Nov 24, 2024  
2022-2023 Catalog 
    
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2022-2023 Catalog [ARCHIVED CATALOG]

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PHYS 212 - Physics for Scientists and Engineers 2

Credits: 5
Lecture Contact Hours: 5
Lab Contact Hours: 2
Description: This second semester, calculus-based course is a continuation of PHYS 211 . Advanced topics such as electricity, magnetism, light and modern physics are investigated through lecture demonstration, simulations and laboratory work. This course is designed for engineering students and science majors.

Prerequisites: PHYS 211  with a minimum grade of 2.0.
Corequisites: None.
Recommended: None.

Course Category: Liberal Arts | Science with Lab
This course counts toward Schoolcraft’s General Education Requirements.
This course counts toward a Michigan Transfer Agreement General Education Requirement.

This Course is Typically Offered: Winter, Spring, Summer, Fall
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Course Competencies
  1. Analyze the thermodynamic efficiency of various engine cycles.
  2. Analyze thermodynamic processes using the first law of thermodynamics and the ideal gas law.
  3. Evaluate the electric force between point charges.
  4. Evaluate the electric field at a distance from a charged object.
  5. Sketch both electric field lines and equipotential lines around charged objects.
  6. Analyze the motion of a charge in terms of the electric field it encounters.
  7. Evaluate the electric potential at a distance from a charged object.
  8. Analyze the motion of a charge in terms of the electric potential it encounters.
  9. Analyze properties of simple AC and DC circuits.
  10. Relate the magnetic force on a moving charge to the magnetic field it encounters.
  11. Sketch the magnetic field near a current carrying wire.
  12. Evaluate the magnetic field at a distance from a current carrying wire.
  13. Relate the acceleration of charge to electromagnetic waves.
  14. Analyze the image formed by a system of lenses and/or mirrors.
  15. Use the principle of superposition to explain interference and diffraction effects for electromagnetic waves.
  16. Assign the appropriate SI unit to a physical characteristic.
  17. Use significant figures when reporting calculated values.
  18. Use a digital multimeter to measure current, voltage and resistance.
  19. Use DataStudio for data acquisition.
  20. Develop data tables and graphs to portray the results of experimental data collection.
  21. Use curve fitting to analyze data.
  22. Identify sources of experimental error.
  23. Develop a conclusion based on analysis of experimental data.


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