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UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 1 Work †After Attendance (†EQ Sheet; Concept Map) • Place HW on my desk • †Pickup a new Essential Question Sheet and a Conservation of Energy Concept Map • Pickup and sign out your computer • Log into www.plutonium-239.com • Select the Warm-Up link • Complete today’s warm-up and submit it • Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • Causes of Force Test UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Chapter 6 Work and Energy UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Units of Chapter 6 •Work Done by a Constant Force •Work Done by a Varying Force •Kinetic Energy and the Work-Energy Principle •Potential Energy •Conservative and Nonconservative Forces •Mechanical Energy and Its Conservation •Problem Solving Using Conservation of Mechanical Energy UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Units of Chapter 6 •Other Forms of Energy; Energy Transformations and the Law of Conservation of Energy •Energy Conservation with Dissipative Forces: Solving Problems •Power UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Equations to Know: Conservation of Energy W Fr cos F kx W Pavg t P F cos 1 2 K mv 2 U g mgh 1 2 U s kx 2 Conservation of Energy: Work EQ(s): How do we calculate work in terms of kinetic energy? Start: I tell my wife, “It is called work for a reason, that is why they pay you.” So, what is work afterall? How do we calculate work in terms of kinetic energy? 6-1 Work Done by a Constant Force The work done by a constant force is defined as the distance moved multiplied by the component of the force in the direction of displacement: (6-1) How do we calculate work in terms of kinetic energy? 6-1 Work Done by a Constant Force In the SI system, the units of work are joules: As long as this person does not lift or lower the bag of groceries, he is doing no work on it. The force he exerts has no component in the direction of motion. How do we calculate work in terms of kinetic energy? 6-1 Work Done by a Constant Force Solving work problems: 1. Draw a free-body diagram. 2. Choose a coordinate system. 3. Apply Newton’s laws to determine any unknown forces. 4. Find the work done by a specific force. 5. To find the net work, either find the net force and then find the work it does, or find the work done by each force and add. How do we calculate work in terms of kinetic energy? 6-1 Work Done by a Constant Force Work done by forces that oppose the direction of motion, such as friction, will be negative, because cos 180° = -1. Centripetal forces do no work, as they are always perpendicular to the direction of motion. How do we calculate work in terms of kinetic energy? 6-2 Work Done by a Varying Force For a force that varies, the work can be approximated by dividing the distance up into small pieces, finding the work done during each, and adding them up. As the pieces become very narrow, the work done is the area under the force vs. distance curve. How do we calculate work in terms of kinetic energy? Pasco Work and Energy LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. How do we calculate work in terms of kinetic energy? WebAssign/Lab Time • Work on WebAssign Problems 6.1 - 6.4 or the Pasco Work and Energy Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) How do we calculate work in terms of kinetic energy? Summary • Answer the Essential Question. • Ticket out the Door: – What is the formula for work? – How much work have you done if you strain to move a couch but never move it? – How much work have you done if you lift the couch 1 m up with a force of 500 N? • HW: – Pasco Work and Energy Lab (Questions and Conclusions) – WebAssign Problems 6.1 - 6.4 UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 2 Kinetic Energy Work-Energy Principle After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions Conservation of Energy: Kinetic Energy EQ(s): How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? Start: Solve the following equation for ax: v 2 v02 2ax What have you calculated if you multiply ax by its mass? INSERT Picture How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? 6-3 Kinetic Energy and the Work-Energy Principle Energy was traditionally defined as the ability to do work. We now know that not all forces are able to do work; however, we are dealing in these chapters with mechanical energy, which does follow this definition. How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? 6-3 Kinetic Energy and the Work-Energy Principle If we write the acceleration in terms of the velocity and the distance, we find that the work done here is (6-2) We define the kinetic energy: (6-3) How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? 6-3 Kinetic Energy and the Work-Energy Principle If the KE of an object is doubled, by what factor has its speed increased? 1 2 KE1 mv1 ;KE 2 2KE1 2 1 2 12 2 22 m v2 2v 2 2v mv 2v 1 m 11 v11 2 2 How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? 6-3 Kinetic Energy and the Work-Energy Principle If its speed is doubled, by what factor does its KE increase? 1 2 KE1 mv1 ;v2 2v1 2 1 1 1 22 2 22 KE mv KE m v222 44m 2v 4v 1 1 11 2 2 2 How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? 6-3 Kinetic Energy and the Work-Energy Principle This means that the work done is equal to the change in the kinetic energy: (The Work-Energy Principle) (6-4) • If the net work is positive, the kinetic energy increases. • If the net work is negative, the kinetic energy decreases. How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? 6-3 Kinetic Energy and the Work-Energy Principle Because work and kinetic energy can be equated, they must have the same units: kinetic energy is measured in joules. How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? Pasco Work and Energy LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? WebAssign/Lab Time • Work on WebAssign Problems 6.1 - 6.7 or the Pasco Work and Energy Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) How do we calculate work in terms of kinetic energy? How can the velocity of an object be quantified in terms of its kinetic energy? Summary • Answer the Essential Questions. • Ticket out the Door: – What is the formula for kinetic energy? – What is the formula for the work-energy principle? – What happens to the velocity of an object if the net work is negative? • HW: – Pasco Work and Energy Lab (Questions and Conclusions) – WebAssign Problems 6.1 - 6.7 UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 3 Potential Energy After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions Conservation of Energy: Potential Energy EQ(s): How can the position of an object be quantified in terms of its potential energy? Start: Solve the following equation for the y-axis: W max How can the position of an object be quantified in terms of its potential energy? START Derivation W max Wgravity mgy Wgravity mg y y0 Wgravity mgy0 mgy If y > y0, then gravity does negative work (aka. The object moves in the opposite direction of gravity and energy is “stored” in the object by exerting an external force). If y < y0, then gravity does positive work (aka. The object moves in the same direction as gravity). How can the position of an object be quantified in terms of its potential energy? 6-4 Potential Energy An object can have potential energy by virtue of its surroundings. Familiar examples of potential energy: • A wound-up spring • A stretched elastic band • An object at some height above the ground • and Donuts!!! How can the position of an object be quantified in terms of its potential energy? 6-4 Potential Energy In raising a mass m to a height h, the work done by an external force is Wext Fext d cos mgh Wext mg y y0 (6-5a) We therefore define the gravitational potential energy: Ugrav mgy or PE grav mgy (6-6) Does this go against our START Activity where Wgrav mgy? Note that Wgrav U grav How can the position of an object be quantified in terms of its potential energy? 6-4 Potential Energy This potential energy can become kinetic energy if the object is dropped. Potential energy is a property of a system as a whole, not just of the object (because it depends on external forces). If , where do we measure y from? It turns out not to matter, as long as we are consistent about where we choose y = 0. Only changes in potential energy can be measured. How can the position of an object be quantified in terms of its potential energy? 6-4 Potential Energy Potential energy can also be stored in a spring when it is compressed; the figure below shows potential energy yielding kinetic energy. How can the position of an object be quantified in terms of its potential energy? 6-4 Potential Energy The force required to compress or stretch a spring is: (6-8) where k is called the spring constant, and needs to be measured for each spring. This equation is known as Hooke’s Law Steve Vai: “Crossroads” How does the transformation of energy affect the total energy of a closed system? Hooke’s Law This is not to be confused with: Hook-meets-Peter-Banning-Attorney-At-Law QuickTime™ and a H.264 decompressor INSERT VIDEO CLIP are needed to see this picture. Youtube address How does the transformation of energy affect the total energy of a closed system? Hooke’s Law or with: T. J.-Hook-er-Enfor-s-er-of-the-Law How can the position of an object be quantified in terms of its potential energy? 6-4 Potential Energy The force increases as the spring is stretched or compressed further. We find that the potential energy of the compressed or stretched spring, measured from its equilibrium position, can be written: (6-9) How does the transformation of energy affect the total energy of a closed system? Story Time with Mr. Seuss What are two examples of potential energy in this story? QuickTime™ and a decompressor are needed to see this picture. http://www.youtube.com/watch?v=wKlynOMLWw0 How can the position of an object be quantified in terms of its potential energy? Pasco Hooke’s Law LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. How can the position of an object be quantified in terms of its potential energy? WebAssign/Lab Time • Work on WebAssign Problems 6.1 - 6.10, the Pasco Work and Energy Lab, or the Pasco Hooke’s Law Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) How can the position of an object be quantified in terms of its potential energy? Summary • Answer the Essential Questions. • Ticket out the Door: – What is the equation for gravitational potential energy? – What is the equation for elastic potential energy? – Why is the equation for Hooke’s Law negative? • HW: – Pasco Hooke’s Law Lab (Questions and Conclusions) – WebAssign Problems 6.1 - 6.10 UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 4 Conservative Forces and Nonconservative Forces; Conservation of Mechanical Energy After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions COE: Conservation of Mechanical Energy EQ(s): How does the transformation of energy affect the total energy of a closed system? Start: Solve the following equation for gy, multiply both sides by mass, m (Do not cancel out m), and then set the final conditions equal to the initial conditions: v 2 v02 2gy How does the transformation of energy affect the total energy of a closed system? START Derivation 2 v 2 v2 2v0 v2 02 2g g y y0 m v v0 mg 2 2 1 2 1 2 mv mv0 mgy0 mgy 2 2 1 2 1 2 mv0 mgy0 mv mgy 2 2 K 0 U0 K U 1 2 2 y y0 : (v v0 ) g 1m 2m g v v0 2 1 2 y y0 : (v v02 ) mg 3m 2m mg v v0 2 How does the transformation of energy affect the total energy of a closed system? 6-5 Conservative and Nonconservative Forces If friction is present, the work done depends not only on the starting and ending points, but also on the path taken. Friction is called a nonconservative force. How does the transformation of energy affect the total energy of a closed system? 6-5 Conservative and Nonconservative Forces Potential energy can only be defined for conservative forces. How does the transformation of energy affect the total energy of a closed system? 6-5 Conservative and Nonconservative Forces Therefore, we distinguish between the work done by conservative forces and the work done by nonconservative forces. We find that the work done by nonconservative forces is equal to the total change in kinetic and potential energies: (6-10) How does the transformation of energy affect the total energy of a closed system? 6-6 Mechanical Energy and Its Conservation If there are no nonconservative forces, the sum of the changes in the kinetic energy and in the potential energy is zero – the kinetic and potential energy changes are equal but opposite in sign. This allows us to define the total mechanical energy: And its conservation: (6-12b) How does the transformation of energy affect the total energy of a closed system? 6-7 Problem Solving Using Conservation of Mechanical Energy In the image on the left, the total mechanical energy is: The energy buckets (right) show how the energy moves from all potential to all kinetic. How does the transformation of energy affect the total energy of a closed system? 6-7 Problem Solving Using Conservation of Mechanical Energy 1 0 (Example 1) Determine the total mechanical energy at the top of the building, E0, and at the top of his jump, E1: E0 E1 K000 U K US0 UG0 K K111U UUS1S1S1U UU G1 SS00 U G G00 G1 G1 1 2 1 2 mv0 mgy0 mv1 mgy1 2 2 How does the transformation of energy affect the total energy of a closed system? 6-7 Problem Solving Using Conservation of Mechanical Energy (Example 2) Determine the total mechanical energy at the top of his jump, E1, and as he just touches the trampoline, E2: E1 E2 1 2 K111 U K US1 UG1 K K222U UUS2SS22U UU G2 S1 U G1 G1 GG 22 1 2 1 2 mv1 mgy1 mv2 mgy2 2 2 How does the transformation of energy affect the total energy of a closed system? 6-7 Problem Solving Using Conservation of Mechanical Energy (Example 3) Determine the total mechanical energy as he just touches the trampoline, E2, and as fully compresses the trampoline, E3: 2 3 E2 E3 K222U K K U USS2 U UG2 K K33 U U USS3S33U UU GG3G S22 U G G22 33 1 2 1 2 mv2 mgy2 kx3 2 2 How does the transformation of energy affect the total energy of a closed system? 6-7 Problem Solving Using Conservation of Mechanical Energy (Example 4) If there is no the speed of E0 friction, E1 a roller coaster will depend only on its height KK0 0U USS00 U UG0 U US1S1U UU G 0 K1 U G1G1 compared to its starting height. 1 2 mgy0 mv1 0 2 v1 2gy0 1 How does the transformation of energy affect the total energy of a closed system? 6-7 Problem Solving Using Conservation of Mechanical Energy (Example 5): Using conservation of mechanical energy for an elastic force at the start of the pole vault, E0, and at the top of the pole vault, E1: 1 E0 E1 K000 U K U SSS000 U UG0 K K111U UUS1S1S1U UU G1 G G00 G1 G1 1 2 1 2 1 2 mv0 kx0 mv1 mgy1 2 2 2 0 How does the transformation of energy affect the total energy of a closed system? Pasco Hooke’s Law LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. How does the transformation of energy affect the total energy of a closed system? WebAssign/Lab Time • Work on WebAssign Problems 6.1 - 6.14, the Pasco Work and Energy Lab, or the Pasco Hooke’s Law Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) How does the transformation of energy affect the total energy of a closed system? Summary • Answer the Essential Questions. • Ticket out the Door: – A block of mass m slides without friction along the looped track. If the block is to remain on the track, even at the top of circle (whose radius is r), from what minimum height h must it be released? • HW: – Pasco Hooke’s Law Lab (Questions and Conclusions) – WebAssign Problems 6.1 - 6.14 UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 5 Conservation of Energy After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • Yesterday’s TOTD A block “car” of of mass mass m m rolls slides without without friction friction along along the the looped looped track. track.If If the block car is to is to remain remain onon thethe track, track, even even at at thethe toptop of of circle circle (whose (whose radius is r), from what minimum height h must it be released? 0 222 111 vv m FvF rg mg rr 2 1 G v1 y0 E0 E1 KK0 0U U SS00 U UG0 U US1S1U UUG1G1 G 0 K1 U 1 FG r 1 111 2 2 mgy gygy rg mv rg v1 g2rg gy mgy 2r mgy 0gy 0 0000 1 1 11 2 222 5 y0 r 2 How does the transformation of energy affect the total energy of a closed system? COE: Conservation of Energy EQ(s): How does the transformation of energy affect the total energy of a closed system? Start: A bowling ball is hung from the ceiling by a steel wire. The instructor pulls the ball back and stands against the wall with the ball against his nose. To avoid injury the instructor is supposed to release the ball without pushing it. Why? How does the transformation of energy affect the total energy of a closed system? 6-8 Other Forms of Energy; Energy Transformations and the Conservation of Energy Some other forms of energy: Electric energy, nuclear energy, thermal energy, chemical energy. Work is done when energy is transferred from one object to another. In other words, theforms Law of of that Accounting for all ofConservation energy, we find Energy that energy is neither created nor the totalstates energy neither increases nor destroyed, is transferred one object to decreases. but Energy as a wholefrom is conserved. another. E E E 1 2 n How does the transformation of energy affect the total energy of a closed system? 6-9 Energy Conservation with Dissipative Processes; Solving Problems If there is a nonconservative force such as friction, where do the kinetic and potential energies go? They become heat; the actual temperature rise of the materials involved can be calculated. Please enter . . . The Collision Balls K U U0 K KU U KWNCK 0U U0 FNC d Recall thatKW0 NC Fr cos180 How does the transformation of energy affect the total energy of a closed system? 6-9 Energy Conservation with Dissipative Processes; Solving Problems Problem Solving: 1. Draw a picture. 2. Determine the system for which energy will be conserved. 3. Figure out what you are looking for, and decide on the initial and final positions. 4. Choose a logical reference frame. 5. Apply conservation of energy. 6. Solve. How does the transformation of energy affect the total energy of a closed system? Law of Conservation of Energy Will the bowling ball hit his chin upon its return? Explain. Where did the energy go? How does the transformation of energy affect the total energy of a closed system? Law of Conservation of Energy Will the bowling ball hit his chin upon its return? Explain. QuickTime™ and a decompressor are needed to see this picture. Where did the energy go? How does the transformation of energy affect the total energy of a closed system? The Pendulum of Pain Who puts their trust in Laws of Physics? QuickTime™ and a H.264 decompressor are needed to see this picture. How does the transformation of energy affect the total energy of a closed system? The Pendulum of Pain Who puts their trust in Laws of Physics? How does the transformation of energy affect the total energy of a closed system? Pasco Exp. 8: Projectile Velocity LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. INSERT LAB PICTURE How does the transformation of energy affect the total energy of a closed system? WebAssign/Lab Time • Work on WebAssign Problems 6.1 - 6.17, the Pasco Work and Energy Lab, Pasco Hooke’s Law Lab, or the Pasco Experiment 8: Projectile Velocity Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) How does the transformation of energy affect the total energy of a closed system? Summary • Answer the Essential Question. • Ticket out the Door: You drop a ball from a height of 2.0 m, and it bounces back to a height of 1.45 m: – What fraction of its initial energy is lost during the bounce? – What is the ball’s speed just as it leaves the ground after the bounce? – Where did the energy go? • HW: – Experiment 8: Projectile Velocity Lab (Questions and Conclusions) – WebAssign Problems 6.1 - 6.17 INSERT PICTURE UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 6 Power After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions UNIT Title: Section Title EQ(s):? Start: ? INSERT Picture EQ? TITLE INSERT NOTES HERE 6-10 Power Power is the rate at which work is done – (6-17) In the SI system, the units of power are watts: The difference between walking and running up these stairs is power – the change in gravitational potential energy is the same. 6-10 Power Power is also needed for acceleration and for moving against the force of gravity. The average power can be written in terms of the force and the average velocity: (6-17) How does the transformation of energy affect the total energy of a closed system? TITLE (Thought Question)? INSERT VIDEO CLIP Youtube address EQ? LAB TITLE LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. INSERT LAB PICTURE EQ? LAB TITLE REPORT •One Report for each group of no more than 4 people. •Refer to the Laboratory Report Expectations Handout. INSERT LAB PICTURE EQ: ? WebAssign/Lab Time • Work on WebAssign Problems ?.?? - ?.?? (*Except ?.??), the Lab Title Lab Report, or the Lab Title Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) EQ? Summary • Answer the Essential Questions. • Ticket out the Door: INSERT PICTURE • HW: – Lab Title REPORT – Lab Title Lab (Questions and Conclusions) – WebAssign Problems ?.? - ?.?? (*Except ?.??) UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 7 Power After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions UNIT Title: Section Title EQ(s):? Start: ? INSERT Picture EQ? TITLE INSERT NOTES HERE How does the transformation of energy affect the total energy of a closed system? TITLE (Thought Question)? INSERT VIDEO CLIP Youtube address EQ? LAB TITLE LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. INSERT LAB PICTURE EQ? LAB TITLE REPORT •One Report for each group of no more than 4 people. •Refer to the Laboratory Report Expectations Handout. INSERT LAB PICTURE EQ: ? WebAssign/Lab Time • Work on WebAssign Problems ?.?? - ?.?? (*Except ?.??), the Lab Title Lab Report, or the Lab Title Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) EQ? Summary • Answer the Essential Questions. • Ticket out the Door: INSERT PICTURE • HW: – Lab Title REPORT – Lab Title Lab (Questions and Conclusions) – WebAssign Problems ?.? - ?.?? (*Except ?.??) UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 8 Work Day #2 After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? LAB TITLE LAB •Work in groups of no more than 4 people. •Return all supplies to the counter/cart. INSERT LAB PICTURE UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? LAB TITLE REPORT •One Report for each group of no more than 4 people. •Refer to the Laboratory Report Expectations Handout. INSERT LAB PICTURE UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? WebAssign/Lab Time • Work on WebAssign Problems ?.?? - ?.?? (*Except ?.??), the Lab Title Lab Report, or Lab Title Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Summary • Answer the Essential Questions. • 3 - 2 - 1: – 3 Things You know well for the test. – 2 Questions you still have for the test. – 1 Thing you enjoyed from this unit. • HW: – Lab Title REPORT – Lab Title Lab (Questions and Conclusions) – WebAssign Problems ?.? - ?.?? (*Except ?.??) INSERT PICTURE UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 9 Summary / Work Day #3 After Attendance • • • • • • Place HW on my desk Pickup and sign out your computer Log into www.plutonium-239.com Select the Warm-Up link Complete today’s warm-up and submit it Logout and return the computer to the cart Feed Back for Google Docs • Was anything confusing on google docs? • Noteworthy Student Responses Review of Materials • WebAssign Questions UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Summary of Chapter 6 • Work: •Kinetic energy is energy of motion: • Potential energy is energy associated with forces that depend on the position or configuration of objects. • UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Summary of Chapter 6 • The net work done on an object equals the change in its kinetic energy. • If only conservative forces are acting, mechanical energy is conserved. • Power is the rate at which work is done. UEQ #1: How do forces affect the motion of objects? UEQ #2: What affects the forces acting on or between objects? Summary of the Causes of Force • Newton’s law of universal gravitation: • Coulomb’s law: • Satellites are able to stay in Earth orbit because of their large tangential speed. UEQ #1: How do forces affect the motion of objects? UEQ #2: What affects the forces acting on or between objects? †Causes of Force Essential Questions • How does centripetal acceleration affect the motion of an object? • What affects the strength of forces that act at a distance? • How do the four fundamental forces dominate nature? • How can we describe the motion of a satellite or planet? • How are forces and pressure related for solids, liquids, and gases? †Answer these before the test. UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? LAB TITLE REPORT •One Report for each group of no more than 4 people. •Refer to the Laboratory Report Expectations Handout. INSERT LAB PICTURE UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? WebAssign/Lab Time • Work on WebAssign Problems 6.1 - 6.22, the Lab Title Lab Report, or Lab Title Lab • Final Copy Criteria – – – – – State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) • Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? †EQ/WebAssign/Lab Time • †Answer the Essential Questions • Work on WebAssign Problems 6.1 - 6.22, the Lab Title Lab Report, or the Lab Title Lab • Final Copy Criteria – – – – – • State the problem (Ex. Find displacement) Draw a picture/diagram Provide a list or table of all given data (Ex. t = 2 s) Solve the problem symbolically (Ex. v=x/t x = vt) Plug in numbers and units to obtain answer. (Ex. x = (5 m/s)(2 s)= 10 m) Notes about WebAssign: – Positive vs. negative answers (Try a negative sign) – Look at the final unit (hours or minutes or seconds) UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Summary • Ticket out the Door: Write down two questions and their answer for the test tomorrow and turn it in. – One conceptual problem – One mathematical problem • HW (Write down in your Student Planner): – – – – – Answer the Essential Questions Lab Title Lab Report Lab Title Lab (Questions and Conclusions) WebAssign Problems 6.1 - 6.22 WebAssign Final Copy UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Day 10: Test Conservation of Energy UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? †After Attendance • Place HW on my desk (in Reverse Alphabetical Order): WebAssign Final Copy Essential Questions Laboratory Assignment(s) • Pickup the following: Chapter 7 Vocabulary Acceleration Scantron Sheet • Fill in the following on the scantron sheet front: Name: Write your name on it!! Subject: PIM Test: CEM1 Date: S10 Period: Block 2 UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? †Conservation of Energy Test #1 • Do not write on Part I (the scantron questions) • Put your name on Part II and complete it • Verify any corrections below that have made before submitting your test. • Complete the Chapter 7 Vocabulary Acceleration Test Corrections • Question UEQ: How does an object’s mass distribution and interactions with other objects and force at a distance influence the object’s motion? Summary • Ticket out the Door: Turn in the Conservation of Energy Test • HW: – Chapter 7 Vocabulary Acceleration How does the transformation of energy affect the total energy of a closed system? Law of Conservation of Energy Will the bowling ball hit his chin upon its return? Explain. QuickTime™ and a decompressor are needed to see this picture. Where did the energy go?