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Transcript
Physics 218 Lecture 21 Dr. David Toback Physics 218, Lecture XXI 1 Schedule for the Rest of the Semester • • • • • • • • • Today: Chapter 12 Tuesday Nov 21st: Exam 3 Thursday Nov 23rd: No class, Thanksgiving Tuesday November 28th: Chapter 13, Part 1 Thursday November 30th: Chapter 13, Part 2 Tuesday December 5th: Final Exam Review No lecture on December 7th (Reading day) Final exam is Monday, December 11th, 1-3PM We will skip Chapter 15 Physics 218, Lecture XXI 2 Chapter 12: Overview • Newton’s gravitational law • Dynamics and Gravity • Gravity and Uniform Circular Motion • Escape Velocity Physics 218, Lecture XXI 3 Physics 218, Lecture XXI 4 Gravitation Newton’s law of Universal Gravitation “Every particle in the universe attracts every other particle” Physics 218, Lecture XXI 5 Large number of scales Kinda amazing! Gravity covers the attraction between – – – – – – – – An apple near the earth The earth and the moon The earth and the sun The sun and our galaxy Our galaxy and the universe Every particle in the universe and an apple The Earth and you Bevo and Reveille Physics 218, Lecture XXI 6 Newton’s Law “Every particle in the universe attracts every other particle with a force that is proportional to the product of their masses and inversely proportional to the square of the distance between them. This force acts along the line joining the particles” • Gravity has a magnitude and direction Gravity is a force Physics 218, Lecture XXI 7 The Force of Gravity m1m 2 Fgravity G 2 (rˆ) r Direction of the Distance between force the masses G 6.67 10 11 N m /kg 2 2 Physics 218, Lecture XXI 8 The motion of the moon and the planets • One of the great achievements of physics is that it explains the motion of planets • It took awhile, but they eventually figured out that the motion of the planets made much more sense if one assumed that the Sun was the center of motion rather than the Earth • Newton was able to use his gravitational law and Uniform Circular Motion to “Predict” these observations Physics 218, Lecture XXI 9 Gravity and Circular Motion • Use the force of gravity along with other forces in force diagrams • Circular motion is motion with the acceleration pointed towards the center of the circle • The Earth is a good “center” acceleration for Satellites and Moons Physics 218, Lecture XXI 10 Binary System Two equal mass stars maintain a constant distance RS apart and rotate about a point, midway between them, at a revolution rate of once per time T What must be the mass of each star? RS Physics 218, Lecture XXI 11 Gravitational Potential Energy How much potential energy does a ball of mass m have in outer space? Assuming you know ME and G, calculate how much work you would have to do move a ball from the surface of the earth to some distance R Physics 218, Lecture XXI R 12 Escape Velocity • What happens if I throw a ball up in the air? Will it fall down? • What if I throw it up really fast? • What if I throw it up REALLY fast? • Can I throw it up so fast that it will never come down? How fast would that be? Physics 218, Lecture XXI 13 Example: Geosynchronous Satellite A satellite is in orbit around the Earth and its speed is such that it always stays above the same point on the earth throughout the day. Assuming a spherical Earth with mass ME, determine the height of the satellite (from the center of the Earth) in terms of the period, ME and G Physics 218, Lecture XXI 14 Next Week • Monday: Chapter 11 HW due • Tuesday: Exam 3 – Covers Chapter 8 through 11 • Only sections listed on the syllabus – Mini-practice exam is open and available for people who are caught up. Usual 5 points • Thursday: Thanksgiving, no class • Following Tuesday: Lecture on Chapter 13 – Periodic Motion Physics 218, Lecture XXI 15 Physics 218, Lecture XXI 16 Note: Do not sell your textbook! You will need the same book for 208 Physics 218, Lecture XXI 17 Three Bodies Three bodies of identical and known mass M form the vertices of an equilateral triangle of side L. They rotate in circular orbits around the center of the triangle and are held in place by their mutual gravitation. What is the speed of each? L L L Physics 218, Lecture XXI 18 Density of a Planet A satellite orbits very near a planet’s surface (I.e., R=RPlanet, but we don’t know R) with period T. What is the density of the planet in terms of the measured period T? Physics 218, Lecture XXI 19 Kepler’s st 1 Law Kepler: The path of each planet about the Sun is an ellipse with the Sun at one focus. Newton: Gravity gives a center seeking force! Centripetal forces can lead to both elliptical motion or circular motion (circular motion is just a special case which we happen to have studied already!) Physics 218, Lecture XXI 20 Kepler’s nd 2 Law Kepler: Each planet moves so that an imaginary line drawn from the Sun to the planet sweeps out area in equal periods of time Newton: Can show this, but it’ll be easier when we get to angular momentum. We’ll come back to this later Physics 218, Lecture XXI 21 Kepler’s rd 3 Law Kepler: The ratio of the squares of the periods of any two planets revolving about the Sun is equal to the ratio of the cubes of their semi-major axes. 2 T1 S1 T S 2 2 3 For a Circle S = Radius Physics 218, Lecture XXI 22 Derivation of rd 3 Law for a Circle Let’s say there are two small planets revolving around the sun in circular motion with periods T1 and T2 and radii R1 and R2 respectively. Use Newton’s laws to show the following: 2 T1 R 1 T R 2 2 3 Physics 218, Lecture XXI Assume the masses of the planets are so small or that they are so far apart that we may neglect the gravitational attraction between the two. 23 Understanding the motion of planets • One of the great achievements of physics is that it explains the motion of planets • It took awhile, but they eventually figured out that the motion of the planets made much more sense if one assumed that the Sun was the center of motion rather than the Earth • Then Kepler made some important observations WAY before Newton • Newton was able to “Predict” these observations (and now so are we…) Physics 218, Lecture XXI 24 A way simplify problems It takes some fancy integration, but one can show that we can “model” the Earth as if all the mass were concentrated at its center • One can model any sphere as a point • This is why we like to model things as spheres in the first place. Physics 218, Lecture XXI 25 Calculate the Magnitude of g For a person on the earth what is g. Use 24 – MEarth = 5.97*10 kg -11 2 2 – G = 6.67*10 N*m /kg – R = REarth = 6.38*106 m Physics 218, Lecture XXI 26 Ok… So what? A single formula can show that: 1. the acceleration of an apple towards the Earth has magnitude g and is pointing down 2. as you may have noticed, Bevo and Reveille aren’t attracted to each other very much Physics 218, Lecture XXI 27 Bevo and Reveille Bevo and Reveille have masses mB and mR and are standing D meters apart. Despite what you might like to believe, what is the attraction between them? More specifically, find Reveille’s acceleration. Hint: Assume a spherical cow Perhaps this explains why we’ve never observed any attraction… Physics 218, Lecture XXI 28 How to solve these types of problems • Some thoughts – What keeps a satellite up? Its speed – |Accel| = v2/r – |Force| = ma = mv2/r • The trick is going to be to ask the question – What are the forces? Is it in uniform circular motion? If so, we can use Newton’s law: FGravity = FUniform Circular Motion Physics 218, Lecture XXI 29 Space craft in Orbit A space craft, with mass m, is circling the earth at radius R = 2rEarth. What is the force on the space craft in terms of g and m? Model the space craft as a single point near the Earth which we model as a point at its center Physics 218, Lecture XXI 30 Satellites/Orbiting Problems A satellite problem is a good example of the substantive problems we need to be able to solve. Predict the outcome of the experiment Physics 218, Lecture XXI 31 Weightlessness • What is the weight of the person in the figure? • What is the difference between being in “free fall” and being “out of the reach of large gravitational forces?” Physics 218, Lecture XXI 32 Throwing a Baseball A person throws a baseball at 100 km/hr, but it is attracted back towards him because of gravity. • Estimate the force 1 Meter away? • Assuming constant acceleration (Bad assumption), how long does it take to turn around? Physics 218, Lecture XXI 33 Vector Form Force ON mass 2 due to mass 1 m1m 2 F21 G 2 rˆ12 r21 Physics 218, Lecture XXI 34 More on Vector Form r̂21 r̂12 By Newtons Laws : F21 F12 Physics 218, Lecture XXI 35