collisions, gravitation, rotational motion, torque, angular momentum, and oscillatory motion. Emphasis is on practical applications in physics, engineering, the life sciences, and everyday life. Laboratory work and lecture demonstrations illustrate basic physical principles. (Students in PHYS 0109 should be enrolled concurrently in MATH 0121 or MATH 0122 or have completed a high school or college calculus course.) 3 hrs. lect., 3 hrs. lab.

Newtonian Physics
This course examines motion as it occurs throughout the universe. Topics covered include inertia, force, Newton's laws of motion, work and energy, linear momentum, collisions, gravitation, rotational motion, torque, angular momentum, and oscillatory motion. Emphasis is on practical applications in physics, engineering, the life sciences, and everyday life. Laboratory work and lecture demonstrations illustrate basic physical principles. (Students in PHYS 0109 should be enrolled concurrently in MATH 0121 or MATH 0122 or have completed a high school or college calculus course.) 3 hrs. lect., 3 hrs. lab.

Electricity and Magnetism
The physical principles of electricity and magnetism are developed and applied to the electrical structure of matter and the electromagnetic nature of light. Practical topics from electricity and magnetism include voltage, current, resistance, capacitance, inductance, and AC and DC circuits. Laboratory work includes an introduction to electronics and to important instruments such as the oscilloscope. (PHYS 0109; MATH 0122 concurrent or prior) 3 hrs. lect., 3 hrs. lab.

Electricity and Magnetism
The physical principles of electricity and magnetism are developed and applied to the electrical structure of matter and the electromagnetic nature of light. Practical topics from electricity and magnetism include voltage, current, resistance, capacitance, inductance, and AC and DC circuits. Laboratory work includes an introduction to electronics and to important instruments such as the oscilloscope. (PHYS 0109; MATH 0122 concurrent or prior) 3 hrs. lect., 3 hrs. lab.

Electricity and Magnetism
The physical principles of electricity and magnetism are developed and applied to the electrical structure of matter and the electromagnetic nature of light. Practical topics from electricity and magnetism include voltage, current, resistance, capacitance, inductance, and AC and DC circuits. Laboratory work includes an introduction to electronics and to important instruments such as the oscilloscope. (PHYS 0109; MATH 0122 concurrent or prior) 3 hrs. lect., 3 hrs. lab.

An Introduction to the Universe
Our universe comprises billions of galaxies in a rapidly expanding fabric. How did it begin? Will it expand forever, or how may it end? How do the stars that compose the galaxies evolve from their births in clouds of gas, through the tranquility of middle age, to their often violent deaths? How can scientists even hope to answer such cosmic questions from our vantage point on a small planet, orbiting a very ordinary star? Are there other planets, orbiting other stars, where intelligent beings may be pondering similar issues? This introductory astronomy course, designed for nonscience majors, will explore these and other questions. Students will also become familiar with the night sky, both as part of our natural environment and as a scientific resource, through independent observations and sessions at the College Observatory. The approach requires no college-level mathematics, but students should expect to do quantitative calculations using scientific notation and occasionally to use elementary high-school algebra. (Students may not receive credit for both PHYS 0155 and PHYS 0165.) 3 hrs. lect., 2 hrs. lab./disc.

An Introduction to the Universe
Our universe comprises billions of galaxies in a rapidly expanding fabric. How did it begin? Will it expand forever, or how may it end? How do the stars that compose the galaxies evolve from their births in clouds of gas, through the tranquility of middle age, to their often violent deaths? How can scientists even hope to answer such cosmic questions from our vantage point on a small planet, orbiting a very ordinary star? Are there other planets, orbiting other stars, where intelligent beings may be pondering similar issues? This introductory astronomy course, designed for nonscience majors, will explore these and other questions. Students will also become familiar with the night sky, both as part of our natural environment and as a scientific resource, through independent observations and sessions at the College Observatory. The approach requires no college-level mathematics, but students should expect to do quantitative calculations using scientific notation and occasionally to use elementary high-school algebra. (Students may not receive credit for both PHYS 0155 and PHYS 0165.) 3 hrs. lect., 2 hrs. lab./disc.

An Introduction to the Universe
Our universe comprises billions of galaxies in a rapidly expanding fabric. How did it begin? Will it expand forever, or how may it end? How do the stars that compose the galaxies evolve from their births in clouds of gas, through the tranquility of middle age, to their often violent deaths? How can scientists even hope to answer such cosmic questions from our vantage point on a small planet, orbiting a very ordinary star? Are there other planets, orbiting other stars, where intelligent beings may be pondering similar issues? This introductory astronomy course, designed for nonscience majors, will explore these and other questions. Students will also become familiar with the night sky, both as part of our natural environment and as a scientific resource, through independent observations and sessions at the College Observatory. The approach requires no college-level mathematics, but students should expect to do quantitative calculations using scientific notation and occasionally to use elementary high-school algebra. (Students may not receive credit for both PHYS 0155 and PHYS 0165.) 3 hrs. lect., 2 hrs. lab./disc.

An Introduction to the Universe
Our universe comprises billions of galaxies in a rapidly expanding fabric. How did it begin? Will it expand forever, or how may it end? How do the stars that compose the galaxies evolve from their births in clouds of gas, through the tranquility of middle age, to their often violent deaths? How can scientists even hope to answer such cosmic questions from our vantage point on a small planet, orbiting a very ordinary star? Are there other planets, orbiting other stars, where intelligent beings may be pondering similar issues? This introductory astronomy course, designed for nonscience majors, will explore these and other questions. Students will also become familiar with the night sky, both as part of our natural environment and as a scientific resource, through independent observations and sessions at the College Observatory. The approach requires no college-level mathematics, but students should expect to do quantitative calculations using scientific notation and occasionally to use elementary high-school algebra. (Students may not receive credit for both PHYS 0155 and PHYS 0165.) 3 hrs. lect., 2 hrs. lab./disc.

An Introduction to the Universe
Our universe comprises billions of galaxies in a rapidly expanding fabric. How did it begin? Will it expand forever, or how may it end? How do the stars that compose the galaxies evolve from their births in clouds of gas, through the tranquility of middle age, to their often violent deaths? How can scientists even hope to answer such cosmic questions from our vantage point on a small planet, orbiting a very ordinary star? Are there other planets, orbiting other stars, where intelligent beings may be pondering similar issues? This introductory astronomy course, designed for nonscience majors, will explore these and other questions. Students will also become familiar with the night sky, both as part of our natural environment and as a scientific resource, through independent observations and sessions at the College Observatory. The approach requires no college-level mathematics, but students should expect to do quantitative calculations using scientific notation and occasionally to use elementary high-school algebra. (Students may not receive credit for both PHYS 0155 and PHYS 0165.) 3 hrs. lect., 2 hrs. lab./disc.

Physics in the Universe
This introduction to the phenomena and physical principles of the universe follows a similar syllabus to that of PHYS 0155, but with an added emphasis on analytical material. Principles of Newtonian mechanics are applied to the motions of planets, stars, and galaxies; statistical techniques help in understanding structures ranging from the interiors of stars to clusters of galaxies; and quantum principles are used to understand the radiation we receive from cosmic sources and the physical processes at work there. 3 hrs. lect., 3.5 hrs. lab./disc. (PHYS 0109 or equivalent) (Students may not receive credit for both PHYS 0155 and PHYS 0165.)

Physics in the Universe
This introduction to the phenomena and physical principles of the universe follows a similar syllabus to that of PHYS 0155, but with an added emphasis on analytical material. Principles of Newtonian mechanics are applied to the motions of planets, stars, and galaxies; statistical techniques help in understanding structures ranging from the interiors of stars to clusters of galaxies; and quantum principles are used to understand the radiation we receive from cosmic sources and the physical processes at work there. 3 hrs. lect., 3.5 hrs. lab./disc. (PHYS 0109 or equivalent) (Students may not receive credit for both PHYS 0155 and PHYS 0165.)

Physics in the Universe
This introduction to the phenomena and physical principles of the universe follows a similar syllabus to that of PHYS 0155, but with an added emphasis on analytical material. Principles of Newtonian mechanics are applied to the motions of planets, stars, and galaxies; statistical techniques help in understanding structures ranging from the interiors of stars to clusters of galaxies; and quantum principles are used to understand the radiation we receive from cosmic sources and the physical processes at work there. 3 hrs. lect., 3.5 hrs. lab./disc. (PHYS 0109 or equivalent) (Students may not receive credit for both PHYS 0155 and PHYS 0165.)

Physics in the Universe
This introduction to the phenomena and physical principles of the universe follows a similar syllabus to that of PHYS 0155, but with an added emphasis on analytical material. Principles of Newtonian mechanics are applied to the motions of planets, stars, and galaxies; statistical techniques help in understanding structures ranging from the interiors of stars to clusters of galaxies; and quantum principles are used to understand the radiation we receive from cosmic sources and the physical processes at work there. 3 hrs. lect., 3.5 hrs. lab./disc. (PHYS 0109 or equivalent) (Students may not receive credit for both PHYS 0155 and PHYS 0165.)

Physics in the Universe
This introduction to the phenomena and physical principles of the universe follows a similar syllabus to that of PHYS 0155, but with an added emphasis on analytical material. Principles of Newtonian mechanics are applied to the motions of planets, stars, and galaxies; statistical techniques help in understanding structures ranging from the interiors of stars to clusters of galaxies; and quantum principles are used to understand the radiation we receive from cosmic sources and the physical processes at work there. 3 hrs. lect., 3.5 hrs. lab./disc. (PHYS 0109 or equivalent) (Students may not receive credit for both PHYS 0155 and PHYS 0165.)

Physics in the Universe
This introduction to the phenomena and physical principles of the universe follows a similar syllabus to that of PHYS 0155, but with an added emphasis on analytical material. Principles of Newtonian mechanics are applied to the motions of planets, stars, and galaxies; statistical techniques help in understanding structures ranging from the interiors of stars to clusters of galaxies; and quantum principles are used to understand the radiation we receive from cosmic sources and the physical processes at work there. 3 hrs. lect., 3.5 hrs. lab./disc. (PHYS 0109 or equivalent) (Students may not receive credit for both PHYS 0155 and PHYS 0165.)

Relativity and Quantum Physics
This course probes a number of areas for which classical physics has provided no adequate explanations. Topics covered include Einstein's special relativity, quantization of atomic energy levels and photons, the atomic models of Rutherford and Bohr, and wave-particle duality. (PHYS 0109, MATH 0122; PHYS 0110 concurrent or prior) 3 hrs. lect.

Electronics for Scientists
An introduction to modern electronic circuits and devices, emphasizing both physical operation and practical use. Transistors and integrated circuits are considered in both analog and digital applications. Examples and laboratory experiments stress measurement and control applications in the physical and biological sciences. Students will gain hands-on familiarity with the design, use, and troubleshooting of electronic instrumentation. (PHYS 0110 or by waiver) 3 hrs. lect., 3 hrs. lab.

Electronics for Scientists
An introduction to modern electronic circuits and devices, emphasizing both physical operation and practical use. Transistors and integrated circuits are considered in both analog and digital applications. Examples and laboratory experiments stress measurement and control applications in the physical and biological sciences. Students will gain hands-on familiarity with the design, use, and troubleshooting of electronic instrumentation. (PHYS 0110 or by waiver) 3 hrs. lect., 3 hrs. lab.

Electronics for Scientists
An introduction to modern electronic circuits and devices, emphasizing both physical operation and practical use. Transistors and integrated circuits are considered in both analog and digital applications. Examples and laboratory experiments stress measurement and control applications in the physical and biological sciences. Students will gain hands-on familiarity with the design, use, and troubleshooting of electronic instrumentation. (PHYS 0110 or by waiver) 3 hrs. lect., 3 hrs. lab.

Intermediate Electromagnetism
The unified description of electricity and magnetism is one of the greatest triumphs of physics. This course provides a thorough grounding in the nature of electric and magnetic fields and their interaction with matter. Mathematical techniques appropriate to the solution of problems in electromagnetism are also introduced. The primary emphasis is on static fields, with the full time-dependent Maxwell equations and electromagnetic waves introduced in the final part of the course. (PHYS 0212) 3 hrs. lect.

Experimental Techniques in Physics
This course will cover the design and execution of experiments, and the analysis and presentation of data, at an advanced level. Laboratory experiments will be chosen to illustrate the use of electronic, mechanical, and optical instruments to investigate fundamental physical phenomena, such as the properties of atoms and nuclei and the nature of radiation. Skills in computer-based data analysis and presentation will be developed and emphasized. This course satisfies the College writing requirement. (PHYS 0201 and PHYS 0202 and PHYS 0212; MATH 0200 recommended) 3 hrs. lect., 3 hrs. lab.

Experimental Techniques in Physics
This course will cover the design and execution of experiments, and the analysis and presentation of data, at an advanced level. Laboratory experiments will be chosen to illustrate the use of electronic, mechanical, and optical instruments to investigate fundamental physical phenomena, such as the properties of atoms and nuclei and the nature of radiation. Skills in computer-based data analysis and presentation will be developed and emphasized. This course satisfies the College writing requirement. (PHYS 0201 and PHYS 0202 and PHYS 0212; MATH 0200 recommended) 3 hrs. lect., 3 hrs. lab.

Experimental Techniques in Physics
This course will cover the design and execution of experiments, and the analysis and presentation of data, at an advanced level. Laboratory experiments will be chosen to illustrate the use of electronic, mechanical, and optical instruments to investigate fundamental physical phenomena, such as the properties of atoms and nuclei and the nature of radiation. Skills in computer-based data analysis and presentation will be developed and emphasized. This course satisfies the College writing requirement. (PHYS 0201 and PHYS 0202 and PHYS 0212; MATH 0200 recommended) 3 hrs. lect., 3 hrs. lab.

Experimental Techniques in Physics
This course will cover the design and execution of experiments, and the analysis and presentation of data, at an advanced level. Laboratory experiments will be chosen to illustrate the use of electronic, mechanical, and optical instruments to investigate fundamental physical phenomena, such as the properties of atoms and nuclei and the nature of radiation. Skills in computer-based data analysis and presentation will be developed and emphasized. This course satisfies the College writing requirement. (PHYS 0201 and PHYS 0202 and PHYS 0212; MATH 0200 recommended) 3 hrs. lect., 3 hrs. lab.

Experimental Techniques in Physics
This course will cover the design and execution of experiments, and the analysis and presentation of data, at an advanced level. Laboratory experiments will be chosen to illustrate the use of electronic, mechanical, and optical instruments to investigate fundamental physical phenomena, such as the properties of atoms and nuclei and the nature of radiation. Skills in computer-based data analysis and presentation will be developed and emphasized. This course satisfies the College writing requirement. (PHYS 0201 and PHYS 0202 and PHYS 0212; MATH 0200 recommended) 3 hrs. lect., 3 hrs. lab.

Statistical Mechanics
The course opens with a review of classical thermodynamics and continues with an examination of the fundamental concepts of probability, statistics, and distribution functions. These topics are followed by in-depth discussion of the concepts of energy, energy quantization, and the application of these concepts to the modeling of macroscopic systems. The remainder of the course is a study of statistical mechanics and its application to a variety of classical and quantum systems. Topics covered include statistical thermodynamics, Maxwellian distributions, imperfect gases, equipartition theorem, quantum statistics, heat capacities of solids, electromagnetic radiation, and ideal quantum gases. (PHYS 0202 and PHYS 0212) 3 hrs. lect.

Quantum Mechanics
A fundamental course in quantum mechanics aimed at understanding the mathematical structure of the theory and its application to physical phenomena at the atomic and nuclear levels. Topics include the basic postulates of quantum mechanics, operator formalism, Schrödinger equation, one-dimensional and central potentials, angular momentum and spin, perturbation theory, and systems of identical particles. (PHYS 0202 and PHYS 0212; MATH 0200 recommended) 3 hrs. lect.

Independent Study and Special Topics
(Approval required)

Independent Study and Special Topics
(Approval required)

Independent Study and Special Topics
(Approval required)

Independent Study and Special Topics
(Approval required)

Independent Study and Special Topics
(Approval required)

Independent Study and Special Topics
(Approval required)

Independent Study and Special Topics
(Approval required)

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Project
Independent research project culminating in both written and oral presentations.

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)

Senior Research and Thesis
Independent research in the fall, winter, and spring terms culminating in a written thesis (two units total). (Approval required)