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Transcript
AP PHYSICS LEVEL C ELECTRICITY AND MAGNETISM Course Syllabus Parkland High School Teacher: Mr. Flueso Phone: 610-351-5600 ext. 73147 Email: [email protected] PHS course number: 447 Prerequisites: A final grade of B or better in AP Physics I, successful Completion of AP Physics C: Mechanics, must be taking or have taken Calculus. Course text: Fundamentals of Physics, Tenth Edition, Halliday, Resnick, Walker, 2014 Class website: http://teachersites.schoolworld.com/webpages/SFlueso/index.cfm Materials needed for each class: Pencil and pen, Physics notebook with extra paper, scientific calculator (preferably graphing), textbook, and all appropriate handouts announced. It is highly recommended (not required) that you have a tablet or laptop for this course because most of the homework is online. How you will be graded: You are expected to chart your progress and keep track of your own grade. Knowing your percentages in each category, the formula below may be used to calculate your own grade at any given time throughout the marking period. Percentage of Marking Period Grade Graded assignments 25% Laboratory 25% Class Participation 5% Tests and Quizzes 50% Total: 100% Tracking your grade: Home Access Center will be updated approximately one week following an assessment. There is also an Excel template available on my website that will calculate the grade for you if you would like faster information. Attendance policy: You are responsible to get the notes that you missed and complete whatever assignments you missed. You will not always be reminded. Making up missed work is your responsibility. If you cut class, you will receive a zero for whatever was completed on the day you cut. You are responsible to make up missed labs available on the Moodle portal, or set up a time to make labs up in the classroom. Use the class website and Moodle to keep up if you are out. You are expected to be aware of what was missed during an absence prior to returning to class. Notebook suggestions: Your notebook should be a three-ring binder of about 1.5-inch width. The notebook is not graded, however, the course is cumulative in nature, and the College Board requires that you keep a lab portfolio for this course. Classroom Rules 1. One person speaks at a time. You are to respect the instructor and one another at all times in the classroom. Raise your hand when you want to speak. Use good manners and be polite! 2. Act appropriately while in the classroom. This means no foul language or discussions that are not appropriate for school. No talking negatively about other people. No gossip or drama! 3. Hands off equipment. No touching any gadgets or equipment unless told to do so by an instructor. When you do use equipment, you may only use it for the intended use so that it does not break, and we keep everybody safe. 4. Keep the room clean and neat. This means no graffiti on any school property. Throw away all of your garbage. No food or drink in the classroom. Push chairs in nicely when you leave. *Rules and procedures may be changed if the instructor determines it is necessary. * In the event of a substitute or student teacher, the same rules, procedures, and expectations apply. Homework: Homework will often be collected and graded, or just checked for completion. Homework will not always be assessed. However, you will not always know when it will be assessed, so have it done! It is your responsibility to be aware of all assignments and progress before you return from an absence. Use the website, Moodle, and WileyPlus portal to print out any documents that were handed out during class. Quizzes: Pop quizzes may be given at any time. Extra Credit: Extra credit will be offered periodically by Mr. Flueso on a class-wide basis. Bonus assignments will be part of your “graded assignments” grade. What to do if you feel lost: If you ever become overwhelmed, or feel that you are falling far behind the class, please set up a time to meet with Mr. Flueso and discuss an action plan to get you back on track. Good luck! Course Overview AP Physics C is the second of a two year sequence that is designed to prepare students to take the AP Physics C examination. It begins by integrating the use of calculus (differentiation and integration) into the AP Physics B topics of mechanics and electricity & magnetism. This allows students to solve calculus based problems (SC8). This course emphasizes problem solving in the context of the principles of physical laws and principles; as well as the ability to apply that knowledge and skill to phenomenon in either an experimental or theoretical setting. Great attention is given to strengthening and reinforcing the natural connections between the sciences and with mathematics. Proper preparation to take this course includes the completion of Physics Honors, AP Physics B. While it is best if Calculus is completed prior to the start of this course; it is possible to take it in parallel if the student is able to commit additional time and effort. Students will be involved in problem solving activities on an individual, small group and large group basis. Through this process the ability to read and understand problems, break them down into their component parts and then create and present solutions will be developed. These same skills will be developed with activities in the physics laboratory. In that case, problem solving will be done in real time with hands-on problems. Much of the work done in the laboratory will include the gathering of data through PASCO electronic sensors. That data will be configured by the students using the PASCO software and then analyzed using that software as well as a number of compatible programs, including Excel and LoggerPro. Through this process both analytical techniques as well as technological capability will be developed. Course outline with timeline and laboratory list Unit/Chapters /Timeframe Unit I: Electrostatics Chapters: 21, 22, 23, 24, 25 Weeks: 1-8 Objectives and Experiments Students will be able to: 1. Employ Coulomb’s Law to determine the electrostatic forces between three or more electric charges located at arbitrary angles to one another. 2. Add electric fields which are oriented at arbitrary angles to one another. 3. Calculate the electric field of a ring charge, line charge, and charge distributed on the plane surface. 4. Calculate work done on the charge by an electric field. 5. Calculate the electric potential of an electric field with different configurations. 6. Use potential gradient in solving electric field problems. 7. Use Guass’s Law to determine the electric field strength nearby, and inside various conductors with various charge configurations. 8. Calculate the capacitance of capacitors with different shapes, with and without a dielectric. 9. Name common dielectrics and distinguish polar and non-polar dielectrics. 10.Calculate the capacitance in electric circuits. 11.Calculate the energy stored in capacitors. Associated Experiments: 1. Measure/estimate charge on a piece of tape. 2. Measure the charge of an electron (Oil Drop Experiment) 3. Coulomb’s Law experiment. 4. Electric Field Mapping activity 5. Measure the dielectric strength of different materials while building a capacitor. Unit II: Electric Current & Circuits Chapters: 26, 27 Weeks: 9-12 Students will be able to: 1. State the two types of electric charge, their sources, and how they interact. 2. Define and contrast insulators and conductors. 3. Describe the process of charging by conduction and induction. 4. Employ Coulomb’s Law to determine the electrostatic forces between two or more electric charges. 5. Define an electric field, and contrast it with electrostatic force. 6. Construct electric field lines for various charge distributions in both homework and laboratory exercises. 7. Define electrostatic potential, and potential difference. 8. Calculate the potential at points in the vicinity of one or more electric charges, and determine the work done by an electric field to move a test charge from one point to another. 9. Construct equipotential lines for various charge distributions in both homework and laboratory exercises. 10.Determine the capacitance of a parallel plate capacitor with, or without a dielectric, given the charge on plates, and the voltage across them. 11.Employ Coulomb’s Law to determine the electrostatic forces between three or more electric charges located at arbitrary angles to one another. 12.Add electric fields which are oriented at arbitrary angles to one another. Define and contrast voltage, current, resistance. 13.Employ Ohm’s Law to determine the voltage, current, and resistance of series and parallel DC circuits in both homework and laboratory exercises. 14.Determine the resistance of a DC circuit element when its composition, dimensions, and temperature are known. 15.Calculate the power generated and dissipated by various DC circuit elements when current, voltage, and resistance are known. 16.Determine the voltage and the charge on capacitors connected in series and in parallel combinations in a complete DC circuit. 17.Determine the emf of a power supply in a DC circuit that has an internal resistance. 18.Calculate the resistance, current and voltage in different electrical circuits. 19.Calculate power and work done by the electric current. 20.Calculate e.m.f and internal resistance in the electric circuit. 21.Use Kirchhoff’s rules to determine current and voltage distribution in electric circuits. 22.Calculate current, voltage and charge in RC circuits. Associated Experiments: 1. Students build simple circuits using batteries, bulbs, wires, and capacitors. 2. Students perform a full circuit lab using DMMs and examine Ohm’s Law and Kirchoff’s Rules. 3. Students investigate the internal resistance of batteries. 4. Students investigate resistivity of nichrome wire. 5. Students investigate RC discharge. Unit III: Magnetism and Electromagneti c Induction Chapters: 28, 29, 30, 31 Weeks: 13-18 Students will be able to: 1. Map magnetic field lines in the vicinity of one or more magnets. 2. State how the direction of the magnetic field is determined for fields generated by ferromagnetic materials, and electric currents. 3. Map magnetic field lines in the vicinity of electric current. 4. Calculate the strength of the magnetic field at a point in the vicinity of a straight wire or solenoid, and their directions using the right hand rule. 5. Determine the magnitude and the direction of force on an electric charge moving perpendicular to a uniform magnetic field. 6. Calculate the magnitude and direction of force between two current carrying wires. 7. Define magnetic flux through a surface. 8. Employ Faraday’s Law to determine the emf around a closed loop of wire when the flux changes due to change in field strength, or the orientation or size of the closed loop. 9. Explain the operation of motors, generators and galvanometers and their development with respect to Faraday’s work. 10.Explain how transformers work in AC circuits, and how they are advantageous in transmitting currents over long distance. 11.Add magnetic fields which are oriented at arbitrary angles. 12.Determine the force on a current carrying wire oriented at an arbitrary angle to a magnetic field. 13.Determine the force on a charged object whose velocity is at an arbitrary angle to a magnetic field. 14.Determine the force current carrying wires oriented at an arbitrary angle to each other. 15.Add magnetic fields which are oriented at arbitrary angles. 16.Determine the force on a current carrying wire oriented at an arbitrary angle to a magnetic field. 17.Determine the force on a charged object whose velocity is at an arbitrary angle to a magnetic field. 18.Determine the force current carrying wires oriented at an arbitrary angle to each other. 19. Use Gauss’s Law for magnetic field problems. 20. Calculate the magnetic field of a moving charge. 21. Calculate magnetic field of a current element. 22. Use Ampere’s Law to find magnetic field of conductors with different shapes. 23. Use the Biot-Savart Law to calculate the magnetic field produced by a current carrying wire. 24. Use Faraday’s Law to determine the induced current. 25. Define inductance and self inductance. 26. Calculate the magnetic field energy. 27. Calculate current and voltage in RL circuits. 28. Calculate current and voltage in RLC circuits. 29. Sketch graphs of potential and current through various components of an LC oscillator. 30. Sketch graphs of the magnetic field energy , the electric field energy, and the total energy for LC oscillators as a function of time. 31. Apply Maxwell’s Equations to calculate induced magnetic fields. Associated Experiments: 1. Students use compasses to explore fields produced by currents and permanent magnets. 2. One of the interesting experiments is to measure/estimate the dipole moment of a bar magnet. 3. Magnetic force on a dipole using Helmholtz coils and measurement of dipole moment. 4. Measurement of EMF generated by loop rotating in a magnetic field. 5. Measurement of c using resonant frequency of a wound toroid. 6. Investigation of RC, RL, LC, and RLC circuits using oscilloscopes and function generators.