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Pascack Valley Regional HS District AP Physics B Syllabus Updated, September 2010 (Lecture-Discussion: four 47 min sessions per week; Labs 1 94 min investigation per week) Advance Placement Physics B course is algebra-based course in general Physics. It is equivalent to an introductory algebra-based university level physics course. Its syllabus is designed by the College Board and is often taken by students whose major field of study in college does not require an extensive knowledge of calculus. The course utilizes guided inquiry and student-centered learning to foster the development of critical thinking skills. The emphasis in the course is on understanding of the concepts and skills and using the concepts and formulae to solve problems. Laboratory work will be covered as an integral part of this course. The prerequisite for this course requires students to have earned a minimum grade of B+ in Honors physics and a recommendation from the Honors Physics teacher. Textbook Physics, Cutnell & Johnson; 7th Ed. New York: John Wiley, ISBN 0-471-66315-8 Student Supplemental Resource Online version of textbook including Wileyplus: www.wiley.com/college/wileyplus Teacher Supplemental Resources Summer Assignment [ Not applicable for 2010-11 school year] As an introduction to this colleague-level course and in order to get a head start on the material students will need to master for the AP Physics examination they must complete a two-part assignment: Assignment 1 - Self Study: reviews what students were required to master in Honors Physics I. Complete the assignment in pencil in a hardcover marble notebook. Show detailed work for each problem. During the course of the year student will be provided with assignments that will require them to learn at their own direction. This first “self-study” assignment will serve as practice for students. In September the class will review this assignment in detail and discuss individual learning styles and effective approaches for students to learn at their own direction. Assignment 2 – Project-Based Learning: provides students with an opportunity to apply the concepts of physics they learned in Honors Physics I. Students can expect to complete one design project each month in AP Physics. Typically, a design project requires students to research a particular concept or principle and then apply it by designing a device that utilizes the principle. Most design projects include a competitive component (10%) to a student’s score. Sample Summer Assignment Project a] Develop a good understanding of Hooke’s Law, gravitational potential energy, and kinetic energy. Begin with the text and then gather more info in a library or other sources. b] Complete the Bungee Egg Drop Design Project (attached) Bungee Egg Drop Objective Design and build a bungee drop cord and use it to drop an uncooked Grade-A Large chicken egg such that it approaches a target area as close as possible without breaking. The competition 1] The cord & report must be submitted during the first class session in September. Late or missing reports are assigned a grade of zero. 2] No physical alterations may be made to the device’s cord one it has been submitted. 3] You are required to drop your egg from two different heights as announced during the competition. This height will range from 2.0 - 4.0 meters. 4] The cord you design may be made of any material and more than one strand but, it must recoil at least 25% of the announced drop height. Eggs must be Grade A Large (Shopright brand eggs will be supplied by Mr. Bilash) 5] At least 2.0 cm of the pointed-end of the egg must extend beyond the attachment harness and may not be protected in anyway. 6] Once you are told what the drop height will be you will be given five minutes to prepare your device. (The time will be strictly limited). 7] The closer your egg arrives to the target area the higher your grade (closest = 10 points; furthest away = 1 point; breakage = 0 points). The score for this assignment is strictly competitive. (ie: only one student receives 10 points) 8] One device per person. Report Your device must be accompanied by a design report detailing how and why your device works, including scaled diagrams, an outline of the relevant equations/physics involved, data reflecting at least 24 trials, detailed calculations and an explanation. It is expected that your device will provide reproducible results. Reports must show experimental data based on your research and development of your device. For further information this problem is not original, check the Internet (Science Olympiad; science competitions; egg drop) or library for ideas and assistance one question per student may be emailed to me via email before August 15. Collaboration is encouraged, but remember the device will be tested competitively. Good luck and enjoy your summer! Grading Grades will be weighted as follows: Marking Period Exam 40% Quizzes 20% Homework 20% Laboratory work/reports 10% Projects 10% 1 per marking period 1 per week 20 problems per week + chapter outline 1 per week (due every Monday) 3 per marking period Quizzes may contain questions and/or problems from the homework, the reading assignments, and/or recently covered or previously learned material. Homework Problems Students should expect to complete between 20 problems per week (see attached assignment sheet) -- requiring between 8-12 hours of home study (per College Board guidelines). As a personal goal, students should complete each problem with 15 minutes. Homework must be submitted in two phases: half the questions are to be completed for Friday while the other half is due Monday. Each problem must be completed according to AP criteria: including diagram, relevant equations, set-up of equations, in step-by-step form and impeccably neat. Every problem must be completed in full. Students will earn one point per question. Homework constitutes 20% of your final grade. Answers to odd-numbered questions may be found at the end of the text. A complete solution manual is available for your perusal in the Physics Office -- however, it may not be removed or reproduced. Assigned Reading & Chapter Outlines The assigned chapter should be read prior to the first meeting of each week to prepare for meaningful classroom discussion. A detailed chapter outline must be submitted at the start of each unit (usually on Mondays). Laboratory Work/Reports Students will complete on average one laboratory experiment per week. Most of the lab experiments are open-ended: The students are given an objective and a list of equipment. Students design their own procedure, data gathering, and data analysis. Generally, reports will be submitted for grading on Mondays. Reports are to be typed and must include the following elements: Objective, Theory & Hypothesis, Methods and Materials, Data and Analysis, Discussion and Conclusion. Students will be expected to maintain a Digital Portfolio of all of their lab reports on their laptops and backed-up to the district network drive. Learning Objectives Motion in 1-D • Describe a frame of reference • Compare and contrast Aristotle and Galileo’s views of motion • Define and apply definitions of displacement, average velocity, instantaneous velocity, and average acceleration • Demonstrate proficiency in solving problems using kinematics equations, including problems involving free fall by using the value of the acceleration due to gravity Vectors & 2-D • Analyze motion graphs qualitatively and quantitatively, including calculations of the slope of the tangent of an x-versus-t graph, the slope of the v-versus-t graph, the area under the v-versus-t graph and the area under the a-versus-t graph • Distinguish between vectors and scalars • Add vectors using graphical methods: parallelogram and polygon methods • Add vectors using the component method of vector addition • Describe the horizontal and vertical motion of a projectile • Demonstrate proficiency in solving problems of situations involving projectiles fired horizontally and at an angle • Apply the concepts of vectors to solve problems involving relative velocity. Laws of Motion • Distinguish between contact forces and field forces by identifying the agent that causes the force • Distinguish between mass and weight, and calculate weight using the acceleration due to gravity • Differentiate between static and kinetic friction • State and apply Newton’s first law of motion for objects in static equilibrium • Demonstrate proficiency in accurately drawing and labeling free-body diagrams • State and apply Newton’s second law of motion • Demonstrate proficiency in solving problems that involve objects in motion with constant acceleration by analyzing the resultant force(s) in horizontal surfaces, inclined planes, and pulley systems (Atwood’s machines) • State and apply Newton’s third law of motion • State and apply Newton’s law of universal gravitation • Describe Cavendish’s experiment to determine the value of the universal gravitation constant • Derive the acceleration due to gravity at the surface of the earth or other planets • Explain and apply the relationship between the speed and the orbital radius of a satellite • Demonstrate proficiency in solving problems involving apparent weightlessness in a satellite and in an elevator • State Kepler’s three laws of planetary motion • Derive and apply Kepler’s third law of planetary motion Work & Energy • Define and apply the concepts of work done by a constant force, potential energy, kinetic energy, and power • Calculate the work from the area under the curve of a force-versus-displacement graph • Distinguish between conservative and non-conservative forces • State and apply the principle of conservation of mechanical energy • Demonstrate proficiency in solving problems by applying the work–energy theorem to situations that involve conservative and non-conservative forces Linear Momentum • Define and give examples of impulse and momentum • Restate Newton’s second law of motion in terms of momentum • Calculate the change in momentum from the area under the curve of a force versus time graph • Derive a statement of the conservation of momentum between two objects by applying Newton’s third law Collisions • Define and recognize examples of elastic and inelastic collisions • Explain which conservation laws apply to each type of collisions • Demonstrate proficiency in solving problems involving conservation of momentum in collisions in one and two dimensions Circular Motion • Explain the characteristics of uniform circular motion • Derive the equation for centripetal acceleration of an object moving in a circle at constant speed • Understand that centripetal force is not a new type of force • Understand that centrifugal force does not exist • Demonstrate proficiency in solving problems involving banking angles, the conical pendulum and motion in a vertical circle Rotation • Define and calculate the torque of a given force about an axis of rotation • State the two conditions of equilibrium (translational and rotational) and apply them to solve for unknown forces and/or distances in a variety of situations Simple Harmonic Motion • Define and identify the following terms on a displacement-versus-time graph: equilibrium position, amplitude, period, and frequency • Define simple harmonic motion • Use the reference circle to describe the displacement, velocity and acceleration • Describe and apply Hooke’s law and Newton’s second law to determine the acceleration as a function of displacement • Apply the principles of conservation of mechanical energy for an object moving with simple harmonic motion • Derive and apply the equation to obtain the period of a mass–spring system • Derive and apply the equation to obtain the period of a simple pendulum • Demonstrate proficiency in solving problems involving horizontal and vertical mass–spring systems • Define resonant frequency and give examples of resonance Fluids • Define atmospheric pressure, gauge pressure, and absolute pressure, and the relationship among these terms • Define and apply the concept of fluid pressure • State and apply Pascal’s principle in practical situations such as hydraulic lifts • State and apply Archimedes’ principle to calculate the buoyant force • Demonstrate proficiency in accurately drawing and labeling free-body diagrams involving buoyant force and other forces • State the characteristics of an ideal fluid • Apply the equation of continuity in solving problems • Understand that Bernoulli’s equation is a statement of conservation of energy • Demonstrate proficiency in solving problems involving changes in depth and/or changes in pressure and/or changes in velocity Thermal Physics • Understand and apply the mechanical equivalent of heat • Describe the condition for thermal equilibrium and define temperature • Define the coefficient of linear expansion and apply the equation to calculate linear thermal expansion Heat • Explain the mechanisms of heat transfer: conduction, radiation, and convection • Demonstrate proficiency in solving problems involving thermal conductivity Kinetic Theory & Thermodynamics • State and apply the gas laws: Boyle’s, Charles’s and Gay Lussac’s • Apply the Ideal Gas law and the General Gas law to the solution of problems involving changes in volume, pressure, and temperature • State the postulates of the kinetic theory • Understand that the average translational energy of molecules in a gas is directly proportional to the absolute temperature • State and apply the first law of thermodynamics • Define and illustrate the four thermodynamic processes: isothermal, adiabatic, isovolumetric, isobaric process • Calculate of the work done by graphical methods • State and understand the implications of the second law of thermodynamics • Describe a typical heat engine and define the efficiency of a heat engine • Understand a Carnot engine and how its efficiency is expressed in terms of the Kelvin temperatures between which it operates • Demonstrate proficiency in solving problems related to thermodynamic processes • Calculate of the work done by graphical methods • State and understand the implications of the second law of thermodynamics • Describe a typical heat engine and define the efficiency of a heat engine • Understand a Carnot engine and how its efficiency is expressed in terms of the Kelvin temperatures between which it operates • Demonstrate proficiency in solving problems related to thermodynamic processes Electric Forces & Fields • Define electrostatics and the nature of an electric charge • State the law of electrostatics and the law of conservation of charge • State Coulomb’s law and its equation to calculate the electrostatic force between two charges • Explain the charging of an object by contact and by induction • Distinguish between conductors and insulators • Understand the distribution of charge in a conductor • Define the permittivity of free space • Define the electric field and derive for a single point charge • Describe electric field lines as means to depict the electric field • Demonstrate proficiency in solving problems involving electric charges by applying appropriate vector addition methods • Understand that equipotential lines are perpendicular to electric field lines Electric Potential Energy & The Electric Potential • Define and apply the concepts of electric potential energy, electric potential, and electric potential difference • Describe and apply the relationship of the potential difference between two points to the uniform electric field existing between the points • Demonstrate proficiency in solving problems involving the calculation of the total potential at any point in the vicinity of a number of known charges • Demonstrate proficiency in solving problems involving the calculation of the work required to move a known charge from one point to another • Apply a relationship between the electric field and the potential difference in a parallel plate configuration • Define capacitance and apply the equation to calculate the total charge • Understand and apply the fact that the capacitance depends on the geometry of the capacitor: area and separation between the plates • Calculate the equivalent capacitance of capacitors connected in series and in parallel • Determine the energy stored in a parallel plate capacitor Electric Circuits • Define electric current as the rate of flow of charge • Understand some reasons for the conventional direction of electric current • Explain the term emf (electromotive force) and what is a source of emf • Define resistance and the factors affecting the resistance of a conductor • State and apply Ohm’s law • Understand and apply the equation of electric power as the rate of energy transferred in the form of heat • Draw schematic diagrams of circuits, including measuring devices such as ammeters and voltmeters • Analyze series and parallel circuits and demonstrate proficiency in calculations of equivalent resistance, current, and voltage drop • Calculate the terminal voltage, taking into account the internal resistance of a battery • State and apply Kirchhoff’s laws to solve complex networks • Analyze circuits with resistors and capacitors (steady state) and demonstrate proficiency in calculations of equivalent resistance, current, and voltage drop Current & Resistance DC Circuits Magnetic Forces & Fields • Describe the magnetic fields created by magnets • Calculate the magnetic force exerted on a moving charge and determine the direction of the magnetic field, the velocity of the charge, and the magnetic force by using a right-hand-rule • Calculate the magnetic force on a current carrying wire (or loop of wire) and determine the direction of the magnetic field, the current, and the magnetic force by using a right-hand-rule • Calculate the magnetic force on a long, straight wire and determine the direction of the magnetic field, the current, and the magnetic force by using a right-hand rule • Determine the magnitude and direction of the magnetic force between two parallel wires Electromagnetic Induction • Describe Faraday’s experiments that led to the conclusion that a changing magnetic field induces an emf • State Faraday’s law of induction and Lenz’s law • Demonstrate proficiency in solving problems involving an induced emf in cases where the magnetic flux density changes and in cases where the area of a loop of wire is changed • Apply Lenz’s law to determine the direction of the induced current in a variety of situations including motional emf Waves & Sound • Define and give characteristics and examples of longitudinal, transverse, and surface waves • Apply the equation for wave velocity in terms of its frequency and wavelength • Describe the relationship between energy of a wave and its amplitude • Describe the behavior of waves at a boundary: fixed-end, free-end, boundary between different media • Demonstrate proficiency in solving problems involving transverse waves in a string • Distinguish between constructive and destructive interference • State and apply the principle of superposition • Describe the formation and characteristics of standing waves • Describe the characteristics of sound and distinguish between ultrasonic and infrasonic sound waves • Calculate the speed of sound in air as a function of temperature • Describe the origin of sound in musical instruments • Use boundary behavior characteristics to derive and apply relationships for calculating the characteristic frequencies for an open pipe and for a closed pipe • Explain the interference of sound waves and the formation of beats • Apply the Doppler effect to predict the apparent change in sound frequency Electromagnetic Waves • Explain how electromagnetic waves are produced • Describe the electromagnetic spectrum and the relationship between frequency, wavelength, and speed of electromagnetic waves • Describe Roemer and Michelson’s experiment to determine the speed of light • Explain the dispersion of light and the visible spectrum Interference & Wave Nature of Light • State the conditions for constructive interference and destructive interference Describe Young’s double-slit experiment and apply the results of the experiment to predict the location of bright and dark fringes • Describe the pattern observed by the use of a diffraction grating • Demonstrate proficiency in solving problems involving the use of a single slit, a double slit and a diffraction grating • Explain and apply the characteristics of thin-film interference using the concepts of boundary behavior • Calculate the thickness of a film Reflection of Light – Mirrors • Discuss the evidence supporting the ray model of light • State and apply the law of reflection • Define the following terms for spherical mirrors: principal axis, focal point, and focal length • Demonstrate proficiency in the use of ray diagrams to find the image of an object using a converging and a diverging mirror • Understand how mirrors form real and virtual images • Demonstrate proficiency in solving problems that use the mirror equation to calculate the focal length of a mirror, image distance, image height, and the magnification • Explain what is meant by spherical aberration Refraction of Light – Lenses & Optical Instruments • Define the index of refraction and describe the behavior of refracted light • Apply Snell’s law to the solution of problems • Explain the concepts of critical angle and total internal reflection • Demonstrate proficiency in the use of ray diagrams to find the image of an object using a converging and a diverging lens and a combination of lenses • Understand how lenses form real and virtual images • Demonstrate proficiency in solving problems that use the lens equation to calculate the focal length of a lens, image distance, image height, and the magnification Atomic Physics & Quantum Effects • Describe Thomson and Millikan’s experiments related to the electron • Discuss the basics of Planck’s hypothesis • Define a photon and relate its energy to its frequency and/or wavelength • Convert energy units: joules to electronvolts and vice versa • Demonstrate proficiency in solving problems involving the energy of a photon and the conservation of momentum in photon interactions • Explain the characteristics of the photoelectric effect and define the terms “work function” and “threshold frequency” • Given a graph of energy versus frequency, understand the meaning of the slope, the x-intercept, and the y-intercept • Demonstrate proficiency in solving problems involving the calculation of the maximum kinetic energy of photoelectrons • Understand the nature and production of X-rays • Describe the results of the collision of an X-ray photon with an electron (Compton effect) and the results of the scattering of X-rays from a crystal (Davisson–Germer experiment) • Understand the dual nature of light and matter, and apply de Broglie’s equation to calculate the wavelength of a particle • Describe how atomic spectra are produced • Demonstrate proficiency in drawing and interpreting energy-level diagrams • Calculate the energy absorbed or emitted by an atom when an electron moves to a higher or lower energy level Nuclear Physics & Elementary Particles • Describe the structure and properties of the nucleus • Apply Einstein’s equation of mass energy equivalence • Calculate the mass defect and the total binding energy of the nucleus • Understand the origin of the strong and weak nuclear forces • Describe three types of radiation emitted in radioactivity: alpha decay, beta radiation and gamma radiation • Understand how nuclear reactions are produced • Define the following terms: threshold energy, chain reaction, and critical mass • Explain the process of nuclear fission and the basic operation of a nuclear reactor • Describe a chain reaction • Explain the process of nuclear fusion and how magnetic and inertial confinements • can provide thermonuclear power Laboratory Experiments 1. Motion in One Dimension Objective: To analyze the motion of objects moving at constant speed and at uniform accelerated motion. Data should be collected to produce a graph of x versus t and use the graph to plot a v- versus t-graph for each object. Equipment: A video camera to record the motion of various objects: a bowling ball rolling on a carpet and a dynamics car on a track, LoggerPro3 to perform video analysis Type of Lab: Open-ended Allotted Time: 90 minutes 2. Vector Addition Objective: To compare the experimental value of a resultant of several vectors to the values obtained through graphical and analytical methods. Equipment: A force table set Type of Lab: Open-ended Allotted Time: 30 minutes 3. Projectile Motion Objective: To determine the initial velocity of a projectile and the angle at which the maximum range can be attained. Equipment: A projectile launcher and a meter stick Type of Lab: Open-ended Allotted time: 50 minutes B. Newton's Laws Of Motion Laboratory Experiments: 4. Atwood’s Machine: Newton’s Second Law Objective: To determine the acceleration of a system and the tension in the string. Equipment: Modified Atwood’s machine: dynamics cart and track, meter stick, stopwatch or photogate, and a set of masses Type of Lab: Open-ended Allotted Time: 50 minutes 5. Frictional Forces Objective: Determination of static and kinetic coefficients of friction using two different methods. Equipment: Rectangular blocks of different materials (felt and wood), spring scale, wooden board that can be used as an inclined plane, protractor Type of Lab: Open-ended Allotted Time: 50 minutes C. Work, Energy, Power Reading/Homework Assignments: Selected items from Chapter 6 Physlet problems: 6.9, 6.11, 7.4, and 7.6 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 6. Conservation of Mechanical Energy Objective: To determine the velocity of a system in order to verify the conservation of mechanical energy. Equipment: Modified Atwood’s machine: dynamics cart and track, a set of masses, meter stick and stopwatch or photogate. Type of Lab: Open-ended Allotted Time: 50 minutes D. Systems Of Particles, Linear Momentum Reading/Homework Assignments: Selected items from Chapter 7 Physlet® problems: 8.6 and 8.9 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 7. Conservation of Linear Momentum Objective: To determine the velocity of each glider before and after a collision. Equipment: Air track set. Type of Lab: Open-ended Allotted Time: 50 minutes E. Circular Motion And Rotation Reading/Homework Assignments: Selected items from Chapters 5 and 8 Physlet problem: 3:15 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 8. Centripetal Force Objective: To determine the velocity of a flying toy and the tension in the string. Equipment: Holy Cow or Flying Pig, a meter stick, and a triple-beam balance Type of Lab: Open-ended Allotted Time: 30 minutes F. Oscillations And Gravitation Reading/Homework Assignments: Selected items from Chapters 5, 6, and 11 Physlet problems: 4.11, 5.5, 5.7, 16.5, and 16.7 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 9. Potential Energy Investigation: Spring and Gravitational. Objective: To determine the spring constant of the spring, the evaluation of the extent to which the change in gravitational potential energy of the mass is equal to the change in the spring potential energy. Equipment: Hooke’s law apparatus, a set of masses, and a meter stick. Type of Lab: Open-ended Allotted Time: 50 minutes 10. Kepler's Laws Objective: To plot a planetary orbit and apply Kepler’s Laws Equipment: Worksheet with planetary data and polar graph paper Type of Lab: Teacher directed Allotted Time: None in class; this lab exercise is given as a homework assignment. 7 II. Fluid Mechanics And Thermal Physics [C2] Instructional Time: 4 weeks A. Fluid Mechanics Reading/Homework Assignments: Selected items from Chapter 10 Physlet problems: 14.1, 14.3, and 15.7 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 11. Archimedes’ Principle Objective: To determine the density of two unknown materials. Equipment: Triple-beam balance, overflow can, beaker, various metal objects and string Type of Lab: Open-ended Allotted Time: 30 minutes 12. Torricelli’s Theorem Objective: To determine the exit velocity of a liquid and to investigate the range attained with holes at varying heights. Equipment: Clear plastic bottle with three holes at various heights, plastic container, water, and meter stick. Type of Lab: Open-ended Allotted Time: 50 minutes 8 B. Temperature and Heat Reading/Homework Assignments: Selected items from Chapters 13 and 14 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiment: 13. Coefficient of Linear Expansion Objective: To determine the coefficient of linear expansion of two metal rods. Equipment: Linear expansion apparatus Type of Lab: Teacher directed Allotted Time: 50 minutes C. Kinetic Theory and Thermodynamics Reading/Homework Assignments: Selected items from Chapters13 and 15 Physlet problems: 21.11 and 21.5 Learning Objectives: At the end of this unit the student should be able to: 9 • Calculate of the work done by graphical methods • State and understand the implications of the second law of thermodynamics • Describe a typical heat engine and define the efficiency of a heat engine • Understand a Carnot engine and how its efficiency is expressed in terms of the Kelvin temperatures between which it operates • Demonstrate proficiency in solving problems related to thermodynamic processes Laboratory Experiments: 14. The Ideal Gas Law Objective: To verify that the pressure of a gas (air) at a fixed temperature is inversely proportional to the gas volume, to verify that the volume of a gas at a fixed pressure is proportional to the gas temperature and to determine an experimental value for a constant that relates the temperature in Celsius to the absolute temperature. Equipment: Boyle’s law apparatus, a set of masses, thermometer, heating plate, and ice Type of Lab: Open-ended Allotted Time: 50 minutes III. Electricity and Magnetism [C3] Instructional Time: 8 weeks A. Electrostatics Reading/Homework Assignments: Selected items from Chapters 16 and 17 Physlet problems: 23.8 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 15. Coulomb’s Law Objectives: To determine the charge on two spherical polystyrene balls Equipment: Polystyrene balls, string, stand, and a meter stick Type of Lab: Open-ended Allotted Time: 20 minutes 16. Equipotential Lines and Electric Fields Objectives: To map both the potentials and the electric fields around a system of twodimensional, charged conductors. Equipment: Field mapper kit Type of Lab: Teacher-directed Allotted Time: 50 minutes B. Conductors and Capacitors Reading/Homework Assignments: Selected items from Chapters 16, 17, and 19 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 17. Static Electricity Investigation Objective: To make qualitative observations of the behavior of an electroscope when it is charged by conduction and by induction . Equipment: Electroscope and electrostatic materials set Type of Lab: Open-ended Allotted Time: 30 minutes C. Electric Circuits Reading/Homework Assignments: Selected items from Chapters 18 and 19 Physlet problems: 30.1 a–e and 30.3 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 18. Series and parallel circuits Objective: To investigate the behavior of resistors in series, parallel, and series-parallel circuits. The lab should include measurements of voltage and current. Equipment: Circuit board set, voltmeter, ammeter, and batteries Type of Lab: Open-ended Allotted Time: 90 minutes D. Magnetic Fields Reading/Homework Assignments: Selected items from Chapter 20 Physlet problems: 27.8 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 19. Magnetic Field Investigation Objectives: To map the magnetic field around a bar magnet and to determine the strength of the magnetic field . Equipment: Bar magnet, compasses, meter stick and protractor Type of Lab: Open-ended Allotted Time: 30 minutes 13 E. Electromagnetism Reading/Homework Assignments: Selected items from Chapter 21 Physlet problems: 29.3 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 20. Electromagnetic Induction Objectives: To qualitatively examine the effects of changing magnetic field by observing currents induced in a solenoid and to determine whether your observations agree with the theory of electromagnetic induction and Lenz’s law. Equipment: Power supply, galvanometer, bar magnet, and solenoid Type of Lab: Open-ended Allotted Time: 30 minutes IV. Waves and Optics [C4] Instructional Time: 4 weeks A. Wave Motion and Sound Reading/Homework Assignments: Selected items from Chapters 11 and 12 Physlet problems: 17.4, 18.12, and 18.14 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 21. Standing Waves in a String Objective: To determine the experimental value of the frequency by means of a graph of collected data. Equipment: Electric string vibrator, string, pulley with rod support, meter stick and set of masses Type of Lab: Teacher-directed Allotted Time: 90 minutes B. Physical Optics Reading/Homework Assignments: Selected items from Chapters 22 and 24 Learning Objectives: At the end of this unit the student should be able to: • Explain how electromagnetic waves are produced • Describe the electromagnetic spectrum and the relationship between frequency, wavelength, and speed of electromagnetic waves • Describe Roemer and Michelson’s experiment to determine the speed of light • Explain the dispersion of light and the visible spectrum • State the conditions for constructive interference and destructive interference • Describe Young’s double-slit experiment and apply the results of the experiment to predict the location of bright and dark fringes • Describe the pattern observed by the use of a diffraction grating • Demonstrate proficiency in solving problems involving the use of a single slit, a double slit and a diffraction grating • Explain and apply the characteristics of thin-film interference using the concepts of boundary behavior • Calculate the thickness of a film Laboratory Experiments: 22. Interference Objective: To determine the wavelength of a source of light by using a double slit and a diffraction grating of known spacing. Equipment: He-Ne Laser, slits, and meter stick Type of Lab: Open-ended Allotted Time: 50 minutes C. GEOMETRIC OPTICS Reading/Homework Assignments: Selected items from Chapter 23 Physlet problems: 33.4, 34.4, and 35.4 Learning Objectives: At the end of this unit the student should be able to: Laboratory Experiments: 23. Index of Refraction Objectives: To determine the index of refraction of an acrylic block Equipment: Optics bench, ray table, light source and acrylic block Type of Lab: Open-ended Allotted Time: 30 minutes 24. Mirrors and Lenses Objectives: This lab is divided into two sections: 1. Using a concave mirror, determine three locations where a real image can be formed and one where a virtual image is formed. 2. Determine the focal length of a converging lens directly and the focal length of a diverging lens by combining it with a converging lens. Equipment: Optics bench, set of lenses and mirrors, light source Type of Lab: Open-ended Allotted Time: 50 minutes V. Atomic and Nuclear Physics [C5] Instructional Time: 2 weeks A. Atomic Physics And Quantum Effects Reading/Homework Assignments: Selected items from Chapter 27 Learning Objectives: At the end of this unit the student should be able to: • Describe Thomson and Millikan’s experiments related to the electron • Discuss the basics of Planck’s hypothesis • Define a photon and relate its energy to its frequency and/or wavelength • Convert energy units: joules to electronvolts and vice versa C5—Evidence of Curricular Requirement: Atomic and nuclear physics 17 • Demonstrate proficiency in solving problems involving the energy of a photon and the conservation of momentum in photon interactions • Explain the characteristics of the photoelectric effect and define the terms “work function” and “threshold frequency” • Given a graph of energy versus frequency, understand the meaning of the slope, the xintercept, and the y-intercept • Demonstrate proficiency in solving problems involving the calculation of the maximum kinetic energy of photoelectrons • Understand the nature and production of X-rays • Describe the results of the collision of an X-ray photon with an electron (Compton effect) and the results of the scattering of X-rays from a crystal (Davisson–Germer experiment) • Understand the dual nature of light and matter, and apply de Broglie’s equation to calculate the wavelength of a particle • Describe how atomic spectra are produced • Demonstrate proficiency in drawing and interpreting energy-level diagrams • Calculate the energy absorbed or emitted by an atom when an electron moves to a higher or lower energy level Laboratory Experiments: 25. Photoelectric Effect Objective: Using a simulation, collect data to create a graph that will allow you to find the value of Planck’s constant for three different metals. Equipment: Photoelectric effect simulation: http://www.walter-fendt.de/ph11e/photoeffect.htm Type of Lab: Virtual lab Allotted Time: 50 minutes B. Nuclear Physics Reading/Homework Assignments: Selected items from Chapters 30 and 31 Learning Objectives: At the end of this unit the student should be able to: • Describe the structure and properties of the nucleus • Apply Einstein’s equation of mass energy equivalence • Calculate the mass defect and the total binding energy of the nucleus • Understand the origin of the strong and weak nuclear forces 18 • Describe three types of radiation emitted in radioactivity: alpha decay, beta radiation and gamma radiation • Understand how nuclear reactions are produced • Define the following terms: threshold energy, chain reaction, and critical mass • Explain the process of nuclear fission and the basic operation of a nuclear reactor • Describe a chain reaction • Explain the process of nuclear fusion and how magnetic and inertial confinements • can provide thermonuclear power Homework Calendar First Marking Period Date Sept 8-11 Topic Motion in 1-D Ch. 1 & 2 (all sections) Wed., Sept 9 Sept 14-18 Project: Bungie Egg Drop Ch. 3: 6, 10, 12, 16, 17, 18, 20, Vectors & 2-D Motion 22, 40, 42, 50 Ch. 3.1-3.5 Ch. 4: 1, 4, 6, 8, 14, 16, 18, 20, Laws of Motion Ch. 4.1-4.6 22, 25, 26, 28, 30, 36 Sept 21-25 (no school Sept. 21) Sept 28- Oct 2 (no school Sept. 30) Laws of Motion Ch. 4.7 In-Class Examples Ch 2: 4, 6, 14, 16, 18, 20, 24, 26, 32, 36, 49 Ch 4: 40, 43, 48, 54, 56 Friday, Oct. 2 Oct 5-9 Project: Catapult Design Ch. 5: 3, 4, 6, 8, 12, 12, 14, 20, Work & Energy Ch. 5.1-5.8 22, 24, 29, 35, 46 Oct 12-16 Momentum Ch. 6.1 - 6.2 Ch. 6: 2, 4, 6, 7, 10 Oct 19-23 Collisions Ch. 6.2 - 6.4 Ch. 6: 15, 18, 20, 22, 24, 26, 64, 67 Oct 26-30 Circular Motion Ch. 7.1-7.7 Ch. 7: 1, 6, 10, 12, 18, 22, 29, 37, 40, 56 Nov 2-6 Ch. 8: 2, 4, 10, 12, 14 Rotation Ch. 8.1-8.4 Project: Mobile Design Exam (ch 1-8) (NJ Science Teachers’ Convention Oct 12-14) Friday, Nov. 6 Nov. 9 & 10 Homework Ch. 1: 1, 3, 5, 7, 9, 11, 13, 15, 19, 21, 23, 25, 29, 31, 35, 37, 39, 43, 45, 47 Ch. 2: 1, 3, 5, 7, 9, 11, 13, 15, 17, 21, 25, 27, 29, 31, 37, 39, 41, 43, 45, 47, 53 Ch. 3: 5, 7, 9, 11, 13, 15, 19, 21, 23, 39, 41, 44, 48, 51, 55 Ch 4: 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 27, 31, 33, 35, 37 Ch. 4: 39, 41, 42, 45, 47, 51, 53, 55, 57, 59, 60, 61, 62, 63, 66, 69, 71, 72, 73, 78, 81, 83 Ch. 5: 2, 5, 7, 9, 10, 11, 13, 17, 19, 23, 25, 26, 28, 30, 31, 32, 36, 37, 39, 40, 41, 43, 45, 47, 48, 49, 51, 53 Ch. 6: 1, 3, 5, 8, 9, 11, 12, 13, 14 Ch. 6: 16, 17, 19, 21, 23, 25, 27, 29, 31, 33, 35, 37, 39, 40, 44, 47, 49, 53, 55, 58, 60, 62 Ch. 7: 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 31, 33, 35, 36, 39, 53, 55, 61, 67, 69 Ch. 8: 1, 3, 5, 9, 11, 13, 19, 67, 68, 69 Unless otherwise directed: Chapter should be read prior to coming to Monday’s class Rough draft of weekly homework assignments due every Friday Homework notebook due every Monday Quiz on previous week’s material every Monday Lab reports are due Mondays Second Marking Period Date Nov 16-20 Nov 23-25 (short week) Nov 30 - Dec 4 Dec 7-11 Sat., Dec 12 Dec 14-18 Dec21-23 (short week) Jan 4-8 Friday, Jan. 8 Jan 11-15 Jan 19-22 (short week) Jan 21 & 22 Jan 26 & 27 Topic In-Class Examples Thermal Physics 2, 12, 16, 26, 40, 9.1 10.1- 10.5 Heat 2, 4, 14, 28, 36, 37 11.1-11.5 Thermodynamics From Handout 12.1-12.7 Electric Forces & 1, 4, 10, 14, 16, 20, 26, 32, 40, 46, Fields 56, 62 15.1-15.7, 15.9 Design Project Due: Physics Olympic Projects Energy & 6, 8, 16, 22, 26, 28, 30, 40, 44, 50, Capacitance 52, 58, 68 16.1-16.4, 16.5-16.9 Current & Resistance 2, 6, 14, 20, 30, 40, 46, 56 17.1-17.8 DC Circuits 2, 10, 12, 14, 22, 24, plus those from 18.1-18.5 handout Design Project Due Magnetism 19.1-19.4, 19.719.11 Inductance 20.1-20.3 2 MP Exam Exam (1st & 2nd MP) Homework 1, 5. 8, 11, 13, 15, 17, 18, 21, 23, 25, 27, 29, 31, 33, 35, 37, 39, 41, 43, 45, 49, 51, 57, 61, 63, 65 1, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, 31, 33, 35, 39, 41, 57 3, 5, 7, 9, 11, 13, 15, 17, 19, 23, 27, 29, 31, 33, 35, 37, 51, 53, 61 3, 5, 7, 9, 12, 13, 15, 17, 19, 21, 23, 25, 27, 29, 33, 35, 37, 39, 41, 45, 47, 49, 51, 53, 59, 61 1, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 29, 31, 33, 37, 39, 41, 43, 45, 47, 49, 50, 51, 53, 55, 57, 59 1, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 31, 33, 39, 41, 47, 49, 51, 55 1, 3, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, 31, 33, 37, 41, 43, 45, 47, 51, 57, 61 2, 4, 14, 20, 24, 28, 38, 42, 48, 54, 56 1, 3, 5, 7, 11, 13, 19, 21, 25, 29, 33, 35, 37, 41, 45, 49, 51, 53, 55, 57, 69 2, 10, 26, 30, 3, 5, 7, 9, 11, 19, 27, 31, 33, 35, Third Marking Period Date Feb 1-5 Feb 8-12 Feb 28-Mar3 March 6-10 March 13-17 March 20-24 March 27-31 Apr 7 & 8 Topic Vibration & Waves Ch. 13 Sound Ch. 14 Design Project Reflection & Refraction Ch. 22 Mirrors & Lenses Ch. 23 Wave Optics Ch. 24 Quantum Physics Ch. 27: 1-3, 9 Atomic Physics Ch. 28: 1-5 Design Project Nuclear Physics & Elementary Particles Ch. 29 & 30 3 MP Exam In-Class Examples 2, 6, 8, 12, 16, 20, 22, 26, 32, 34, 40, 44, 50 2, 10, 18, 21, 24, 28, 32, 38, 44, 48, 50 Homework 3, 5, 7, 9, 11, 13, 15, 19, 21, 25, 27, 33, 37, 39, 43, 45, 51, 53, 57, 65, 71 1, 5, 7, 9, 14, 17, 23, 25, 29, 31, 39, 41, 43, 45, 47, 57 6,8,17,24,32,37 7,9,11,13,15,19,21,23,25,27,29,35,3 9,42,51 2,6,13,18,29,37,41, 2,4,40, 3,5,7,10,15,19,21,23,25,27,30,39,40, 42,47,49,53,57 3,6,7,9,38,41,43, 27: 14, 15 28: 1,2,8,28 27: 2,5,11,12,16,20,44,46,49 28: 3,5,7,10,12,13,29,30,32,33 29: 2,14,23,36,42 30:1 29: 1,12,13,15,16,24,25,27, 37,39, 49, 50 30: 2,4,12,13 Fourth Marking Period Date Topic In-Class Examples Homework