I. General Information
1. Course Title:
College Physics II
2. Course Prefix & Number:
PHYS 1402
3. Course Credits and Contact Hours:
Credits: 4
Lecture Hours: 3
Lab Hours: 2
4. Course Description:
This course is an algebra-based introductory physics. It is a continuation of
PHYS 1401. The course topics include: Fluids, thermodynamics, electromagnetism, AC and DC circuit, electromagnetic waves and light, optics, modern physics including atomic and nuclear physics. In addition to the emphases placed in the first semester physics course, an oral presentation of the student project is required. Knowledge of trigonometry is needed for a successful completion of this course.
5. Placement Tests Required:
6. Prerequisite Courses:
PHYS 1402 - College Physics II
All Credit(s) from the following...
Course Code | Course Title | Credits |
MATH 1470 | College Algebra | 3 cr. |
PHYS 1401 | College Physics I | 4 cr. |
7. Other Prerequisites
Grade of “C” or higher in MATH 1470 or equivalent placement test score.
8. Prerequisite (Entry) Skills:
Operating a graphing calculator.
9. Co-requisite Courses:
PHYS 1402 - College Physics II
There are no corequisites for this course.
II. Transfer and Articulation
1. Course Equivalency - similar course from other regional institutions:
St. Cloud State University, PHYS 232 General Physics II, 4 credits
University of MN Duluth, PHYS 1002 Introduction to Physics II, 5 credits
III. Course Purpose
MN Transfer Curriculum (General Education) Courses - This course fulfills the following goal area(s) of the MN Transfer Curriculum:
Goal 3 – Natural Sciences
IV. Learning Outcomes
1. College-Wide Outcomes
College-Wide Outcomes/Competencies |
Students will be able to: |
Demonstrate oral communication skills |
Give presentation on an experimental project and on solutions to problems professionally. |
Demonstrate written communication skills |
Write scientific reports and solutions to physics problems competently. |
Work as a team member to achieve shared goals |
Carry out experiments, projects, or problem solving collaboratively as a group. |
2. Course Specific Outcomes - Students will be able to achieve the following measurable goals upon completion of
the course:
- Demonstrate understanding of laws of physics and physical principles by drawing conclusions based on the laws and principles applied to the given problems and situations. MnTC Goal 3
- Demonstrate understanding of scientific theories in physics by presenting analyses of problems and situations based on the theories. MnTC Goal 3
- Formulate and test hypotheses through laboratory experiments by designing apparatus, collecting data, analyzing statistically and graphically, and identifying sources of error and uncertainty. MnTC Goal 3
- Communicate the findings, analyses, and interpretations of experimental projects by oral presentations and in written reports. MnTC Goal 3
- Communicate the findings, analyses, and interpretations of lab experiments in written reports. MnTC Goal 3
- Evaluate societal issues from a physics perspective. MnTC Goal 3
- Ask questions about the physical evidence presented. MnTC Goal 3
- Make informed judgments about physics-related topics and policies. MnTC Goal 3
- Design two experimental apparatuses that demonstrate laws of physics or physics principles.
- Demonstrate the use of computers to acquire and analyze experimental data.
- Demonstrate the use of computational software to solve numerical problems in physics.
- Relate laws of physics and physical principles to natural phenomena in everyday life.
V. Topical Outline
Listed below are major areas of content typically covered in this course.
1. Lecture Sessions
- Fluid Statics and Dynamics
- Archimedes’ principle
- Bernoulli’s principle and conservation of mass and energy
- Thermodynamics
- Nature of many-body particle system in Ideal Gas Law, thermal energy
- Laws of Thermodynamics
- Efficiency
- Entropy
- Electricity
- Charges, electrostatics
- Electric current, electrodynamics
- Electric hazards
- Magnetism
- Magnetism
- Magnetic induction
- Electromagnet
- Electric generator
- AC and DC Circuit
- Circuit components
- Conservation of energy and charge
- Kirchhoff’s Laws
- Electromagnetic Waves and Light
- EM spectrum, dispersion, intensity
- Interference
- Diffraction
- Polarization
- Optics
- Index of refraction
- Geometric optics
- Images produced by mirrors and lenses
- Thin lens approximation
- Modern Physics
- Special theory of relativity
- Quantum mechanical principles
- Atomic Physics
- Atomic theory
- Quantized energy levels and emission and absorption spectra
- Matter waves
- Nuclear Physics
- Radioactivity, half-life
- Radiations, isotopes, radioactive dating
- Nuclear fission and fusion
- Radiation damage and therapy
- Magnetic resonance and imaging
2. Laboratory/Studio Sessions
- Archimedes’ Principle and Bernoulli's Equation
- Ideal Gas Law
- Thermal Expansion
- Latent Heats
- Electrostatics, Capacitance
- Magnetism and Magnetic Induction
- Electrical Resistance, Electric Circuits
- Electromagnetic Waves
- Optics: Mirrors and Lenses
- Diffraction, Interference
- Absorption and Emission Spectra
- Radioactivity
I. General Information
1. Course Title:
College Physics II
2. Course Prefix & Number:
PHYS 1402
3. Course Credits and Contact Hours:
Credits: 4
Lecture Hours: 3
Lab Hours: 2
4. Course Description:
This course is an algebra-based introductory physics. It is a continuation of
PHYS 1401. The course topics include: Fluids, thermodynamics, electromagnetism, AC and DC circuit, electromagnetic waves and light, optics, modern physics including atomic and nuclear physics. In addition to the emphases placed in the first semester physics course, an oral presentation of the student project is required. Knowledge of trigonometry is needed for a successful completion of this course.
5. Placement Tests Required:
6. Prerequisite Courses:
PHYS 1402 - College Physics II
All Credit(s) from the following...
Course Code | Course Title | Credits |
MATH 1470 | College Algebra | 3 cr. |
PHYS 1401 | College Physics I | 4 cr. |
7. Other Prerequisites
Grade of “C” or higher in MATH 1470 or equivalent placement test score.
8. Prerequisite (Entry) Skills:
Operating a graphing calculator.
9. Co-requisite Courses:
PHYS 1402 - College Physics II
There are no corequisites for this course.
II. Transfer and Articulation
1. Course Equivalency - similar course from other regional institutions:
St. Cloud State University, PHYS 232 General Physics II, 4 credits
University of MN Duluth, PHYS 1002 Introduction to Physics II, 5 credits
III. Course Purpose
2. MN Transfer Curriculum (General Education) Courses - This course fulfills the following goal area(s) of the MN Transfer Curriculum:
Goal 3 – Natural Sciences
IV. Learning Outcomes
1. College-Wide Outcomes
College-Wide Outcomes/Competencies |
Students will be able to: |
Demonstrate oral communication skills |
Give presentation on an experimental project and on solutions to problems professionally. |
Demonstrate written communication skills |
Write scientific reports and solutions to physics problems competently. |
Work as a team member to achieve shared goals |
Carry out experiments, projects, or problem solving collaboratively as a group. |
2. Course Specific Outcomes - Students will be able to achieve the following measurable goals upon completion of
the course:
- Demonstrate understanding of laws of physics and physical principles by drawing conclusions based on the laws and principles applied to the given problems and situations. MnTC Goal 3
- Demonstrate understanding of scientific theories in physics by presenting analyses of problems and situations based on the theories. MnTC Goal 3
- Formulate and test hypotheses through laboratory experiments by designing apparatus, collecting data, analyzing statistically and graphically, and identifying sources of error and uncertainty. MnTC Goal 3
- Communicate the findings, analyses, and interpretations of experimental projects by oral presentations and in written reports. MnTC Goal 3
- Communicate the findings, analyses, and interpretations of lab experiments in written reports. MnTC Goal 3
- Evaluate societal issues from a physics perspective. MnTC Goal 3
- Ask questions about the physical evidence presented. MnTC Goal 3
- Make informed judgments about physics-related topics and policies. MnTC Goal 3
- Design two experimental apparatuses that demonstrate laws of physics or physics principles.
- Demonstrate the use of computers to acquire and analyze experimental data.
- Demonstrate the use of computational software to solve numerical problems in physics.
- Relate laws of physics and physical principles to natural phenomena in everyday life.
V. Topical Outline
Listed below are major areas of content typically covered in this course.
1. Lecture Sessions
- Fluid Statics and Dynamics
- Archimedes’ principle
- Bernoulli’s principle and conservation of mass and energy
- Thermodynamics
- Nature of many-body particle system in Ideal Gas Law, thermal energy
- Laws of Thermodynamics
- Efficiency
- Entropy
- Electricity
- Charges, electrostatics
- Electric current, electrodynamics
- Electric hazards
- Magnetism
- Magnetism
- Magnetic induction
- Electromagnet
- Electric generator
- AC and DC Circuit
- Circuit components
- Conservation of energy and charge
- Kirchhoff’s Laws
- Electromagnetic Waves and Light
- EM spectrum, dispersion, intensity
- Interference
- Diffraction
- Polarization
- Optics
- Index of refraction
- Geometric optics
- Images produced by mirrors and lenses
- Thin lens approximation
- Modern Physics
- Special theory of relativity
- Quantum mechanical principles
- Atomic Physics
- Atomic theory
- Quantized energy levels and emission and absorption spectra
- Matter waves
- Nuclear Physics
- Radioactivity, half-life
- Radiations, isotopes, radioactive dating
- Nuclear fission and fusion
- Radiation damage and therapy
- Magnetic resonance and imaging
2. Laboratory/Studio Sessions
- Archimedes’ Principle and Bernoulli's Equation
- Ideal Gas Law
- Thermal Expansion
- Latent Heats
- Electrostatics, Capacitance
- Magnetism and Magnetic Induction
- Electrical Resistance, Electric Circuits
- Electromagnetic Waves
- Optics: Mirrors and Lenses
- Diffraction, Interference
- Absorption and Emission Spectra
- Radioactivity