printer friendly pagePHYSICS 23: Electricity, Magnetism, and Optics
How are electric and magnetic fields generated by static and moving charges, and what are their applications? How is light related to electromagnetic waves? Students learn to represent and analyze electric and magnetic fields to understand electric circuits, motors, and generators. The wave nature of light is used to explain interference, diffraction, and polarization phenomena. Geometric optics is employed to understand how lenses and mirrors form images. These descriptions are combined to understand the workings and limitations of optical systems such as the eye, corrective vision, cameras, telescopes, and microscopes. Discussions based on the language of algebra and trigonometry. Physical understanding fostered by peer interaction and demonstrations in lecture, and interactive group problem solving in discussion sections. Prerequisite:
PHYSICS 21 or
PHYSICS 21S.
Terms: Win
| Units: 4
| UG Reqs: GER: DB-NatSci, WAY-SMA
Instructors:
Schleier-Smith, M. (PI)
;
Gudinas, A. (TA)
;
Kadir, S. (TA)
...
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Instructors:
Schleier-Smith, M. (PI)
;
Gudinas, A. (TA)
;
Kadir, S. (TA)
;
Nakato, Y. (TA)
;
Rahman, A. (TA)
;
Shyaka, V. (TA)
;
Weiss, W. (TA)
PHYSICS 24: Electricity, Magnetism, and Optics Laboratory
Guided hands-on exploration of concepts in electricity and magnetism, circuits and optics with an emphasis on student predictions, observations and explanations. Introduction to multimeters and oscilloscopes. Pre- or corequisite: PHYS 23.
Terms: Win
| Units: 1
PHYSICS 41: Mechanics
How are motions of objects in the physical world determined by the laws of physics? Students learn to describe the motion of objects (kinematics) and then understand why motions have the form they do (dynamics). Emphasis on how the important physical principles in mechanics, such as conservation of momentum and energy for translational and rotational motion, follow from just three laws of nature: Newton's laws of motion. The distinction made between fundamental laws of nature and empirical rules that are useful approximations for more complex physics. Problems are drawn from examples of mechanics in everyday life. Skills developed in verifying that derived results satisfy criteria for correctness, such as dimensional consistency and expected behavior in limiting cases. Discussions based on the language of mathematics, particularly vector representations and operations, and calculus. Physical understanding is fostered by peer interaction and demonstrations in lecture, and discussion sec
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How are motions of objects in the physical world determined by the laws of physics? Students learn to describe the motion of objects (kinematics) and then understand why motions have the form they do (dynamics). Emphasis on how the important physical principles in mechanics, such as conservation of momentum and energy for translational and rotational motion, follow from just three laws of nature: Newton's laws of motion. The distinction made between fundamental laws of nature and empirical rules that are useful approximations for more complex physics. Problems are drawn from examples of mechanics in everyday life. Skills developed in verifying that derived results satisfy criteria for correctness, such as dimensional consistency and expected behavior in limiting cases. Discussions based on the language of mathematics, particularly vector representations and operations, and calculus. Physical understanding is fostered by peer interaction and demonstrations in lecture, and discussion sections based on interactive group problem-solving. Please enroll in a section that you can attend regularly. In order to register for this class students who have never taken an introductory Physics course at Stanford must complete the Physics Placement Diagnostic at
https://physics.stanford.edu/academics/undergraduate-students/placement-diagnostic. Students who complete the Physics Placement Diagnostic by 3 PM (Pacific) on Friday will have their hold lifted over the weekend. Prerequisites: Physics placement diagnostic AND
Math 20 or higherCorequisites: Completion of OR co-enrollment of
Math 21 or higher. Since high school math classes vary widely, it is recommended that you take at least one math class at Stanford before or concurrently with
Physics 41. In addition, it is recommended that you take
Math 51 or
CME 100 before taking the next course in the
Physics 40 series,
Physics 43.
Terms: Aut, Win
| Units: 4
| UG Reqs: GER: DB-NatSci, WAY-SMA
Instructors:
Blakemore, C. (PI)
;
Nanni, E. (PI)
;
Tompkins, L. (PI)
...
more instructors for PHYSICS 41 »
Instructors:
Blakemore, C. (PI)
;
Nanni, E. (PI)
;
Tompkins, L. (PI)
;
Tam, F. (SI)
;
-, I. (TA)
;
Akinleye, H. (TA)
;
Alary, A. (TA)
;
Batra, G. (TA)
;
Bindon, S. (TA)
;
Campello, A. (TA)
;
Dolev, K. (TA)
;
Gaiser, S. (TA)
;
Manwadkar, V. (TA)
;
Mittal, D. (TA)
;
Nee, M. (TA)
;
Sundaresan, G. (TA)
;
Wendt, D. (TA)
;
Yuan, A. (TA)
;
Zhang, Z. (TA)
PHYSICS 41E: Mechanics, Concepts, Calculations, and Context
Physics 41E (
Physics 41 Extended) is a 5-unit version of
Physics 41 (4 units) for students with little or no high school physics. Course topics and mathematical complexity are similar, but not identical to
Physics 41. There is an additional class meeting every week, and attendance at all class sessions is mandatory. The extra classroom time and corresponding extra study time outside of class allows students to engage with concepts and become fluent in mathematical tools that include vector representations and operations, and relevant calculus. There is a strong emphasis on developing problem-solving skills, particularly as applied to real world examples, to leave students prepared for subsequent engineering, physics, or related courses they may take. The course will explore important physical principles in mechanics including: using Newton's Laws and torque to analyze static structures and forces; understanding the equations of kinematics; and utilizing energy in its many forms and
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Physics 41E (
Physics 41 Extended) is a 5-unit version of
Physics 41 (4 units) for students with little or no high school physics. Course topics and mathematical complexity are similar, but not identical to
Physics 41. There is an additional class meeting every week, and attendance at all class sessions is mandatory. The extra classroom time and corresponding extra study time outside of class allows students to engage with concepts and become fluent in mathematical tools that include vector representations and operations, and relevant calculus. There is a strong emphasis on developing problem-solving skills, particularly as applied to real world examples, to leave students prepared for subsequent engineering, physics, or related courses they may take. The course will explore important physical principles in mechanics including: using Newton's Laws and torque to analyze static structures and forces; understanding the equations of kinematics; and utilizing energy in its many forms and applications. Prerequisites: Physics placement diagnostic AND
Math 20 or higher. Corequisites: Completion of OR co-enrollment of
Math 21 or higher. Since high school math classes vary widely, it is recommended that you take at least one math class at Stanford before or concurrently with
Physics 41. In addition, it is recommended that you take
Math 51 or
CME 100 before taking the next course in the
Physics 40 series,
Physics 43. Priority will be given to students who have had little physics background.
Terms: Win
| Units: 5
| UG Reqs: WAY-SMA
Instructors:
Blakemore, C. (PI)
;
Church, S. (PI)
;
Wieman, C. (PI)
...
more instructors for PHYSICS 41E »
Instructors:
Blakemore, C. (PI)
;
Church, S. (PI)
;
Wieman, C. (PI)
;
Martins, K. (TA)
;
Nee, M. (TA)
;
Sherman, L. (TA)
;
Wei, X. (TA)
;
Xiang, C. (TA)
;
Yang, C. (TA)
;
Zenagui, A. (TA)
PHYSICS 41S: STEMentors in Physics
STEMentors in Physics has been designed to provide timely support for students in PHYS 41 with study and problem-solving skills applicable in both physics and STEM courses in general. Students will join a small cohort of other PHYS 41 students looking to build community with and support other students in STEM. Weekly sections will focus on group activities and individual check-ins facilitated by a peer mentor who has previously taken PHYS 41. These activities are designed to normalize challenging experiences within a college science course, build key study skills such as how to effectively review lecture notes and practice problems, prepare for and reflect on exams, and reinforce problem-solving processes that will build student confidence over the quarter. Students should enroll in a weekly mentor section. Link to Mentor Bios:
https://physics.stanford.edu/undergraduate/physics-stementors#:~:text=The%20Physics%20STEMentors%20program%20is,successful%20Chemistry%20Department%20STEMentors%20program. Co-Requisite: PHYS 41
Terms: Win
| Units: 1
Instructors:
Tam, F. (PI)
;
Tompkins, L. (PI)
;
Aispuro, J. (TA)
...
more instructors for PHYSICS 41S »
Instructors:
Tam, F. (PI)
;
Tompkins, L. (PI)
;
Aispuro, J. (TA)
;
Farah, E. (TA)
;
Ku, A. (TA)
;
Lin, J. (TA)
;
Riedman, N. (TA)
;
Vats, A. (TA)
PHYSICS 42: Classical Mechanics Laboratory
Hands-on exploration of concepts in classical mechanics: Newton's laws, conservation laws, rotational motion. Introduction to laboratory techniques, experimental equipment and data analysis. Pre- or corequisite:
PHYSICS 41.
Terms: Aut, Win
| Units: 1
Instructors:
Devin, J. (PI)
;
Alary, A. (TA)
;
Calvera, V. (TA)
...
more instructors for PHYSICS 42 »
Instructors:
Devin, J. (PI)
;
Alary, A. (TA)
;
Calvera, V. (TA)
;
Curtis, I. (TA)
;
Dacunha, T. (TA)
;
Pecastaings, M. (TA)
;
Shiferaw, M. (TA)
PHYSICS 43: Electricity and Magnetism
What is electricity? What is magnetism? How are they related? How do these phenomena manifest themselves in the physical world? The theory of electricity and magnetism, as codified by Maxwell's equations, underlies much of the observable universe. Students develop both conceptual and quantitative knowledge of this theory. Topics include: electrostatics; magnetostatics; simple AC and DC circuits involving capacitors, inductors, and resistors; integral form of Maxwell's equations; electromagnetic waves. Principles illustrated in the context of modern technologies. Broader scientific questions addressed include: How do physical theories evolve? What is the interplay between basic physical theories and associated technologies? Discussions based on the language of mathematics, particularly differential and integral calculus, and vectors. Physical understanding fostered by peer interaction and demonstrations in lecture, and discussion sections based on interactive group problem solving. Prerequisite:
PHYSICS 41, 41E or equivalent.
MATH 21 or
MATH 51 or
CME 100 or equivalent. Recommended corequisite:
MATH 52 or
CME 102. Please make sure your AP scores are uploaded before enrollment opens.
Terms: Win, Spr
| Units: 4
| UG Reqs: GER: DB-NatSci, WAY-SMA
Instructors:
Kasevich, M. (PI)
;
Lee, Y. (PI)
;
Nanavati, C. (PI)
...
more instructors for PHYSICS 43 »
Instructors:
Kasevich, M. (PI)
;
Lee, Y. (PI)
;
Nanavati, C. (PI)
;
Batra, G. (TA)
;
Brandenstein, C. (TA)
;
Deroo, V. (TA)
;
Entin, N. (TA)
;
Ferree, N. (TA)
;
Jia, K. (TA)
;
Kundu, S. (TA)
;
Li, D. (TA)
;
Liu, F. (TA)
;
Lu, J. (TA)
;
McEntaggart, A. (TA)
;
Morales, A. (TA)
;
Nee, M. (TA)
;
Pan, A. (TA)
;
Panelli, G. (TA)
;
Peets, E. (TA)
;
Safvati, B. (TA)
;
Taylor, E. (TA)
;
Wu, J. (TA)
;
Ye, Y. (TA)
;
Yuan, A. (TA)
;
Zic, M. (TA)
PHYSICS 44: Electricity and Magnetism Lab
Hands-on exploration of concepts in electricity, magnetism, and circuits. Introduction to multimeters, function generators, oscilloscopes, and graphing techniques. Pre- or corequisite:
PHYSICS 43.
Terms: Win, Spr
| Units: 1
Instructors:
Devin, J. (PI)
;
Kim, J. (TA)
;
Liu, F. (TA)
;
Liu, S. (TA)
;
Mebratu, M. (TA)
;
Sylber, C. (TA)
PHYSICS 71: Quantum and Thermal Physics
(Second in a three-part series:
PHYSICS 61,
PHYSICS 71,
PHYSICS 81.) This course introduces the foundations of quantum mechanics and thermodynamics to students with a strong high school mathematics and physics background, who are contemplating a major in Physics or Engineering Physics or are interested in a rigorous treatment of physics. Topics related to quantum mechanics include atoms, electrons, and nuclei. Experimental evidence for physics that is not explained by classical mechanics and E&M. Quantization of light, Planck's constant. Photoelectric effect, Compton and Bragg scattering. Bohr model, atomic spectra. Matter waves, wave packets, interference. Fourier analysis and transforms Heisenberg uncertainty relationships. Particle-in-a-box, simple harmonic oscillator, barrier penetration, tunneling. Topics related to thermodynamics: limitations of classical mechanics in describing systems with a very large number of particles. Ideal gas, equipartition, heat capacity, the definit
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(Second in a three-part series:
PHYSICS 61,
PHYSICS 71,
PHYSICS 81.) This course introduces the foundations of quantum mechanics and thermodynamics to students with a strong high school mathematics and physics background, who are contemplating a major in Physics or Engineering Physics or are interested in a rigorous treatment of physics. Topics related to quantum mechanics include atoms, electrons, and nuclei. Experimental evidence for physics that is not explained by classical mechanics and E&M. Quantization of light, Planck's constant. Photoelectric effect, Compton and Bragg scattering. Bohr model, atomic spectra. Matter waves, wave packets, interference. Fourier analysis and transforms Heisenberg uncertainty relationships. Particle-in-a-box, simple harmonic oscillator, barrier penetration, tunneling. Topics related to thermodynamics: limitations of classical mechanics in describing systems with a very large number of particles. Ideal gas, equipartition, heat capacity, the definition of temperature, entropy. A brief introduction to kinetic theory and statistical mechanics. Maxwell speed distribution, ideal gas in a box. Laws of thermodynamics. Cycles, heat engines, free energy. Prerequisites:
Physics 61 and (
Math 51 or
Math 61CM). Corequisite:
Physics 43 or equivalent (e.g. AP Physics C E&M),
MATH 52 or 62CM. This course was offered as
PHYSICS 65 prior to Academic Year 2022-2023.
Terms: Win
| Units: 4
| UG Reqs: GER: DB-NatSci, WAY-FR, WAY-SMA
PHYSICS 71L: Modern Physics Laboratory
Experiments are drawn from optics, heat, and modern physics. Pre- or co-requisite:
Physics 71.
Terms: Win
| Units: 1
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