This Week. 5/27/2015 Physics 214 Summer
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1 This Week Circular motion Going round the bend Riding in a ferris wheel, the vomit comet Gravitation Our solar system, satellites (Direct TV) The orbit of the Earth,tides, Dark matter 5/27/2015 Physics 214 Summer
2 Circular Motion Circular motion is very common and very important in our everyday life. Satellites, the moon, the solar system and stars in galaxies all rotate in circular orbits. The term circular here is being used loosely since even repetitive closed motion is generally not a perfect circle. At any given instant an object that is not moving in a straight line is moving along the arc of a circle. So if we understand motion in a circle we can understand more complicated trajectories. Remember at any instant the velocity is along the path of motion but the acceleration can be in any direction. 5/27/2015 Physics 214 Summer
3 Circular motion a = v 2 /r F = ma = mv 2 /r If the velocity of an object changes direction then the object experiences an acceleration and a force is required. This is centripetal acceleration and force and is directed toward the center of the circle. This is the effect you feel rounding a corner in a car 5/27/2015 Physics 214 Summer
4 Balance of forces We need to understand the forces that are acting horizontally and vertically. In the case shown the tension or force exerted by the string has components which balance the weight in the vertical direction and provide the centripetal force horizontally. T v = W = mg T h = mv 2 /r 5/27/2015 Physics 214 Summer
5 1D-02 Conical Pendulum Could you find the NET force? T sin(θ) = mv 2 /R T cos(θ) = mg v = sqrt( gr tan(θ) ) Period of the pendulum τ= 2πR/v, where R = L / sin(θ) τ= 2πsqrt( Lcos(θ)/g ) NET FORCE IS TOWARD THE CENTER OF THE CIRCULAR PATH 5/27/2015 Physics 214 Summer
6 1D-03 Demonstrations of Central Force What will happen T THE SHAPES/SURFACES when it is OF SEMI-RIGID OBJECTS BECOME MORE T CURVED subjected TO PROVIDE to forces GREATER CENTRAL FORCES DURING ROTATION. during rotation? θ θ 2T cos (θ)= mv 2 /R 5/27/2015 Physics 214 Summer
7 Cars F f F f Rear When a car turns a corner it is friction between the tires and the road which provides the centripetal force. Above If the road is banked then the normal force also provides a force. For a banked track there is a velocity for which no friction is required. F f W = mg 5/27/2015 Physics 214 Summer
8 Vertical circles N If v = 0 then N = mg v W = mg mg N = mv 2 /r As v increases N becomes smaller g + is always toward the center of the circle Ferris wheel At the bottom N - mg = mv 2 /r When v 2 /r = g the car becomes weightless. Same as the vomit comet At the top Mg N = mv 2 /r 5/27/2015 Physics 214 Summer
9 1D-05 Twirling Wine Glass WHAT IS THE PHYSICS THAT KEEPS THE WINE FROM SPILLING? Same as m string v g N + mg = mv 2 /R N > 0 THE GLASS WANTS TO MOVE ALONG THE TANGENT TO THE CIRCLE AND THE REACTION FORCE OF THE PLATE AND GRAVITY PROVIDE THE CENTRIPETAL FORCE TO KEEP IT IN THE CIRCLE 5/27/2015 Physics 214 Summer
10 1D-07 Paper Saw THE RADIAL FORCES HOLDING THE PAPER TOGETHER MAKE THE PAPER RIGID. Is paper more rigid than wood? 5/27/2015 Physics 214 Summer
11 Free fall versus Weightless Near the earths surface there is a force F = mg which is called the weight of an object. Since the force of gravity is always present then this force always is present. There are situations where if we were standing on a scale the apparent weight, the reading on the scale, could be smaller or larger than the real weight. In an accelerating elevator In the case of free fall our apparent weight is zero In an elevator and the cable snaps. The case of being weightless corresponds to the case where one is moving in a circle and the force of gravity is exactly equal to the centripetal force required. Since the force of gravity is vertical the type of cases where weightlessness happens are At the top of a ferris wheel if mg = mv 2 /r At the top of a hump back bridge if mg = mv 2 /r 5/27/2015 Physics 214 Summer
12 Planes and satellites Vomit Comet This uses a plane moving in a circle so that mg = mv 2 /r Although this only occurs exactly at one point in the arc the The trajectory of the plane is designed so that the effect of gravity is very small for a much longer time Space station As a satellite circles the earth in a stable orbit we have all the time that the gravitational force exactly equals the centripetal force since the center of the earth is the center of the circle and the direction of gravity. So everything and everybody is weightless all the time independent of mass. That is toothbrushes and people are both weightless. GmM/r 2 = mv 2 /r or GM/r 2 = v 2 /r 5/27/2015 Physics 214 Summer
13 Gravitation and the planets Astronomy began as soon as man was able to observe the sky and records exist going back several thousand years. In particular the yearly variation of the stars in the sky and the motion of observable objects such as planets. People observed the fixed North Star and, for example, the rising of Sirius signaling the flooding of the Nile. Copernicus was the first person to advocate a sun centered solar system. Followed by Galileo who used the first telescopes Tycho Brahe was the most famous naked eye astronomer. Kepler, his assistant used the data to draw quantitative conclusions. 5/27/2015 Physics 214 Summer
14 Keplers Laws 1) Orbits are ellipses 2) The radius vector sweeps out areas in equal times equal 3) T 2 proportional to r 3 T is the period which for the earth is one year and r is the average radius For circular motion with constant velocity v The circumference of a circle is 2πR and the Period T = 2πr/v 5/27/2015 Physics 214 Summer
15 Newton and Gravitation Newton developed the Law of Gravitation force between two objects is F = GM 1 m 2 /r 2. The constant of proportionality was measured by Cavendish after more than 100 years G = 6.67 x N.m 2 /kg 2. Since at the earths surface mg = GmM e /r 2 the experiment measured the mass of the earth edu/class/applets/newtons Cannon/newtmtn.html 5/27/2015 Physics 214 Summer
16 Planetary orbits For a simple circular orbit GmM/r 2 = mv 2 /r Period T = 2πr/v T 2 /r 3 = 4π 2 /GM s where M is the mass of the sun and m the mass of the earth or M is the mass of the earth and m the mass of a satellite. For a geosynchronous orbit period is 24 hours and height above the earths surface is 22,000miles 5/27/2015 Physics 214 Summer
17 Calculations GmM e /r 2 = mv 2 /r where M e is the mass of the earth and m the mass of a satellite. At the earths surface mg = GmM e /R e 2 v 2 = gr e 2 / r for a stable orbit So at the earths surface V = ~ 17500mph For a synchronous satellite at a height of 22,000 miles V = ~6500mph V decreases with distance. The moon is losing energy because of the tides so it is moving away from us. r v 5/27/2015 Physics 214 Summer
18 1D-04 Radial Acceleration & Tangential Velocity Once the string is cut, where is the ball going? AT ANY INSTANT, THE VELOCITY VECTOR OF THE BALL IS DIRECTED ALONG THE TANGENT. AT THE INSTANT WHEN THE BLADE CUTS THE STRING, THE BALL S VELOCITY IS HORIZONTAL SO IT ACTS LIKE A HORIZONTALLY LAUNCHED PROJECTILE AND LANDS IN THE CATCH BOX. 5/27/2015 Physics 214 Summer
19 1D-08 Ball in Ring Is the ball leaving in a straight line or continuing this circular path? THE FORCE WHICH KEEPS THE BALL MOVING CIRCULAR IS PROVIDED BY THE RING. ONCE THE FORCE IS REMOVED, THE BALL CONTINUES IN A STRAIGHT LINE, ACCORDING TO NEWTON S FIRST LAW. 5/27/2015 Physics 214 Summer
20 Summary of Chapter 5 Circular motion and centripetal acceleration and force. F c = mv 2 /r Ferris wheel, car around a corner or over a hill. Gravitation and Planetary orbits For a simple circular orbit GmM/r 2 = mv 2 /r M is the mass of the sun and m the mass of the earth. v 2 = GM/r T = 2πr/v T 2 = 4π 2 r 2 /v 2 = 4π 2 r 3 /GM s T 2 /r 3 = 4π 2 /GM s 5/27/2015 Physics 214 Summer
21 Examples of circular motion Vertical motion Looking down N v N v W = mg mg N = mv 2 /r N N = mv 2 /r Side F f v T mg mg N - mg = mv 2 /r mg mg = F f mg + T = mv 2 /r top T - mg = mv 2 /r bottom 5/27/2015 Physics 214 Summer
22 The Orbit of the Earth The Tropic of Capricorn, or Southern tropic, marks the most southerly latitude at which the sun can appear directly overhead at noon. This event occurs at the December solstice, when the southern hemisphere is tilted towards the sun to its maximum extent. The Tropic of Cancer, also referred to as the Northern tropic, is the circle of latitude on the Earth that marks the most northerly position at which the Sun may appear directly overhead at its zenith. This event occurs once per year, at the time of the June solstice, when the Northern Hemisphere is tilted toward the Sun to its maximum extent. 5/27/2015 Physics 214 Summer
23 Moon and tides Tides are dominantly due to the gravitational force exerted by the moon. The moon pulls water toward it, and this causes the bulge toward the moon. The bulge on the side of the Earth opposite the moon is caused by the moon "pulling the Earth away" from the water on that side.since the earth and moon are rotating this effect also plays a role. The moon is locked to the earth so that we always see the same face. Because of the friction generated by tides the moon is losing energy and moving away from the earth. New moon Full moon 5/27/2015 Physics 214 Summer
24 Dark Matter For the orbit of a body of mass m about a much more massive body of mass M GmM/r 2 = mv 2 /r and GM/r = v 2. In fact M is the mass inside the orbit, that is the sun could be nearly as big as the orbit of the earth and it would not change anything. If we look at stars in motion in galaxies we find there is not enough normal matter to provide the necessary gravitational force. We believe this is caused by a new form of matter, which we call dark matter, and it comprises 25% of the energy in our Universe.(normal matter = 4.4%) 5/27/2015 Physics 214 Summer
25 Trajectories to other planets To launch a space craft from earth to say Mars or Jupiter is quite complicated since all the planets are moving including the earth. One needs to be able to calculate a trajectory that minimizes the amount of fuel required. That is why in nearly all launches there are specific time windows which are optimum. 5/27/2015 Physics 214 Summer
26 Questions Chapter 5 Q6 A ball on the end of a string is whirled with constant speed in a counterclockwise horizontal circle. At point A in the circle, the string breaks. Which of the curves sketched below most accurately represents the path that the ball will take after the string breaks (as seen from above)? Explain. 4 3 A 2 1 Path number 3 5/27/2015 Physics 214 Summer
27 Q8 For a ball twirled in a horizontal circle at the end of a string, does the vertical component of the force exerted by the string produce the centripetal acceleration of the ball? Explain. Vertical component balances the weight Horizontal component provides the acceleration Q9 A car travels around a flat (unbanked) curve with constant speed. A. Show all of the forces acting on the car. B. What is the direction of the net force act. F f N mg Rear The force acts toward the center of the turn circle 5/27/2015 Physics 214 Summer
28 Q10 Is there a maximum speed at which the car in question 9 will be able to negotiate the curve? If so, what factors determine this maximum speed? Explain. Yes. The friction between the tires and the road Q11 If a curve is banked, is it possible for a car to negotiate the curve even when the frictional force is zero due to very slick ice? Explain. Yes there is just one speed. If the car moves too slowly it will slide down. If it moves to fast it will slide up. 5/27/2015 Physics 214 Summer
29 Q12 If a ball is whirled in a vertical circle with constant speed, at what point in the circle, if any, is the tension in the string the greatest? Explain. (Hint: Compare this situation to the Ferris wheel described in section 5.2). The tension is the greatest at the bottom because the string has to support the weight and provide the force for the centripetal acceleration. Q19 Does a planet moving in an elliptical orbit about the sun move fastest when it is farthest from the sun or when it is nearest to the sun? Explain by referring to one of Kepler s laws. When it is nearest 5/27/2015 Physics 214 Summer
30 Q20 Does the sun exert a larger force on the earth than that exerted on the sun by the earth? Explain. The magnitude of the forces is the same they are a reaction/action pair Q23 Two masses are separated by a distance r. If this distance is doubled, is the force of interaction between the two masses doubled, halved, or changed by some other amount? Explain. The force reduces by a factor of 4 5/27/2015 Physics 214 Summer
31 Ch 5 E 14 The acceleration of gravity at the surface of the moon is about 1/6 that at the surface of the Earth (9.8 m/s 2 ). What is the weight of an astronaut standing on the moon whose weight on earth is 180 lb? W earth = m g earth = 180 lb W moon = m g moon g moon = 1/6 g earth W moon = m 1/6 g earth = 1/6 m g earth = 1/6 (180 lb) g moo n 5/27/2015 Physics 214 Summer
32 Ch 5 E 16 Time between high tides = 12 hrs 25 minutes. High tide occurs at 3:30 PM one afternoon. a) When is high tide the next afternoon b) When are low tides the next day? a) 3:30 PM + 2 (12 hrs 25 min) high tide T= 12hrs 25min = 3:30 PM + 24 hrs + 50 min t = 4:20 PM low tide T= 12hrs 25min b) Low tide the next day = 4:20 PM - 6 hr 12 min 30 s = 10:07:30 AM 2nd Low tide = 10:07:30 AM + 12 hrs 25 min = 10:32:30 PM 5/27/2015 Physics 214 Summer
33 Ch 5 CP 2 A Ferris wheel with radius 12 m makes one complete rotation every 8 seconds. a) Rider travels distance 2 r every rotation. What speed do riders move at? b) What is the magnitude of their centripetal acceleration? c) For a 40 kg rider, what is magnitude of centripetal force to keep him moving in a circle? Is his weight large enough to provide this centripetal force at the top of the cycle? d) What is the magnitude of the normal force exerted by the seat on the rider at the top? e) What would happen if the Ferris wheel is going so fast the weight of the rider is not sufficient to provide the centripetal force at the top? 5/27/2015 Physics 214 Summer
34 Ch 5 CP 2 (con t) a) S = d/t = 2 r/t = 2 (12m)/8s = 9.42 m/s F cent b) a cent = v 2 /r = s 2 /r = (9.42m/s) 2 /12m = 7.40 m/s 2 c) F cent = m v 2 /r = m a cent = (40 kg)(7.40 m/s 2 ) = 296 N W = mg = (40 kg)(9.8 m/s 2 ) = 392 N Yes, his weight is larger than the centripetal force required. d) W N f = 296 N = 96 newtons e) rider is ejected N 5/27/2015 Physics 214 Summer W
35 A passenger in a rollover accident turns through a radius of 3.0m in the seat of the vehicle making a complete turn in 1 sec. a) Circumference = 2 r, what is speed of passenger? b) What is centripetal acceleration? Compare it to gravity (9.8 m/s 2 ) c) Passenger has mass = 60 kg, what is centripetal force required to produce the acceleration? Compare it to passengers weight. a) s = d/t = 2 (3.0m)/1 = 19m/s Ch 5 CP 4 b) a = v 2 /r = s 2 /r = (19 m/s) 2 /3m = 118 m/s 2 = 12g 3 m c) F = ma = (60 kg)(118 m/s 2 ) = 7080 N F = ma = m (12 g) = 12 mg = 12 weight 5/27/2015 Physics 214 Summer
36 Ch 5 CP 6 The period of the moons orbit about the earth is 27.3 days, but the average time between full moons is 29.3 days. The difference is due to the Earth s rotation about the Sun. a) Through what fraction of its total orbital period does the Earth move in one period of the moons orbit? b) Sketch the sun, earth & moon at full moon condition. Sketch again 27.3 days later. Is this a full moon? c) How much farther does the moon have to move to be in full moon condition? Show that it is approx. 2 days. a) Earth orbital period = 365 days = 0 E Moon orbital period = 27.3 days = 0 M 0 M /0 E = 27.3/ /27/2015 Physics 214 Summer
37 Ch 5 CP 6 (con t) b) Day 0 E M Full Moon (i) S (ii) S E M 27.3 Days Later This is not a full moon. (iii) S E M This is the next full moon. c) For moon to achieve full moon condition, it must sit along the line connecting sun & earth. In part (a) we found that the earth has moved thru of its full orbit in 27.3 days (see diagram (ii)). To be inline w/ sun and earth, moon must move thru same fraction of orbit (see diagram (iii)) (27.3 days) 2 days. 5/27/2015 Physics 214 Summer
38 Space Elevator station v counterweight 100,000km The Space Elevator is a thin ribbon, with a cross-section area roughly half that of a pencil, extending from a ship-borne anchor to a counterweight well beyond geo-synchronous orbit. The ribbon is kept taut due to the rotation of the earth (and that of the counterweight around the earth). At its bottom, it pulls up on the anchor with a force of about 20 tons. The ribbon is 62,000 miles long, about 3 feet wide, and is thinner than a sheet of paper. It is made out of a carbon nanotube composite material. Electric vehicles, called climbers, ascend the ribbon using electricity generated by solar panels and a ground based booster light beam. 5/27/2015 Physics 214 Summer
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