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PHYSICS I (HONORS) (L) (Chemistry I and Algebra II required) Two semesters/One credit each semester A Core 40 and Academic Honors Course This introductory physics course is designed for students who are interested in science and/or engineering, and is an algebra-based course with much attention given to problem solving. This course will prepare a student for the state assessment test in physics and the AP Physics B exam. Approximately 20% of class time will be spent on laboratory activities. Reading and/or problem assignments will be made several nights each week. Students are required to have chemical splash type safety goggles and a scientific calculator. Included in the course will be an exploration of careers and the history of physics. Grades are based on labs, homework problems, quizzes, exams, and class participation. There are two Web sites associated with this course. The companion Web site for the textbook is at http://wps.prenhall.com/esm_giancoli_physicsppa_6 The course Web site is at http://phys1.home.insightbb.com/ TEXTBOOK: Physics: Principles with Applications, 6th Edition Giancoli Pearson/Prentice Hall (2005) State Academic Standards: http://www.doe.state.in.us/standards/Docs-2004/English/PDF/HS-Science/Physics.pdf AP Physics B Course Description: http://apcentral.collegeboard.com/repository/05824apcoursdescphysi_4325.pdf 1 COURSE OUTLINE UNIT I. MECHANICS Approximate Time Topic A - Introduction 3 days Topic B - Describing Motion: Kinematics in One Dimension 8 days Topic C - Describing Motion: Kinematics in Two Dimensions 7 days Topic D - Forces and Motions: Dynamics 8 days Topic E - Circular Motion and Gravitation 7 days Topic F - Work and Energy 8 days Topic G - Momentum and Collisions 8 days Topic H - Rotational Motion 8 days Topic I - Bodies in Equilibrium: Statics 3 days Topic J - Fluids 8 days UNIT II. VIBRATIONS AND WAVES Topic A - Simple Harmonic Motion Topic B - Sound 8 days 8 days KINETIC THEORY (requires independent study) Topic A - Temperature and Kinetic Theory Topic B - Heat Topic C - Thermodynamics 2 days 3 days 2 days ELECTRICITY AND MAGNETISM Topic A - Electric Charge and Electric Fields Topic B - Potential Difference and Capacitance Topic C - Electric Current and Resistance Topic D - DC Circuits Topic E - Magnetism Topic F - Electromagnetism Topic G -Electromagnetic Waves 5 days 5 days 6 days 6 days 6 days 6 days 2 days LIGHT Topic A - Geometric Optics Topic B - Wave Optics Topic C - Optical Instruments 8 days 5 days 5 days UNIT III. UNIT IV. UNIT V. UNIT VI. MODERN PHYSICS Topic A - Relativity Topic B -Quantum Mechanics Topic C -Solid State Physics Topic D - Nuclear Physics Topic E - Frontiers 8 days 6 days (independent study) 6 days 3 days 2 UNIT I. MECHANICS TOPIC A - Introduction Purpose: Students review math and problem-solving skills. Students learn the fundamental quantities of physics. Students learn measurement techniques. Time: 3 days References: Text Chapter 1 Companion Web site http://wps.prenhall.com/esm_giancoli_physicsppa_6 Lecture Topics: 1. Standards of length, mass and time 2. Dimensional Analysis 3. Significant Figures 4. Conversion of Units 5. Order-of-Magnitude Calculations 6. Mathematical Notation 7. Coordinate Systems 8. Trigonometry 9. Problem-Solving Strategy Laboratories: Introduction to Measurement: Easy as . Media Resources: The Mechanical Universe: Introduction Cinema Classics: Time and Place Orders of Magnitude Computer Resources Course Web site: Internet Activity 1 Objectives: 1. Discuss length, mass, time and their SI units. 2. Derive force, velocity, etc. from basic units. 3. Perform a dimensional analysis. 4. Convert units from one system to another. 5. Carry out order-of-magnitude calculations. 6. Become aware of math symbols and Greek letters. 7. Use Cartesian coordinates and trigonometry. 8. Calculate with numbers in exponential notation. 3 TOPIC B - Describing Motion: Kinematics in One Dimension Purpose: Students learn units and equations of motion. Time: 8 days References: Text Chapter 2 Companion Web site Lecture Topics: 1. Displacement 2. Average Velocity 3. Acceleration 4. Motion Diagrams 5. Constant Acceleration 6. Freely Falling Bodies Laboratories: 1. Acceleration due to gravity: Physics with Computers labs 4, 6 2. Sonic Ranger motion studies: Physics with Computer labs 1, 2 Media Resources: The Mechanical Universe: Law of Falling Bodies Cinema Classics: Uniform Motion, Free Fall Physics of Sports: Linear Motion Computer Resources: Course Web site: Internet Activity 2 Objectives: 1. Define displacement and average velocity. 2. Define instantaneous velocity and compare to average. 3. Define average and instantaneous accelerations. 4. Construct position versus time graphs. 5. Construct velocity versus time graphs. 6. Use slopes and areas for above graphs. 7. Use kinematics relations for freely falling bodies. 8. Use kinematics equations to solve problems. 4 TOPIC C - Describing Motion: Kinematics in Two Dimensions Purpose: Students solve vector component problems. Students view two-dimensional motion as separate x and y motions. Time: 7 days References: Text Chapter 3 Companion Web site Lecture Topics: 1. Vectors and Scalars 2. Properties of Vectors 3. Components of a Vector 4. Two Dimensional Velocity and Acceleration 5. Projectile Motion 6. Relative Velocity Laboratories: 1. Projectile Motion: Physics with Computers lab 8 Media Resources: Eames Films Cinema Classics: Vectors Physics of Sports: Projectiles Computer Resources: Course Web site: Internet Activity 3 Objectives: 1. Distinguish between vector and scalar quantities. 2. Understand the basic vector properties and operations. 3. Sketch a projectile trajectory, label velocity and acceleration components. 4. Note projectile motion is separate x and y motions. 5. Discuss assumptions in our treatment of projectiles. 6. Given original velocity and angle, solve projectile motion problems. 7. Given velocity components, solve projectile motion problems. 5 TOPIC D - Forces and Motion: Dynamics Purpose: Students integrate Newtonian viewpoint into psyches. Students solve dynamical and kinematics problems. Time: 8 days Reference Topics: Text Chapter 4 Companion Web site Lecture Topics: 1. Introduction to Classical Mechanics 2. The Concept of Force 3. Newton's First Law 4. Newton's Second Law 5. Newton's Third Law 6. Applications of Newton's Laws 7. Forces of Friction Laboratories: 1. Newton's Second Law: Physics with Computers lab 9 2. Atwood's Machine: Physics with Computers lab 10 3. Newton's Third Law: Physics with Computer lab 11 4. Coefficient of Sliding Friction: Physics with Computers lab 12 Media Resources: The Mechanical Universe: Newton's Laws Cinema Classics: Newton's Laws Physics of Sports: Forces A Million to One (videotape) Computer Resources: Course Web site: Internet Activity 4 Objectives: 1. Discuss forces, effect of unbalanced forces on motion. 2. Distinguish between contact, action at a distance force. 3. Write description and example of each of Newton's laws. 4. Identify action-reaction force pairs. 5. Discuss mass and inertia, mass and weight. 6. Become familiar with SI and English units for F=ma. 7. Note: friction laws are empirical, depend on normal force. 8. Use F=N in solving friction problems. 9. Draw free-body diagrams, apply F=ma in component form. 10. Apply kinematics formulas to extend dynamics problems. 11. Be able to solve systems of equations. 6 TOPIC E - Circular Motion and Gravitation Purpose: Students internalize concept of centripetal acceleration Students solve circular motion problems by analogy to linear kinematics. Students stand in awe of universal gravitation. Time: 7 days References: Text Chapter 5 Companion Web site Lecture Topics: 1. Angular Velocity 2. Angular Acceleration 3. Rotational Motion, Constant Acceleration 4. Relating Angular and Linear Kinematics 5. Centripetal Acceleration 6. Centripetal Force 7. Frames of Reference 8. Newton's Law of Gravitation 9. Gravitational Potential Energy 10. Escape Velocity 11. Kepler's Laws Laboratories: 1. Motion of Mars Media Resources: The Mechanical Universe: Newton and Kepler Cinema Classics: Circular and Planetary Motion Physics of Sports: Human Motion Computer Resources: Course Web site: Internet Activity 5 Objectives: 1. Define angular velocity and acceleration. 2. Identify symbols and units for angular quantities. 3. Distinguish between centripetal and tangential accelerations. 4. Realize rotating problems simplify in angular variables. 5. Match linear and rotational kinematics formulas. 6. Solve rotation problems when speed constant. 7. Describe components of acceleration if speed is constant. 8. Describe components of acceleration if speed is not constant. 9. Understand the origin of fictitious forces. 10. Discuss the inverse-square nature of Newton's gravitation. 11. State and interpret Kepler's laws and calculate orbits. 12. Derive and use Kepler's third law for circular orbits. 7 TOPIC F - Work and Energy Purpose: Students are introduced to basic work and energy concepts. Students solve problems by the energy method. Time: 8 days References: Text Chapter 6 Companion Web site Lecture Topics: 1. Introduction 2. Work 3. Work and Kinetic Energy 4. Potential Energy 5. Conservative and Non-conservative Forces 6. Conservation of Mechanical Energy 7. Non-conservative Forces and the Work-Energy Theorem 8. Power 9. Conservation of Energy 10. Work Done by a Varying Force Laboratories: 1. Power in Stair Climbing 2. Work and Energy: Physics with Computers lab 18 Media Resources: The Mechanical Universe: Conservation of Energy Cinema Classics: Work and Energy: Conservation Physics of Sports: Energy Computer Resources: Course Web site: Internet Activity 6 Objectives: 1. Define work (a scalar) done by constant force. 2. Recognize and give examples of +, –, 0 work. 3. Define kinetic energy. 4. Note potential energy can be +, –, 0 depending on reference. 5. Note differences of potential energy are unique. 6. Contrast conservative and non-conservative forces. 7. Distinguish between kinetic, potential, total energy. 8. State law of conservation of mechanical energy. 9. Relate the work done to change in kinetic energy. 10. Account for non-conservative forces in work-energy law. 11. Define power as the rate of doing work. 12. Describe work done by varying force, relate to graph. 13. Recognize spring potential energy as + or 0. 8 TOPIC G - Momentum and Collisions Purpose: Students learn the concept of momentum. Students use the alternate form of Newton's Second Law. Students analyze collisions using momentum conservation. Time: 8 days References: Text Chapter 7 Companion Web site Lecture Topics: 1. Momentum and Impulse 2. Conservation of Momentum 3. Collisions 4. Glancing Collisions 5. Center of Gravity, Center of Mass 6. Rocket Propulsion Laboratories: 1. Momentum Conservation in an Explosion 2. Momentum, Energy and Collisions: Physics with Computer lab 19 3. Impulse and Momentum: Physics with Computer lab 20 Media Resources: The Mechanical Universe: Conservation of Momentum Cinema Classics: Momentum: Collisions Physics of Sports: Momentum, Impulse, Time Center of Mass - Hammer Throw Skylab Physics Physics and Auto Collisions Computer Resources: Course Web site: Internet Activity 7 Objectives: 1. Understand momentum and F=dp/dt. 2. Note impulse is area under force versus time graph. 3. Realize momentum of isolated system is conserved. 4. Distinguish between elastic and inelastic collisions. 5. Use conservation of momentum in component form. 6. Solve a head-on elastic collision problem. 7. Solve a completely inelastic collision problem. 8. Understand the concept of center mass. 9. Note momentum of center of mass is constant if isolated. 10. Understand rocket propulsion is conservation of momentum. 9 TOPIC H - Rotational Motion Purpose: Students solve dynamics problems involving rotation. Time: 8 days References: Text Chapter 8 Companion Web site Lecture Topics: 1. Torque 2. Relation Between Torque and Angular Acceleration 3. Rotational Kinetic Energy 4. Angular Momentum Laboratories: 1. Moment of Inertia 2. Center of Gravity Media Resources: The Mechanical Universe: Angular Momentum Cinema Classics: Circular Motion Computer Resources: Course Web site: Internet Activity 8 Objectives: 1. Understand the concept of torque. 2. Calculate the inertia of a system of particles. 3. Show torque analog of Newton's Second Law. 4. Describe rotational kinetic energy. 5. Apply the work-energy theorem to rotating bodies. 6. Apply conservation of energy to rotating bodies. 7. Describe angular momentum of particles and rigid bodies. 8. Express torque as change of angular momentum with time. 9. Apply the conservation of angular momentum. 10 TOPIC I - Bodies in Equilibrium: Statics Purpose: Students achieve balance using the two conditions of equilibrium. Time: 3 days References: Text Chapter 9 Companion Web site Lecture Topics: 1. Statics - The Study of forces in equilibrium 2. The condition for equilibrium 3. Solving statics problems Laboratories: 1. Equilibrium of a meter stick Media Resources: Not Available Computer Resources: Course Web site: Internet Activity 9 Objectives: 1. Describe the conditions of equilibrium. 2. Analyze problems with objects in equilibrium. 11 TOPIC J - Fluids Purpose: Students review density and specific gravity. Students review pressure. Students shout "Eureka" and solve buoyancy problem. Students solve problems underlying fluids at rest and in motion. Time: 8 days References: Text Chapter 10 Companion Web site Lecture Topics: 1. Density and Specific Gravity 2. Pressure in Fluids 3. Atmosphere and Gauge Pressure 4. Pascal's Principle 5. Measuring Pressure: Barometer 6. Buoyancy and Archimedes' Principle 7. Fluids in Motion 8. Bernoulli's Equation Laboratories: Kitchen Physics Experiments Media Resources: Not Available Computer Resources: Course Web site: Internet Activity 10 Objectives: 1. Define density. 2. Define pressure and analyze fluid problems involving pressure. 3. Use Pascal's Principle to solve fluid problems. 4. Read a barometer, examine the underlying physics, predict weather. 5. Solve problems using Archimedes' Principle. 6. Internalize observations of fluids in water. 7. Apply Bernoulli's equation to flowing fluids. 12 UNIT II. VIBRATIONS AND WAVES TOPIC A - Simple Harmonic Motion Purpose: Students learn wave concepts and properties. Students study simple harmonic motion in many forms. Time: 8 days References: Text and Companion Web site Chapter 11 Lecture Topics: 1. Hooke's Law 2. Elastic Potential Energy 3. Velocity as a Function of Position 4. Comparing Simple Harmonic and Uniform Circular Motion 5. Position as a Function of Time 6. The Pendulum 7. Wave Motion 8. Types of Waves 9. Frequency, Amplitude, and Wavelength 10. Velocity of Waves on a String 11. Superposition and Interference of Waves 12. Reflection of Waves Laboratories: 1. Investigating Slinky Waves 2. The Simple Pendulum: Physics with Computers lab 14 3. Mass on a Spring: Physics with Computers lab 15, 17 Media Resources: The Mechanical Universe: Resonance: Waves Cinema Classics: Periodic Motion: Waves The Tacoma Narrows Bridge Collapse Computer Resources: Course Web site: Internet Activity 11 Objectives: 1. State, interpret, and use Hooke's Law. 2. Define terms of simple harmonic motion. 3. Describe the nature of systems in harmonic motion. 4. Apply energy principles to harmonic oscillators. 5. Apply oscillator results to mass on spring, pendulum. 6. Discuss simple harmonic motion versus circular motion. 7. Define wave terms and solve wave problems. 8. Solve problems involving waves on strings. 9. Define superposition, interference, and phase. 13 TOPIC B - Sound Purpose: Students use sound to probe longitudinal waves. Time: 8 days References: Text Chapter 12 Companion Web site Lecture Topics: 1. Producing Sound Waves 2. Characteristics of Sound Waves 3. Speed of Sound 4. Energy and Intensity of Sound Waves 5. Spherical and Plane Waves 6. Doppler Effect 7. Interference in Sound Waves 8. Standing Waves 9. Resonance 10. Standing waves in Tubes 11. Beats Laboratories: 1. Resonance Tubes: The Velocity of Sound 2. Sound Waves and Beats: Physics with Computers lab 21 Media Resources: Students make video on Doppler Effect Computer Resources: Course Web site: Internet Activity 12 Objectives: 1. Describe displacement, pressure variations in sound waves. 2. Calculate the speed of sound in various media. 3. Calculate the speed of sound in air at many temperatures. 4. Understand the log nature of decibel scale. 6. Find the intensity of sound given power, distance. 7. Describe and calculate with the Doppler Effect. 8. Describe the conditions in which a shock wave occurs. 9. Describe qualitatively sound interference. 10. Describe quantitatively when resonance occurs. 11. Solve standing wave problems for strings and tubes. 12. Describe the nature of beats. 14 UNIT III TEMPERATURE, HEAT, AND THERMODYNAMICS TOPIC A - Temperature and Kinetic Theory Purpose: Students will believe in things unseen. Time: Self-paced + 2 days References: Text Chapter 13 Companion Web site Lecture Topics: 1. Atomic Theory of Matter 2. Temperature and Thermometers 3. Thermal Equilibrium and the Zeroth Law of Thermodynamics 4. Thermal Expansion 5. Gas Laws and Absolute Temperature 6. Ideal Gas Law 7. Avogadro's Number 8. Kinetic Theory and Meaning of Temperature Laboratories: Not Available Media Resources: Not Available Computer Resources: Course Web site: Internet Activity 13 Objectives: 1. Explain the atomic theory of matter. 2. Define temperature and how to measure it. 3. State the zeroth law of thermodynamics. 4. Observe and calculate thermal expansion. 5. State and solve problems using the gas laws. 6. State and solve problems using the ideal gas law. 7. Define Avogadro's Number. 8. Explain how kinetic theory interprets temperature. 15 TOPIC B - HEAT Purpose: Students distinguish between heat and temperature. Students investigate the transfer of heat. Students solve calorimetry problems using conservation of energy. Time: independent study plus 3 days References: Text Chapter 14 Companion Web site Lecture Topics: 1. Heat as Energy Transfer 2. Internal Energy 3. Specific Heat 4. Calorimetry 5. Latent Heat 6. Heat Transfer: Conduction 7. Heat Transfer: Convection 8. Heat Transfer: Radiation Laboratories: Calorimetry I: Determining the Specific Heat of an Unknown Sample Calorimetry II: Determining the Latent Heat of Fusion Media Resources Not Available Computer Resources: Course Web site: Internet Activity 14 Objectives: 1. Convert joules to kilocalories and vice-versa. 2. Distinguish between the concepts of temperature and heat. 3. Explain specific heat, and latent heats of fusion and vaporization. 4. Solve calorimetry problems using conservation of energy. 5. Distinguish three modes of heat transfer. 6. Solve heat transfer problems involving convection and radiation. 16 TOPIC C - THERMODYNAMICS Purpose: Students learn the laws of thermodynamics and apply them to solve problems. Time: independent study plus 2 days References: Text Chapter 15 Companion Web site Lecture Topics: 1. The First Law of Thermodynamics 2. Ideal Processes and Application of the First Law 3. The Second Law of Thermodynamics 4. Heat Engines 5. Refrigerators, Air Conditioners, and Heat Pumps 6. Entropy 7. Statistical Interpretation of Entropy 8. Global Warming Laboratories: Not Available Media Resources Not Available Computer Resources: Course Web site: Internet Activity 15 Objectives: 1. Explain what is meant by closed and open physical systems. 2. State the first law and apply it to solve problems. 3. Distinguish between and draw PV diagrams of ideal processes. 4. Use PV diagrams to find work done by gas, changes in internal energy, and heat transfer. 5. Solve problems involving added heat during ideal processes at constant pressure or volume. 6. State the second law in three equivalent ways. 7. Solve Carnot heat engine problems using the laws of thermodynamics. 8. Distinguish between reversible and irreversible processes. 9. Calculate changes in entropy. 10. Solve problems involving the statistical interpretation of entropy. 17 UNIT IV ELECTRICITY AND MAGNETISM TOPIC A - Electric Charge and Electric Fields Purpose: Students are conducted through electric fields via analogy with gravitation. Time: 5 days References: Text Chapter 16 Companion Web site Lecture Topics: 1. Properties of Electric Charges 2. Insulators and Conductors 3. Coulomb's Law 4. Experimental Proof of Coulomb's Law 5. Electric Fields 6. Electric Field Lines 8. Van de Graaff Generators 9. Oscilloscopes Laboratories: 1. Electrified Objects 2. Electrostatic Induction Media Resources: The Mechanical Universe: Static Electricity Cinema Classics: Electrostatics Computer Resources: Course Web site: Internet Activity 16 Objectives: 1. Distinguish between conductors, insulators, and semiconductors. 2. Describe charging by contact and induction. 3. Describe charging from a microscopic viewpoint. 4. Solve problems using Coulomb's Law. 5. Calculate electric fields from charge distributions. 6. Describe field lines from standard objects. 7. State, justify observed charges on conductors. 8. Describe ice pail, Van de Graaffs, oscilloscopes. 18 TOPIC B - POTENTIAL DIFFERENCE AND CAPACITANCE Purpose: Students solve problems from scalar potential viewpoint. Students are introduced to the concept of capacitance. Time: 5 days References: Text Chapter 17 Companion Web site Lecture Topics: 1. Potential Difference and Electric Potential 2. Electric Potential and Potential Energy 3. Potentials and Charged Conductors 4. Equipotential Surfaces 5. Definition of Capacitance 6. Parallel-Plate Capacitors 7. Combinations of Capacitors 8. Energy Stored in Capacitors 9. Dielectrics Laboratories: 1. Capacitors: Make Your Own Media Resources: The Mechanical Universe: Potential & Capacitance Voltage: Batteries Computer Resources: Course Web site: Internet Activity 17 Objectives: 1. Understand the concept of potential. 2. Define electric potential difference and the volt. 3. Calculate potential difference in uniform field. 4. Calculate potential difference from charge distribution. 5. Calculate potential energy due to point charges. 6. Justify claims about potentials near conductors. 7. Define electron volt. 8. Define capacitance and the farad. 9. Evaluate capacitance of parallel-plate capacitor. 10. Determine series and parallel equivalent capacitance. 11. Describe dielectrics macro- and microscopically. 19 TOPIC C - Electric Current and Resistance Purpose: Students plumb concepts of current and resistance. Students solve Ohm's Law problems. Time: 6 days References: Text Chapter 18 Companion Web site Lecture Topics: 1. Electric Current 2. Current and Drift Velocity 3. Ohm's Law 4. Resistivity and Resistance 5. Resistance Variation with Temperature 6. Electrical Energy and Power 7. Energy Use at Home Laboratories: 1. Ohm's Law: Physics with Computers lab 25 2. Combinations of Resistors 3. RC Circuits: Physics with Computer lab 27 Media Resources: Cinema Classics: Electric Currents Computer Resources: Course Web site: Internet Activity 18 Objectives: 1. Define current as rate of charge flow and its unit, amp. 2. Calculate drift velocity. 3. Determine resistance from material properties, Ohm's Law. 4. Distinguish between ohmic and non-ohmic conductors. 5. Find resistance at various temperatures. 6. Describe superconductivity and its uses. 7. Sketch circuit diagrams using correct symbols. 8. Use Joule's law to find power dissipation of resistors. 9. Define emf and provide examples. 20 TOPIC D - DC Circuits Purpose: Students analyze and build simple circuits. Time: 6 days References: Text Chapter 19 Companion Web site Lecture Topics: 1. Sources of EMF 2. Resistors in Series 3. Resistors in Parallel 4. Kirchhoff's Rules 5. RC Circuits 6. Measurement of Resistance 7. Household Circuits 8. Electric Safety Laboratories: 1. Series and Parallel Circuits: Physics with Computers lab 26 Media Resources: The Mechanical Universe: Electrical Circuits Computer Resources: Course Web site: Internet Activity 19 Objectives: 1. Describe the function of a source of emf. 2. Determine V given emf for open, closed, short circuit. 3. Calculate I and V in a single loop circuit. 4. Combine resistors in series, parallel, or combination. 5. Use Ohm's law to find I and V in more complex circuits. 6. Find Joule heating of groups of resistors. 7. Apply Kirchoff's rules to multi-loop circuits. 8. Describe charge flow with time in RC circuit. 9. Use ammeter, voltmeter. 10. Find unknown resistances with above devices. 11. Describe the role of fuses and circuit breakers. 12. Compute household loads. 21 TOPIC E - Magnetism Purpose: Students are introduced to magnetic forces. Time: 6 days References: Text Chapter 20 Companion Web site Lecture Topics: 1. Magnets 2. Magnetic Field of the Earth 3. Magnetic Fields 4. Magnetic Forces on Current Carrying Wires 5. Torque on a Current Loop 6. Galvanometer and Applications 7. Motion of Charged Particles in Magnet Fields 8. Magnetic Field of Straight Wire and Ampere's Law 9. Magnetic Force Between Parallel Conductors 10. Magnetic Field of a Current Loop 11. Magnetic Field of a Solenoid 12. Magnetic Domains Laboratories: 1. Magnetic field of a current loop: Physics with Computer labs 28, 29 Media Resources: The Mechanical Universe: Magnetism, Magnetic Fields Cinema Classics: Magnetism Computer Resources: Course Web site: Internet Activity 20 Objectives: 1. Find magnetic forces on moving charges. 2. Find magnetic force on a current carrying wire. 3. Find the torque on a current loop in a magnetic field. 4. Describe the operation of a galvanometer/ 5. Find radius and period of circular orbit of q in B field. 6. Describe the path of charge in non-uniform B field. 7. Describe the operation of a mass spectrometer. 8. Calculate B field for long straight wire. 9. Define amp, coulomb with force between parallel wires. 10. Calculate B field at center of current loop, in solenoid. 11. Describe magnetic domains. 12. Describe the Earth's magnetic field and its origin. 22 TOPIC F - Electromagnetism Purpose: Students explore the link between electricity and magnetism. Time: 6 days References: Text Chapter 21 Companion Web site Lecture Topics: 1. Induced EMF and Magnetic Flux 2. Faraday's Law of Induction 3. Motional EMF 4. Lenz's Law 5. Generators 6. Eddy Currents 7. Self-inductance 8. RL Circuits 9. Energy Stored in a Magnetic Field Laboratories: 1. Faraday's Law Media Resources: The Mechanical Universe: Electromagnetic Induction Cinema Classics: Electromagnetism Computer Resources: Course Web site: Internet Activity 21 Objectives: 1. Describe producing emf with coils linked by iron core. 2. Calculate flux through surface where B field is uniform. 3. Calculate emf due to changing magnetic flux. 4. Apply Lenz's law. 5. Calculate emf between ends of conductor moving in B field. 6. Describe principles of generators and motors. 7. Describe back emf. 8. Describe eddy currents and how to minimize them. 9. Define self-inductance. 10. Describe changes in LR circuit with time. 11. Calculate energy stored in magnetic fields. 23 TOPIC G - Electromagnetic Waves Purpose: Students will appreciate the physics behind TV more than the content. Time: 2 days Reference: Text Chapter 21 Companion Web site Lecture Topics: 1. Maxwell's Equations 2. Electromagnetic Waves 3. Creation of EM Waves 4. Speed of EM Waves 5. Light and the EM Spectrum 6. Speed of Light 7. Energy in Waves 8. Application to Radio and TV Laboratories: Not Available Media Resources: Not Available Computer Resources: Course Web site: Internet Activity 22 Objectives. 1. State Maxwell's Equation. 2. Explain the physical nature of light. 3. Calculate the speed of EM Waves. 4. Calculate energy in EM Waves. 5. Explain the physics behind radio and TV. 6. Define AM and FM. 7. Investigate bandwidth assignments. 24 UNIT V LIGHT TOPIC A - Geometric Optics Purpose: Students reflect on the nature of light. Students explore images formed by mirrors and lenses. Students solve problems using mirror and lens equations. Time: 8 days References: Text Chapter 23 Companion Web site Lecture Topics: 1. The Nature of Light 2. Reflection and Refraction 3. Total Internal Reflection 4. Plane Mirrors 5. Images Found by Spherical Mirrors 6. Thin Lenses 7. Multiple Lens System 8. Aberrations Laboratories: 1. Images Formed by Converging Lenses 2. The Optics Box: Panoply of Experiments Media Resources: Not Available Computer Resources: Course Web site: Internet Activity 23 Objectives: 1. Find the path of a light ray upon reflection or refraction. 2. Understand condition for total internal reflection. 3. Apply internal reflection to explain fiber optics. 4. Identify properties of images (real or virtual, erect or inverted, enlarged or reduced). 5. Understand the sign convention in mirror and lens problem. 6. Calculate the position and size of an image. 7. Use ray tracing to locate images. 8. Describe the origin and correction of aberrations. 25 TOPIC B - Wave Optics Purpose: Students study phenomena revealing the wave nature of light. Time: 5 days References: Text Chapter 24 Companion Web site Lecture Topics: 1. Conditions for Interference 2. Young's Double-Slit Interference 3. Diffraction 4. Single-Slit Diffraction 5. Diffraction Gratings Laboratories: 1. Double-Slit Interference: A Demonstration 2. Polarization 3. Wavelength of Laser Light via Diffraction Grating Media Resources: Cinema Classics: Interference: Diffraction: Colors, Scattering, Polarization Computer Resources: Course Web site: Internet Activity 24 Objectives: 1. State conditions for light wave interference. 2. Describe double-slit interference. 3. Calculate distance between orders for Young's experiment. 4. Describe single-slit Fraunhofer diffraction. 5. Determine maxima and minima positions in single-slit pattern. 6. Solve problems involving diffraction gratings. 7. Determine polarization experimentally. 8. Describe various methods of polarization. 9. Calculate Brewster's angle. 26 TOPIC C - Optical Instruments Purpose: Students use optical knowledge to make and analyze instruments. Time: 5 days References: Text Chapter 25 Companion Web site Lecture Topics: 1. Cameras 2. Eyes 3. Simple Magnifiers 4. Compound Microscopes 5. Telescopes 6. Resolution 7 Michelson Interferometers Laboratories: 1. Telescopes Media Resources:: NASA Video Series Computer Resources: Course Web site: Internet Activity 25 Objectives: 1. Describe the design of the single lens camera. 2. Define f-number and relate to shutter speed. 3. Describe the structure of the eye. 4. Describe common defects of vision. 5. Define diopter and find power of lenses to correct vision. 6. Describe microscopes, telescopes, and magnifiers. 7. Use Rayleigh's criterion to decide resolvability. 8. Describe operation of Michelson Interferometer. 27 UNIT VI: MODERN PHYSICS TOPIC A - Relativity Purpose: Students alter their conceptions of time and space. Time: 8 days References: Text Chapter 26 Companion Web site Lecture Topics: 1. Setting the Stage: Reference Frames, Michelson - Morley 2. Special Relativity: People and Postulates 3. Simultaneity, Time Dilation 4. Twin Paradox, Space - Time 5. Momentum, Mass, the Ultimate Speed 6. E = mc2 7. Velocity Addition 8. General Relativity Laboratories: Not Available Media Resources The Mechanical Universe: Space and Time The Mechanical Universe: Mass and Energy Computer Resources: Course Web site: Internet Activity 26 Objectives: 1. Examine the historical background leading to special relativity. 2. Describe Einstein's postulates and their outcome. 3. Solve problems involving time dilation. 4. Solve problems involving length contraction. 5. Solve problems transforming momentum, mass, and energy. 6. Solve problems with the velocity addition formula. 7. State the difference between special and general relativity. 8. Discuss social and political consequences of relativity. 28 TOPIC B - Atomic Physics and Quantum Mechanics Purpose: Students view things unseen. Time: 6 days References: Text Chapters 27 and 28 Companion Web site Lecture Topics: 1. Discovery of the Electron 2. Blackbody Radiation and Planck's Quantum Hypothesis 3. Einstein's Photon Explanation of the Photoelectric Effect 4. Energy, Mass, and Momentum of the Photon; Compton Effect; Pair Production 5. Wave-Particle Duality 6. Spectra and the Rutherford/Bohr Atom 7. Wave Functions 8. Heisenberg Principle 9. Copenhagen Interpretation of Quantum Mechanics 10. Quantum Numbers 11. Periodic Table 12. Lasers Laboratories: Not Available Media Resources DVD The Elegant Universe (PBS) Computer Resources: Course Web site: Internet Activities 27 and 28 Objectives: 1. Describe the Thomson and Millikan experiments discovering electrons. 2. Describe the quantum hypothesis. Find the energy of photons given wavelength. 3. Solve photoelectric problems using Einstein's photon solution. 4. Find the de Broglie wavelength of moving particles. 5. Describe the Rutherford scattering experiment and the resulting atomic model. 6. Solve spectra problems using the Bohr model. 7. Find energy, angular momentum and radius of electrons in a given level of Bohr atom. 8. Discuss Heisenberg Uncertainty Principle and its implications. 9. Discuss Bohr versus quantum mechanical view of the atom. 10. Name and apply quantum numbers describing electrons in atoms. 11. State the Pauli Exclusion Principle/ 12. Re' the periodic table: given Z, write electron configuration. 29 TOPIC C - Solid State Physics NOT COVERED DUE TO TIME CONSTRAINTS References: Text Chapter 29 Companion Web site Course Web site: Internet Activity 29 30 TOPIC D - Nuclear Physics Purpose: Students will address societal concerns involving radiation from an informed point of view. Time: 6 days References: Text Chapters 30 and 31 Lecture Topics: 1. Structure and Properties of the Nucleus 2. Binding Energy and Nuclear Forces 3. Radioactivity and Half-Life 4. Alpha, Beta Gamma Decay 5. Radioactive Dating 6. Nuclear Reactions 7. Fission 8. Nuclear Power 9. Fusion 10. Effect of Radiation on Biological Organisms 11. Nuclear Medicine Laboratories: 1. Purdue Department of Nuclear Engineering day on campus Media Resources: Not Available Computer Resources: Course Web site: Internet Activities 30 and 31 Objectives: 1. State the components of a nucleus. 2. Solve problems involving binding energy. 3. Define radioactive modes of decay. 4. Solve problems involving radioactive decay. 5. Solve problems involving nuclear reactions. 6. Explain the process of fission and fusion and the source of energy. 7. Explain the workings of a fission power plant - advantages and disadvantages. 8. Examine the societal effects of nuclear weapons. 9. Explain dangers of radiation and fission power. 10. Explain advantages of irradiated food, nuclear medicine, and fission power. 31 TOPIC E - Frontiers in Physics Purpose: Students glimpse current thinking at frontiers of research. Time: 3 days References: Text Chapters 32 and 33 Companion Web site Lecture Topics: 1. The Standard Model of Particle Physics 2. The Big Bang 3. What's Next? Laboratories: Not Available Media Resources: DVD The Elegant Universe (PBS) Computer Resources: Course Web site: Internet Activity 32 and 33 Objectives: 1. Explain the current classification of subatomic particles. 2. Explain the current theory of the origin of the universe. 3. State the evidence in favor of the Big Bang Theory. 4. Explore an area of current research in physics. 32 CORRELATION WITH INDIANA ACADEMIC STANDARDS UNIT I. MECHANICS Topic A - Introduction Topic B - Describing Motion: Kinematics in One Dimension Topic C - Describing Motion: Kinematics in Two Dimensions Topic D - Forces and Motions: Dynamics Topic E - Circular Motion and Gravitation Topic F - Work and Energy Topic G - Momentum and Collisions Topic H - Rotational Motion Topic I - Bodies in Equilibrium: Statics Topic J - Fluids UNIT II. VIBRATIONS AND WAVES Topic A - Simple Harmonic Motion Topic B - Sound UNIT III. UNIT IV. UNIT V. UNIT VI. Standards 1.2, 1.4 1.5, 1.6 1.5 1.5, 1.7, 2.1, 2.2, 2.3 1.8, 1.10, 2.1, 2.2, 2.3 1.9, 1.11, 1.12, 1.14, 1.16 1.9, 1.15, 1.16 1.22, 1.24 KINETIC THEORY (requires independent study) Topic A - Temperature and Kinetic Theory Topic B - Heat Topic C - Thermodynamics 1.1, 1.3, 1.27 1.11, 1.13, 1.27 1.11, 1.12, 1.28 ELECTRICITY AND MAGNETISM Topic A - Electric Charge and Electric Fields Topic B - Potential Difference and Capacitance Topic C - Electric Current and Resistance Topic D - DC Circuits Topic E - Magnetism Topic F - Electromagnetism Topic G -Electromagnetic Waves 1.2, 1.10, 1.17, 1.18 1.18 1.18 1.19 1.18, 2.4 1.20, 1.21, 2.4 1.11, 1.26, 2.4 LIGHT Topic A - Geometric Optics Topic B - Wave Optics Topic C - Optical Instruments 1.24 1.23, 1.24 , 1.26 1.25 MODERN PHYSICS Topic A - Relativity Topic B -Quantum Mechanics Topic C -Solid State Physics Topic D - Nuclear Physics Topic E - Frontiers 2.5, 2.6, 2.7 1.29, 1.30, 2.8 1.1, 1.29, 1.30, 1.31, 1.33, 1.34, 1.35, 2.8, 2.9, 2.10 1.1, 1.31, 2.7 33 INDIANA PHYSICS I ACADEMIC STANDARDS (2000) The Properties of Matter P.1.1 Describe matter in terms of its fundamental constituents and be able to differentiate among those constituents. Text Ch 13, 30, 32 P.1.2 Measure or determine the physical quantities including mass, charge, pressure, volume, temperature, and density of an object or unknown sample. Text Ch 1, 13, 16 P.1.3 Describe and apply the kinetic molecular theory to the states of matter. Text Ch 13 P.1.4 Employ correct units in describing common physical quantities. Text Ch 1 The Relationships Between Motion and Force P.1.5 Use appropriate vector and scalar quantities to solve kinematics and dynamics problems in one and two dimensions. Text Ch 2, 3, 4 P.1.6 Describe and measure motion in terms of position, time, and the derived quantities of velocity and acceleration. Text Ch 2 P.1.7 Use Newton’s Laws (e.g., F = ma) together with the kinematic equations to predict the motion of an object. Text Ch 4 P.1.8 Describe the nature of centripetal force and centripetal acceleration (including the formula a = v2/r), and use these ideas to predict the motion of an object. Text Ch 5 P.1.9 Use the conservation of energy and conservation of momentum laws to predict, both conceptually and quantitatively, the results of the interactions between objects. Text Ch 6, 7 P.1.10 Demonstrate an understanding of the inverse square nature of gravitational and electrostatic forces. Text Ch 5, 16 The Nature of Energy P.1.11 Recognize energy in its different manifestations, such as kinetic (KE = ½mv2), gravitational potential (PE = mgh), thermal, chemical, nuclear, electromagnetic, or mechanical. Text Ch 6, 14, 15, 22 P.1.12 Use the law of conservation of energy to predict the outcome(s) of an energy transformation. Text Ch 6, 15 P.1.13 Use the concepts of temperature, thermal energy, transfer of thermal energy, and the mechanical equivalent of heat to predict the results of an energy transfer. Text Ch 14 P.1.14 Explain the relation between energy (E) and power (P). Explain the definition of the unit of power, the watt. Text Ch 6 Momentum and Energy P.1.15 Distinguish between the concepts of momentum (using the formula p = mv) and energy. Text Ch 7 P.1.16 Describe circumstances under which each conservation law may be used. Text Ch 6, 7 34 The Nature of Electricity and Magnetism P.1.17 Describe the interaction between stationary charges using Coulomb’s Law. Know that the force on a charged particle in an electrical field is qE, where E is the electric field at the position of the particle, and q is the charge of the particle. Text Ch 16 P.1.18 Explain the concepts of electrical charge, electrical current, electrical potential, electric field, and magnetic field. Use the definitions of the coulomb, the ampere, the volt, the volt/meter, and the tesla. Text Ch 16, 17, 18, 20 P.1.19 Analyze simple arrangements of electrical components in series and parallel circuits. Know that any resistive element in a DC circuit dissipates energy, which heats the resistor. Calculate the power (rate of energy dissipation), using the formula Power = IV = I2R. Text Ch 19 P.1.20 Describe electric and magnetic forces in terms of the field concept and the relationship between moving charges and magnetic fields. Know that the magnitude of the force on a moving particle with charge q in a magnetic field is qvBsina, where v and B are the magnitudes of vectors v and B and a is the angle between v and B. Text Ch 21 P.1.21 Explain the operation of electric generators and motors in terms of Ampere’s law and Faraday’s law. Text Ch 20, 21 The Behavior of Waves P.1.22 Describe waves in terms of their fundamental characteristics of velocity, wavelength, frequency or period, and amplitude. Know that radio waves, light, and X-rays are different wavelength bands in the spectrum of electromagnetic waves, whose speed in a vacuum is approximately 3 108 m/s (186,000 miles/second). Text Ch 11 P.1.23 Use the principle of superposition to describe the interference effects arising from propagation of several waves through the same medium. Text Ch 24 P.1.24 Use the concepts of reflection, refraction, polarization, transmission, and absorption to predict the motion of waves moving through space and matter. Text Ch 11, 23, 24 P.1.25 Use the concepts of wave motion to predict conceptually and quantitatively the various properties of a simple optical system. Text Ch 25 P.1.26 Identify electromagnetic radiation as a wave phenomenon after observing refraction, reflection, and polarization of such radiation. Text Ch 22 The Laws of Thermodynamics P.1.27 Understand that the temperature of an object is proportional to the average kinetic energy of the molecules in it and that the thermal energy is the sum of all the microscopic potential and kinetic energies. Text Ch 13, 14 P.1.28 Describe the Laws of Thermodynamics, understanding that energy is conserved, heat does not move from a cooler object to a hotter one without the application of external energy, and that there is a lowest temperature, called absolute zero. Use these laws in calculations of the behavior of simple systems. Text Ch 15 35 The Nature of Atomic and Subatomic Physics P.1.29 Describe the nuclear model of the atom in terms of mass and spatial relationships of the electrons, protons, and neutrons. Text Ch 27, 30 P.1.30 Explain that the nucleus, although it contains nearly all of the mass of the atom, occupies less than the proportion of the solar system occupied by the sun. Explain that the mass of a neutron or a proton is about 2,000 times greater than the mass of an electron. Text Ch 27, 30 P.1.31 Explain the role of the strong nuclear force in binding matter together. Text Ch 30, 33 P.1.32 Using the concept of binding energy per nucleon, explain why a massive nucleus that fissions into two medium-mass nuclei emits energy in the process. Text Ch 30 P.1.33 Using the same concept, explain why two light nuclei that fuse into a more massive nucleus emit energy in the process. Text Ch 30 P.1.34 Understand and explain the properties of radioactive materials, including half-life, types of emissions, and the relative penetrative powers of each type. Text Ch 30, 31 P.1.35 Describe sources and uses of radioactivity and nuclear energy. Text Ch 31 36 Standard 2: Historical Perspectives of Physics P.2.1 Explain that Isaac Newton created a unified view of force and motion in which motion everywhere in the universe can be explained by the same few rules. Note that his mathematical analysis of gravitational force and motion showed that planetary orbits had to be the very ellipses that Johannes Kepler had proposed two generations earlier. Text Ch 4, 5 P.2.2 Describe how Newton’s system was based on the concepts of mass, force, and acceleration; his three laws of motion relating to them; and a physical law stating that the force of gravity between any two objects in the universe depends only upon their masses and the distance between them. Text Ch 4, 5 P.2.3 Explain that the Newtonian model made it possible to account for such diverse phenomena as tides, the orbits of the planets and moons, the motion of falling objects, and Earth’s equatorial bulge. Text Ch 4, 5 P.2.4 Describe how the Scottish physicist James Clerk Maxwell used Ampere’s law and Faraday’s law to predict the existence of electromagnetic waves and predict that light was just such a wave. Also understand that these predictions were confirmed by Heinrich Hertz, whose confirmations thus made possible the fields of radio, television, and many other technologies. Text Ch 20, 21, 22 P.2.5 Describe how among the surprising ideas of Albert Einstein’s special relativity is that nothing can travel faster than the speed of light, which is the same for all observers no matter how they or the light source happen to be moving, and that the length of time interval is not the same for observers in relative motion. Text Ch 26 P.2.6 Explain that the special theory of relativity (E=mc2) is best known for stating that any form of energy has mass and that matter itself is a form of energy. Text Ch 26 P.2.7 Describe how general relativity theory pictures Newton’s gravitational force as a distortion of space and time. Text Ch 26, 33 P.2.8 Explain that Marie and Pierre Curie made radium available to researchers all over the world, increasing the study of radioactivity and leading to the realization that one kind of atom may change into another kind, and so must be made up of smaller parts. Note that these parts were demonstrated by Rutherford, Geiger, and Marsden to be small, dense nuclei that contain protons and neutrons and are surrounded by clouds of electrons. Text Ch 27, 30 P.2.9 Explain that Ernest Rutherford and his colleagues discovered that the radioactive element radon spontaneously splits itself into a slightly lighter nucleus and a very light helium nucleus. Text Ch 30 P.2.10 Describe how later, Austrian and German scientists showed that when uranium is struck by neutrons, it splits into two nearly equal parts plus two or three extra neutrons. Note that Lise Meitner, an Austrian physicist, was the first to point out that if these fragments added up to less mass than the original uranium nucleus, then Einstein’s special relativity theory predicted that a large amount of energy would be released. Also note that Enrico Fermi, an Italian working with colleagues in the United States, showed that the extra neutrons trigger more fissions and so create a sustained chain reaction in which a prodigious amount of energy is given off. Text Ch 30, 31 37