Deck 6: Circular Motion and Other Applications of Newtons Laws

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Question
A car travels along the perimeter of a vertical circle (radius = 0.25 km)at a constant speed of 30 m/s.What is the magnitude of the resultant force on the 60-kg driver of the car at the lowest point on this circular path?

A)0.37 kN
B)0.80 kN
C)0.22 kN
D)0.59 kN
E)0.45 kN
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Question
A highway curve has a radius of 0.14 km and is unbanked.A car weighing 12 kN goes around the curve at a speed of 24 m/s without slipping.What is the magnitude of the horizontal force of the road on the car?

A)12 kN
B)17 kN
C)13 kN
D)5.0 kN
E)49 kN
Question
An object attached to the end of a string swings in a vertical circle (R = 1.2 m),as shown.At an instant when θ = 30°,the speed of the object is 5.1 m/s and the tension in the string has a magnitude of 20 N.What is the mass of the object? <strong>An object attached to the end of a string swings in a vertical circle (R = 1.2 m),as shown.At an instant when θ = 30°,the speed of the object is 5.1 m/s and the tension in the string has a magnitude of 20 N.What is the mass of the object?  </strong> A)2.0 kg B)1.5 kg C)1.8 kg D)1.2 kg E)0.80 kg <div style=padding-top: 35px>

A)2.0 kg
B)1.5 kg
C)1.8 kg
D)1.2 kg
E)0.80 kg
Question
A 30-kg child rides on a circus Ferris wheel that takes her around a vertical circular path with a radius of 20 m every 22 s.What is the magnitude of the resultant force on the child at the highest point on this trajectory?

A)49 N
B)0.29 kN
C)0.34 kN
D)0.25 kN
E)0.76 kN
Question
A 0.30-kg mass attached to the end of a string swings in a vertical circle (R = 1.6 m),as shown.At an instant when θ = 50°,the tension in the string is 8.0 N.What is the magnitude of the resultant force on the mass at this instant? <strong>A 0.30-kg mass attached to the end of a string swings in a vertical circle (R = 1.6 m),as shown.At an instant when θ = 50°,the tension in the string is 8.0 N.What is the magnitude of the resultant force on the mass at this instant?  </strong> A)5.6 N B)6.0 N C)6.5 N D)5.1 N E)2.2 N <div style=padding-top: 35px>

A)5.6 N
B)6.0 N
C)6.5 N
D)5.1 N
E)2.2 N
Question
A 0.50-kg mass attached to the end of a string swings in a vertical circle (radius = 2.0 m).When the string is horizontal,the speed of the mass is 8.0 m/s.What is the magnitude of the force of the string on the mass at this position?

A)16 N
B)17 N
C)21 N
D)11 N
E)25 N
Question
An airplane travels 80 m/s as it makes a horizontal circular turn which has a 0.80-km radius.What is the magnitude of the resultant force on the 75-kg pilot of this airplane?

A)0.69 kN
B)0.63 kN
C)0.66 kN
D)0.60 kN
E)0.57 kN
Question
A roller-coaster car has a mass of 500 kg when fully loaded with passengers.The car passes over a hill of radius 15 m,as shown.At the top of the hill,the car has a speed of 8.0 m/s.What is the force of the track on the car at the top of the hill? <strong>A roller-coaster car has a mass of 500 kg when fully loaded with passengers.The car passes over a hill of radius 15 m,as shown.At the top of the hill,the car has a speed of 8.0 m/s.What is the force of the track on the car at the top of the hill?  </strong> A)7.0 kN up B)7.0 kN down C)2.8 kN down D)2.8 kN up E)5.6 kN down <div style=padding-top: 35px>

A)7.0 kN up
B)7.0 kN down
C)2.8 kN down
D)2.8 kN up
E)5.6 kN down
Question
A 0.20-kg object attached to the end of a string swings in a vertical circle (radius = 80 cm).At the top of the circle the speed of the object is 4.5 m/s.What is the magnitude of the tension in the string at this position?

A)7.0 N
B)2.0 N
C)3.1 N
D)5.1 N
E)6.6 N
Question
A 50-kg child riding a Ferris wheel (radius = 10 m)travels in a vertical circle.The wheel completes one revolution every 10 s.What is the magnitude of the force on the child by the seat at the highest point on the circular path?

A)0.29 kN
B)0.49 kN
C)0.69 kN
D)0.20 kN
E)0.40 kN
Question
An airplane moves 140 m/s as it travels around a vertical circular loop which has a 1.0-km radius.What is the magnitude of the resultant force on the 70-kg pilot of this plane at the bottom of this loop?

A)2.1 kN
B)1.4 kN
C)0.69 kN
D)1.5 kN
E)1.3 kN
Question
A 4.0-kg mass on the end of a string rotates in a circular motion on a horizontal frictionless table.The mass has a constant speed of 2.0 m/s and the radius of the circle is 0.80 m.What is the magnitude of the resultant force acting on the mass?

A)39 N
B)20 N
C)44 N
D)0 N
E)30 N
Question
A roller-coaster car has a mass of 500 kg when fully loaded with passengers.At the bottom of a circular dip of radius 40 m (as shown in the figure)the car has a speed of 16 m/s.What is the magnitude of the force of the track on the car at the bottom of the dip? <strong>A roller-coaster car has a mass of 500 kg when fully loaded with passengers.At the bottom of a circular dip of radius 40 m (as shown in the figure)the car has a speed of 16 m/s.What is the magnitude of the force of the track on the car at the bottom of the dip?  </strong> A)3.2 kN B)8.1 kN C)4.9 kN D)1.7 kN E)5.3 kN <div style=padding-top: 35px>

A)3.2 kN
B)8.1 kN
C)4.9 kN
D)1.7 kN
E)5.3 kN
Question
A 0.40-kg mass attached to the end of a string swings in a vertical circle having a radius of 1.8 m.At an instant when the string makes an angle of 40 degrees below the horizontal,the speed of the mass is 5.0 m/s.What is the magnitude of the tension in the string at this instant?

A)9.5 N
B)3.0 N
C)8.1 N
D)5.6 N
E)4.7 N
Question
A 0.50 kg mass attached to the end of a string swings in a vertical circle (radius = 2.0 m).When the mass is at the highest point of the circle the speed of the mass is 8.0 m/s.What is the magnitude of the force of the string on the mass at this position?

A)21 N
B)11 N
C)16 N
D)26 N
E)36 N
Question
An amusement ride consists of a car moving in a vertical circle on the end of a rigid boom.The radius of the circle is 10 m.The combined weight of the car and riders is 5.0 kN.At the top of the circle the car has a speed of 5.0 m/s which is not changing at that instant.What is the force of the boom on the car at the top of the circle?

A)3.7 kN down
B)1.3 kN down
C)6.3 kN up
D)3.7 kN up
E)5.2 kN down
Question
A 0.50-kg mass attached to the end of a string swings in a vertical circle (radius = 2.0 m).When the mass is at the lowest point on the circle,the speed of the mass is 12 m/s.What is the magnitude of the force of the string on the mass at this position?

A)31 N
B)36 N
C)41 N
D)46 N
E)23 N
Question
A car travels around an unbanked highway curve (radius 0.15 km)at a constant speed of 25 m/s.What is the magnitude of the resultant force acting on the driver,who weighs 0.80 kN?

A)0.87 kN
B)0.34 kN
C)0.80 kN
D)0.00 kN
E)0.67 kN
Question
A stunt pilot weighing 0.70 kN performs a vertical circular dive of radius 0.80 km.At the bottom of the dive,the pilot has a speed of 0.20 km/s which at that instant is not changing.What force does the plane exert on the pilot?

A)3.6 kN up
B)4.3 kN up
C)2.9 kN down
D)2.9 kN up
E)5.8 kN down
Question
A race car travels 40 m/s around a banked (45° with the horizontal)circular (radius = 0.20 km)track.What is the magnitude of the resultant force on the 80-kg driver of this car?

A)0.68 kN
B)0.64 kN
C)0.72 kN
D)0.76 kN
E)0.52 kN
Question
A 4.0-kg mass attached to the end of a string swings in a vertical circle of radius 2.0 m.When the string makes an angle of 35° with the vertical as shown,the speed of the mass is 5.0 m/s.At this instant what is the magnitude of the force the string exerts on the mass? <strong>A 4.0-kg mass attached to the end of a string swings in a vertical circle of radius 2.0 m.When the string makes an angle of 35° with the vertical as shown,the speed of the mass is 5.0 m/s.At this instant what is the magnitude of the force the string exerts on the mass?  </strong> A)50 N B)82 N C)89 N D)11 N E)61 N <div style=padding-top: 35px>

A)50 N
B)82 N
C)89 N
D)11 N
E)61 N
Question
A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?

A) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
B) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
C) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
D) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
E) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
Question
The equation below is the solution to a problem. <strong>The equation below is the solution to a problem.   ) The best physical representation of this equation is</strong> A)a sphere of 2.00 kg mass under a 45.2 N tension when at the bottom of a vertical circle. B)a sphere of 2.00 kg mass under a 45.2 N tension when at the side of a vertical circle. C)a sphere of 2.00 kg mass under a 45.2 N tension when at the top of a vertical circle. D)a sphere of 2.00 kg mass at any point on a horizontal circle. E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s. <div style=padding-top: 35px>
)
The best physical representation of this equation is

A)a sphere of 2.00 kg mass under a 45.2 N tension when at the bottom of a vertical circle.
B)a sphere of 2.00 kg mass under a 45.2 N tension when at the side of a vertical circle.
C)a sphere of 2.00 kg mass under a 45.2 N tension when at the top of a vertical circle.
D)a sphere of 2.00 kg mass at any point on a horizontal circle.
E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
Question
A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?

A) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
B) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
C) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
D) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
E) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
Question
A hornet circles around a pop can at increasing speed while flying in a path with a 12-cm diameter.We can conclude that the hornet's wings must push on the air with force components that are

A)straight down.
B)down and inwards.
C)down and outwards.
D)down and backwards.
E)down,backwards and outwards.
Question
The equation below is the solution to a problem. <strong>The equation below is the solution to a problem.   ) The best physical representation of this equation is</strong> A)a sphere of 2.00 kg mass under a 25.6 N tension when at the bottom of a vertical circle. B)a sphere of 2.00 kg mass under a 25.6 N tension when at the side of a vertical circle. C)a sphere of 2.00 kg mass under a 25.6 N tension when at the top of a vertical circle. D)a sphere of 2.00 kg mass at any point on a horizontal circle. E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s. <div style=padding-top: 35px>
)
The best physical representation of this equation is

A)a sphere of 2.00 kg mass under a 25.6 N tension when at the bottom of a vertical circle.
B)a sphere of 2.00 kg mass under a 25.6 N tension when at the side of a vertical circle.
C)a sphere of 2.00 kg mass under a 25.6 N tension when at the top of a vertical circle.
D)a sphere of 2.00 kg mass at any point on a horizontal circle.
E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
Question
A race car traveling at 100 m/s enters an unbanked turn of 400 m radius.The coefficient of (static)friction between the tires and the track is 1.1.The track has both an inner and an outer wall.Which statement is correct?

A)The race car will crash into the outer wall.
B)The race car will crash into the inner wall.
C)The car will stay in the center of the track.
D)The car will stay in the center of the track if the driver speeds up.
E)The car would stay in the center of the track if the radius were reduced to 200 m.
Question
A split highway has a number of lanes for traffic.For traffic going in one direction,the radius for the inside of the curve is half the radius for the outside.One car,car A,travels on the inside while another car of equal mass,car B,travels at equal speed on the outside of the curve.Which statement about resultant forces on the cars is correct?

A)The force on A is half the force on B.
B)The force on B is half the force on A.
C)The force on A is four times the force on B.
D)The force on B is four times the force on A.
E)There is no net resultant force on either as long as they stay on the road while turning.
Question
The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )The maximum safe speed on the track on the planet is ____ times as large as the maximum safe speed on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00 <div style=padding-top: 35px>
Compared to Earth's <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )The maximum safe speed on the track on the planet is ____ times as large as the maximum safe speed on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00 <div style=padding-top: 35px>
)The maximum safe speed on the track on the planet is ____ times as large as the maximum safe speed on Earth.

A)0.250
B)0.500
C)1.00
D)2.00
E)4.00
Question
The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )If the car is to be able to travel at the same speed on the planet as on Earth,the radius of the track on the planet must be ____ times as large as the radius of the track on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00 <div style=padding-top: 35px>
Compared to Earth's <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )If the car is to be able to travel at the same speed on the planet as on Earth,the radius of the track on the planet must be ____ times as large as the radius of the track on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00 <div style=padding-top: 35px>
)If the car is to be able to travel at the same speed on the planet as on Earth,the radius of the track on the planet must be ____ times as large as the radius of the track on Earth.

A)0.250
B)0.500
C)1.00
D)2.00
E)4.00
Question
A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?

A) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
B) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
C) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
D) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
E) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)   <div style=padding-top: 35px>
Question
A boy on board a cruise ship drops a 30.0 gm marble into the ocean.If the resistive force proportionality constant is 0.500 kg/s,what is the terminal speed of the marble in m/s?

A)0.147
B)0.294
C)0.588
D)1.18
E)2.35
Question
For a plane to be able to fly clockwise in a horizontal circle as seen from above,in addition to exerting a force downwards on the air

A)it must be increasing its speed.
B)it must exert a force on the air that is directed to the plane's left side.
C)it must exert a force on the air that is directed to the plane's right side.
D)it does not need to exert a force: it must only move the wing flaps out.
E)it only needs to deflect the air without exerting any additional force on the air.
Question
Two small cylindrical plastic containers with flat bottoms are placed on a turntable that has a smooth flat surface.Canister A is empty;canister B contains lead shot.Each canister is the same distance r from the center.The coefficient of static friction between the canisters and the turntable is μs.When the speed of the turntable is gradually increased,

A)only the lighter container slides outward off the turntable;the heavier one stays on.
B)only the heavier container slides outward off the turntable;the lighter one stays on.
C)both containers slide off the turntable at the same turntable speed.
D)the lighter container slides inward.
E)the heavier container slides inward.
Question
A student is sitting on the right side of a school bus when it makes a right turn.We know that the force of gravity acts downwards and a normal force from the seat acts upwards.If the student stays in place when the bus turns,we also know that there must be

A)no other force on the student.
B)a force parallel to the seat directed forward on the student.
C)a force parallel to the seat directed to the left on the student.
D)a force parallel to the seat directed to the right on the student.
E)a force parallel to the seat in a direction between forward and left on the student.
Question
A hornet circles around a pop can at constant speed once per second in a path with a 12-cm diameter.We can conclude that the hornet's wings must push on the air with force components that are

A)straight down.
B)down and inwards.
C)down and outwards.
D)down and backwards.
E)down,inwards and backwards.
Question
Frank says that if you release the string when swinging a ball in a horizontal circle,the ball flies out in the radial direction defined by the string at the instant you release the ball.John says that it flies out along a tangent line perpendicular to the string,and that it then drops straight down to the ground.Which one,if either,is correct?

A)Frank,because the centrifugal force is no longer counteracted by the string.
B)Frank,because balls naturally fly straight out.
C)John,because there is no centrifugal force.
D)John,because balls fall straight down when released.
E)Neither,because although there is no centrifugal force,and the ball's velocity is tangent to the circle at the instant of release,the ball then follows a parabolic trajectory.
Question
When a car goes around a circular curve on a level road without slipping,

A)no frictional force is needed because the car simply follows the road.
B)the frictional force of the road on the car increases when the car's speed decreases.
C)the frictional force of the road on the car increases when the car's speed increases.
D)the frictional force of the road on the car increases when the car moves to the outside of the curve.
E)there is no net frictional force because the road and the car exert equal and opposite forces on each other.
Question
An iceboat is traveling in a circle on the ice.Halfway around the circle the sail and the steering mechanism fall off the boat.Which statement is correct?

A)The boat will continue traveling in the circle because there is no friction.
B)The boat will continue to travel in the circle because its velocity exerts a force on it.
C)The boat will move off on a line tangent to the circle because there is no force on it.
D)The boat will move off tangent to the circle because there is a force on it perpendicular to the boat directed to the outside of the circle.
E)The boat will move off to the outside perpendicular to the tangent line since a force directed to the outside of the circle always acts on the boat.
Question
The equation below is the solution to a problem. <strong>The equation below is the solution to a problem.   ) The best physical representation of this equation is</strong> A)a sphere of 2.00 kg mass under a 6.00 N tension when at the bottom of a vertical circle. B)a sphere of 2.00 kg mass under a 6.00 N tension when at the side of a vertical circle. C)a sphere of 2.00 kg mass under a 6.00 N tension when at the top of a vertical circle. D)a sphere of 2.00 kg mass at any point on a horizontal circle. E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s. <div style=padding-top: 35px>
)
The best physical representation of this equation is

A)a sphere of 2.00 kg mass under a 6.00 N tension when at the bottom of a vertical circle.
B)a sphere of 2.00 kg mass under a 6.00 N tension when at the side of a vertical circle.
C)a sphere of 2.00 kg mass under a 6.00 N tension when at the top of a vertical circle.
D)a sphere of 2.00 kg mass at any point on a horizontal circle.
E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
Question
A small dense object is suspended from the rear view mirror in a car by a lightweight fiber.As the car is accelerating at 1.90 m/s2,what angle does the string make with the vertical?
Question
An airplane pilot experiences weightlessness as she passes over the top of a loop-the-loop maneuver.If her speed is 200 m/s at the time,find the radius of the loop.
Question
A skydiver of 75 kg mass has a terminal velocity of 60 m/s.At what speed is the resistive force on the skydiver half that when at terminal speed?

A)15 m/s
B)49 m/s
C)30 m/s
D)42 m/s
E)36 m/s
Question
A car enters a level,unbanked semi-circular hairpin turn of 300 m radius at a speed of 40 m/s.The coefficient of friction between the tires and the road is μ = 0.25.If the car maintains a constant speed of 40 m/s,it will

A)attempt to dig into the road surface.
B)tend to veer toward the center of the semicircle.
C)arrive safely at the end of the semicircle.
D)tend to veer toward the outside of the circle.
E)veer toward the center for the first quarter-circle,then veer toward the outside for the second quarter-circle.
Question
If a dense 20.0-kg object is falling in air at half its terminal velocity,what is the drag force on the object at this moment?

A)24.5 N
B)49.0 N
C)69.3 N
D)98.0 N
E)139 N
Question
An airplane flies in a horizontal circle of radius 500 m at a speed of 150 m/s.If the radius were changed to 1000 m,but the speed remained the same,by what factor would its centripetal acceleration change?

A)0.25
B)0.50
C)1.00
D)2.00
E)4.00
Question
An airplane flies in a horizontal circle of radius 500 m at a speed of 150 m/s.If the plane were to fly in the same 500 m circle at a speed of 300 m/s,by what factor would its centripetal acceleration change?

A)0.25
B)0.50
C)1.00
D)2.00
E)4.00
Question
If a 20-kg object dropped in air has a terminal speed of 60 m/s,what was its acceleration at 30 m/s?

A)9.80 m/s2
B)7.35 m/s2
C)4.90 m/s2
D)2.45 m/s2
E)More information is needed to answer this question.
Question
An airplane flies in a horizontal circle of radius 500 m at a speed of 150 m/s.If the plane were to fly in the same 1000 m circle at a speed of 300 m/s,by what factor would its centripetal acceleration change?

A)0.25
B)0.50
C)1.00
D)2.00
E)4.00
Question
A sample of blood is placed into a centrifuge of radius 15.0 cm.The mass of a red corpuscle is 3.0 × 10−16 kg,and the centripetal force required to make it settle out of the plasma is 4.0 × 10−11 N.At how many revolutions per second should the centrifuge be operated?
Question
A space station in the form of a large wheel,120 m in diameter,rotates to provide an "artificial gravity" of 3.00 m/s2 for persons located at the outer rim.Find the rotational frequency of the wheel (in revolutions per minute)that will produce this effect.
Question
What is the net force on a 10-kg solid steel sphere falling in air at terminal speed?

A)980 N
B)200 N
C)98 N
D)49 N
E)Some value other than those given above.
Question
A car enters a level,unbanked semi-circular hairpin turn of 100 m radius at a speed of 28 m/s.The coefficient of friction between the tires and the road is μ = 0.800.If the car maintains a constant speed of 28 m/s,it will

A)attempt to dig into the road surface.
B)tend to veer toward the center of the semicircle.
C)arrive safely at the end of the semicircle.
D)tend to veer toward the outside of the circle.
E)veer toward the center for the first quarter-circle,then veer toward the outside for the second quarter-circle.
Question
The following equation was obtained by solving a physics problem: <strong>The following equation was obtained by solving a physics problem:   The best physical representation of the situation is</strong> A)A car traveling at 16.0 m/s is 19.2° into a turn of a quarter circle on a level road. B)A mass on a string that is originally horizontal has fallen to where the angle between the string and the vertical direction is 19.2°. C)A mass on a string originally horizontal has fallen 19.2° from the horizontal direction. D)A car traveling at 16.0 m/s is on a circular curve banked at 19.2°. E)A car traveling at 16.0 m/s and going over a semicircular mountain-top road is 19.2° down from the top. <div style=padding-top: 35px>
The best physical representation of the situation is

A)A car traveling at 16.0 m/s is 19.2° into a turn of a quarter circle on a level road.
B)A mass on a string that is originally horizontal has fallen to where the angle between the string and the vertical direction is 19.2°.
C)A mass on a string originally horizontal has fallen 19.2° from the horizontal direction.
D)A car traveling at 16.0 m/s is on a circular curve banked at 19.2°.
E)A car traveling at 16.0 m/s and going over a semicircular mountain-top road is 19.2° down from the top.
Question
A race car starts from rest on a circular track of radius 400 m.Its speed increases at the constant rate of 0.500 m/s2.At the point where the magnitudes of the radial and tangential accelerations are equal,determine (a)the speed of the race car,and (b)the elapsed time.
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Deck 6: Circular Motion and Other Applications of Newtons Laws
1
A car travels along the perimeter of a vertical circle (radius = 0.25 km)at a constant speed of 30 m/s.What is the magnitude of the resultant force on the 60-kg driver of the car at the lowest point on this circular path?

A)0.37 kN
B)0.80 kN
C)0.22 kN
D)0.59 kN
E)0.45 kN
0.22 kN
2
A highway curve has a radius of 0.14 km and is unbanked.A car weighing 12 kN goes around the curve at a speed of 24 m/s without slipping.What is the magnitude of the horizontal force of the road on the car?

A)12 kN
B)17 kN
C)13 kN
D)5.0 kN
E)49 kN
5.0 kN
3
An object attached to the end of a string swings in a vertical circle (R = 1.2 m),as shown.At an instant when θ = 30°,the speed of the object is 5.1 m/s and the tension in the string has a magnitude of 20 N.What is the mass of the object? <strong>An object attached to the end of a string swings in a vertical circle (R = 1.2 m),as shown.At an instant when θ = 30°,the speed of the object is 5.1 m/s and the tension in the string has a magnitude of 20 N.What is the mass of the object?  </strong> A)2.0 kg B)1.5 kg C)1.8 kg D)1.2 kg E)0.80 kg

A)2.0 kg
B)1.5 kg
C)1.8 kg
D)1.2 kg
E)0.80 kg
1.2 kg
4
A 30-kg child rides on a circus Ferris wheel that takes her around a vertical circular path with a radius of 20 m every 22 s.What is the magnitude of the resultant force on the child at the highest point on this trajectory?

A)49 N
B)0.29 kN
C)0.34 kN
D)0.25 kN
E)0.76 kN
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5
A 0.30-kg mass attached to the end of a string swings in a vertical circle (R = 1.6 m),as shown.At an instant when θ = 50°,the tension in the string is 8.0 N.What is the magnitude of the resultant force on the mass at this instant? <strong>A 0.30-kg mass attached to the end of a string swings in a vertical circle (R = 1.6 m),as shown.At an instant when θ = 50°,the tension in the string is 8.0 N.What is the magnitude of the resultant force on the mass at this instant?  </strong> A)5.6 N B)6.0 N C)6.5 N D)5.1 N E)2.2 N

A)5.6 N
B)6.0 N
C)6.5 N
D)5.1 N
E)2.2 N
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6
A 0.50-kg mass attached to the end of a string swings in a vertical circle (radius = 2.0 m).When the string is horizontal,the speed of the mass is 8.0 m/s.What is the magnitude of the force of the string on the mass at this position?

A)16 N
B)17 N
C)21 N
D)11 N
E)25 N
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7
An airplane travels 80 m/s as it makes a horizontal circular turn which has a 0.80-km radius.What is the magnitude of the resultant force on the 75-kg pilot of this airplane?

A)0.69 kN
B)0.63 kN
C)0.66 kN
D)0.60 kN
E)0.57 kN
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8
A roller-coaster car has a mass of 500 kg when fully loaded with passengers.The car passes over a hill of radius 15 m,as shown.At the top of the hill,the car has a speed of 8.0 m/s.What is the force of the track on the car at the top of the hill? <strong>A roller-coaster car has a mass of 500 kg when fully loaded with passengers.The car passes over a hill of radius 15 m,as shown.At the top of the hill,the car has a speed of 8.0 m/s.What is the force of the track on the car at the top of the hill?  </strong> A)7.0 kN up B)7.0 kN down C)2.8 kN down D)2.8 kN up E)5.6 kN down

A)7.0 kN up
B)7.0 kN down
C)2.8 kN down
D)2.8 kN up
E)5.6 kN down
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9
A 0.20-kg object attached to the end of a string swings in a vertical circle (radius = 80 cm).At the top of the circle the speed of the object is 4.5 m/s.What is the magnitude of the tension in the string at this position?

A)7.0 N
B)2.0 N
C)3.1 N
D)5.1 N
E)6.6 N
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10
A 50-kg child riding a Ferris wheel (radius = 10 m)travels in a vertical circle.The wheel completes one revolution every 10 s.What is the magnitude of the force on the child by the seat at the highest point on the circular path?

A)0.29 kN
B)0.49 kN
C)0.69 kN
D)0.20 kN
E)0.40 kN
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11
An airplane moves 140 m/s as it travels around a vertical circular loop which has a 1.0-km radius.What is the magnitude of the resultant force on the 70-kg pilot of this plane at the bottom of this loop?

A)2.1 kN
B)1.4 kN
C)0.69 kN
D)1.5 kN
E)1.3 kN
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12
A 4.0-kg mass on the end of a string rotates in a circular motion on a horizontal frictionless table.The mass has a constant speed of 2.0 m/s and the radius of the circle is 0.80 m.What is the magnitude of the resultant force acting on the mass?

A)39 N
B)20 N
C)44 N
D)0 N
E)30 N
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13
A roller-coaster car has a mass of 500 kg when fully loaded with passengers.At the bottom of a circular dip of radius 40 m (as shown in the figure)the car has a speed of 16 m/s.What is the magnitude of the force of the track on the car at the bottom of the dip? <strong>A roller-coaster car has a mass of 500 kg when fully loaded with passengers.At the bottom of a circular dip of radius 40 m (as shown in the figure)the car has a speed of 16 m/s.What is the magnitude of the force of the track on the car at the bottom of the dip?  </strong> A)3.2 kN B)8.1 kN C)4.9 kN D)1.7 kN E)5.3 kN

A)3.2 kN
B)8.1 kN
C)4.9 kN
D)1.7 kN
E)5.3 kN
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14
A 0.40-kg mass attached to the end of a string swings in a vertical circle having a radius of 1.8 m.At an instant when the string makes an angle of 40 degrees below the horizontal,the speed of the mass is 5.0 m/s.What is the magnitude of the tension in the string at this instant?

A)9.5 N
B)3.0 N
C)8.1 N
D)5.6 N
E)4.7 N
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15
A 0.50 kg mass attached to the end of a string swings in a vertical circle (radius = 2.0 m).When the mass is at the highest point of the circle the speed of the mass is 8.0 m/s.What is the magnitude of the force of the string on the mass at this position?

A)21 N
B)11 N
C)16 N
D)26 N
E)36 N
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16
An amusement ride consists of a car moving in a vertical circle on the end of a rigid boom.The radius of the circle is 10 m.The combined weight of the car and riders is 5.0 kN.At the top of the circle the car has a speed of 5.0 m/s which is not changing at that instant.What is the force of the boom on the car at the top of the circle?

A)3.7 kN down
B)1.3 kN down
C)6.3 kN up
D)3.7 kN up
E)5.2 kN down
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17
A 0.50-kg mass attached to the end of a string swings in a vertical circle (radius = 2.0 m).When the mass is at the lowest point on the circle,the speed of the mass is 12 m/s.What is the magnitude of the force of the string on the mass at this position?

A)31 N
B)36 N
C)41 N
D)46 N
E)23 N
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18
A car travels around an unbanked highway curve (radius 0.15 km)at a constant speed of 25 m/s.What is the magnitude of the resultant force acting on the driver,who weighs 0.80 kN?

A)0.87 kN
B)0.34 kN
C)0.80 kN
D)0.00 kN
E)0.67 kN
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19
A stunt pilot weighing 0.70 kN performs a vertical circular dive of radius 0.80 km.At the bottom of the dive,the pilot has a speed of 0.20 km/s which at that instant is not changing.What force does the plane exert on the pilot?

A)3.6 kN up
B)4.3 kN up
C)2.9 kN down
D)2.9 kN up
E)5.8 kN down
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20
A race car travels 40 m/s around a banked (45° with the horizontal)circular (radius = 0.20 km)track.What is the magnitude of the resultant force on the 80-kg driver of this car?

A)0.68 kN
B)0.64 kN
C)0.72 kN
D)0.76 kN
E)0.52 kN
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21
A 4.0-kg mass attached to the end of a string swings in a vertical circle of radius 2.0 m.When the string makes an angle of 35° with the vertical as shown,the speed of the mass is 5.0 m/s.At this instant what is the magnitude of the force the string exerts on the mass? <strong>A 4.0-kg mass attached to the end of a string swings in a vertical circle of radius 2.0 m.When the string makes an angle of 35° with the vertical as shown,the speed of the mass is 5.0 m/s.At this instant what is the magnitude of the force the string exerts on the mass?  </strong> A)50 N B)82 N C)89 N D)11 N E)61 N

A)50 N
B)82 N
C)89 N
D)11 N
E)61 N
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22
A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?

A) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)
B) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)
C) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)
D) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)
E) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when the string is in one possible horizontal position?</strong> A)   B)   C)   D)   E)
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23
The equation below is the solution to a problem. <strong>The equation below is the solution to a problem.   ) The best physical representation of this equation is</strong> A)a sphere of 2.00 kg mass under a 45.2 N tension when at the bottom of a vertical circle. B)a sphere of 2.00 kg mass under a 45.2 N tension when at the side of a vertical circle. C)a sphere of 2.00 kg mass under a 45.2 N tension when at the top of a vertical circle. D)a sphere of 2.00 kg mass at any point on a horizontal circle. E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
)
The best physical representation of this equation is

A)a sphere of 2.00 kg mass under a 45.2 N tension when at the bottom of a vertical circle.
B)a sphere of 2.00 kg mass under a 45.2 N tension when at the side of a vertical circle.
C)a sphere of 2.00 kg mass under a 45.2 N tension when at the top of a vertical circle.
D)a sphere of 2.00 kg mass at any point on a horizontal circle.
E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
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24
A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?

A) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)
B) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)
C) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)
D) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)
E) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the lowest point?</strong> A)   B)   C)   D)   E)
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25
A hornet circles around a pop can at increasing speed while flying in a path with a 12-cm diameter.We can conclude that the hornet's wings must push on the air with force components that are

A)straight down.
B)down and inwards.
C)down and outwards.
D)down and backwards.
E)down,backwards and outwards.
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26
The equation below is the solution to a problem. <strong>The equation below is the solution to a problem.   ) The best physical representation of this equation is</strong> A)a sphere of 2.00 kg mass under a 25.6 N tension when at the bottom of a vertical circle. B)a sphere of 2.00 kg mass under a 25.6 N tension when at the side of a vertical circle. C)a sphere of 2.00 kg mass under a 25.6 N tension when at the top of a vertical circle. D)a sphere of 2.00 kg mass at any point on a horizontal circle. E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
)
The best physical representation of this equation is

A)a sphere of 2.00 kg mass under a 25.6 N tension when at the bottom of a vertical circle.
B)a sphere of 2.00 kg mass under a 25.6 N tension when at the side of a vertical circle.
C)a sphere of 2.00 kg mass under a 25.6 N tension when at the top of a vertical circle.
D)a sphere of 2.00 kg mass at any point on a horizontal circle.
E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
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27
A race car traveling at 100 m/s enters an unbanked turn of 400 m radius.The coefficient of (static)friction between the tires and the track is 1.1.The track has both an inner and an outer wall.Which statement is correct?

A)The race car will crash into the outer wall.
B)The race car will crash into the inner wall.
C)The car will stay in the center of the track.
D)The car will stay in the center of the track if the driver speeds up.
E)The car would stay in the center of the track if the radius were reduced to 200 m.
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28
A split highway has a number of lanes for traffic.For traffic going in one direction,the radius for the inside of the curve is half the radius for the outside.One car,car A,travels on the inside while another car of equal mass,car B,travels at equal speed on the outside of the curve.Which statement about resultant forces on the cars is correct?

A)The force on A is half the force on B.
B)The force on B is half the force on A.
C)The force on A is four times the force on B.
D)The force on B is four times the force on A.
E)There is no net resultant force on either as long as they stay on the road while turning.
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29
The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )The maximum safe speed on the track on the planet is ____ times as large as the maximum safe speed on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00
Compared to Earth's <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )The maximum safe speed on the track on the planet is ____ times as large as the maximum safe speed on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00
)The maximum safe speed on the track on the planet is ____ times as large as the maximum safe speed on Earth.

A)0.250
B)0.500
C)1.00
D)2.00
E)4.00
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30
The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )If the car is to be able to travel at the same speed on the planet as on Earth,the radius of the track on the planet must be ____ times as large as the radius of the track on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00
Compared to Earth's <strong>The coefficient of static friction for the tires of a race car is 0.950 and the coefficient of kinetic friction is 0.800.The car is on a level circular track of 50.0 m radius on a planet where   Compared to Earth's   )If the car is to be able to travel at the same speed on the planet as on Earth,the radius of the track on the planet must be ____ times as large as the radius of the track on Earth.</strong> A)0.250 B)0.500 C)1.00 D)2.00 E)4.00
)If the car is to be able to travel at the same speed on the planet as on Earth,the radius of the track on the planet must be ____ times as large as the radius of the track on Earth.

A)0.250
B)0.500
C)1.00
D)2.00
E)4.00
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31
A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?

A) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)
B) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)
C) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)
D) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)
E) <strong>A rock attached to a string swings in a vertical circle.Which free body diagram could correctly describe the force(s)on the rock when it is at the highest point?</strong> A)   B)   C)   D)   E)
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32
A boy on board a cruise ship drops a 30.0 gm marble into the ocean.If the resistive force proportionality constant is 0.500 kg/s,what is the terminal speed of the marble in m/s?

A)0.147
B)0.294
C)0.588
D)1.18
E)2.35
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33
For a plane to be able to fly clockwise in a horizontal circle as seen from above,in addition to exerting a force downwards on the air

A)it must be increasing its speed.
B)it must exert a force on the air that is directed to the plane's left side.
C)it must exert a force on the air that is directed to the plane's right side.
D)it does not need to exert a force: it must only move the wing flaps out.
E)it only needs to deflect the air without exerting any additional force on the air.
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34
Two small cylindrical plastic containers with flat bottoms are placed on a turntable that has a smooth flat surface.Canister A is empty;canister B contains lead shot.Each canister is the same distance r from the center.The coefficient of static friction between the canisters and the turntable is μs.When the speed of the turntable is gradually increased,

A)only the lighter container slides outward off the turntable;the heavier one stays on.
B)only the heavier container slides outward off the turntable;the lighter one stays on.
C)both containers slide off the turntable at the same turntable speed.
D)the lighter container slides inward.
E)the heavier container slides inward.
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35
A student is sitting on the right side of a school bus when it makes a right turn.We know that the force of gravity acts downwards and a normal force from the seat acts upwards.If the student stays in place when the bus turns,we also know that there must be

A)no other force on the student.
B)a force parallel to the seat directed forward on the student.
C)a force parallel to the seat directed to the left on the student.
D)a force parallel to the seat directed to the right on the student.
E)a force parallel to the seat in a direction between forward and left on the student.
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36
A hornet circles around a pop can at constant speed once per second in a path with a 12-cm diameter.We can conclude that the hornet's wings must push on the air with force components that are

A)straight down.
B)down and inwards.
C)down and outwards.
D)down and backwards.
E)down,inwards and backwards.
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37
Frank says that if you release the string when swinging a ball in a horizontal circle,the ball flies out in the radial direction defined by the string at the instant you release the ball.John says that it flies out along a tangent line perpendicular to the string,and that it then drops straight down to the ground.Which one,if either,is correct?

A)Frank,because the centrifugal force is no longer counteracted by the string.
B)Frank,because balls naturally fly straight out.
C)John,because there is no centrifugal force.
D)John,because balls fall straight down when released.
E)Neither,because although there is no centrifugal force,and the ball's velocity is tangent to the circle at the instant of release,the ball then follows a parabolic trajectory.
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38
When a car goes around a circular curve on a level road without slipping,

A)no frictional force is needed because the car simply follows the road.
B)the frictional force of the road on the car increases when the car's speed decreases.
C)the frictional force of the road on the car increases when the car's speed increases.
D)the frictional force of the road on the car increases when the car moves to the outside of the curve.
E)there is no net frictional force because the road and the car exert equal and opposite forces on each other.
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39
An iceboat is traveling in a circle on the ice.Halfway around the circle the sail and the steering mechanism fall off the boat.Which statement is correct?

A)The boat will continue traveling in the circle because there is no friction.
B)The boat will continue to travel in the circle because its velocity exerts a force on it.
C)The boat will move off on a line tangent to the circle because there is no force on it.
D)The boat will move off tangent to the circle because there is a force on it perpendicular to the boat directed to the outside of the circle.
E)The boat will move off to the outside perpendicular to the tangent line since a force directed to the outside of the circle always acts on the boat.
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40
The equation below is the solution to a problem. <strong>The equation below is the solution to a problem.   ) The best physical representation of this equation is</strong> A)a sphere of 2.00 kg mass under a 6.00 N tension when at the bottom of a vertical circle. B)a sphere of 2.00 kg mass under a 6.00 N tension when at the side of a vertical circle. C)a sphere of 2.00 kg mass under a 6.00 N tension when at the top of a vertical circle. D)a sphere of 2.00 kg mass at any point on a horizontal circle. E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
)
The best physical representation of this equation is

A)a sphere of 2.00 kg mass under a 6.00 N tension when at the bottom of a vertical circle.
B)a sphere of 2.00 kg mass under a 6.00 N tension when at the side of a vertical circle.
C)a sphere of 2.00 kg mass under a 6.00 N tension when at the top of a vertical circle.
D)a sphere of 2.00 kg mass at any point on a horizontal circle.
E)a 2.00 kg gecko running on the ceiling with a speed of 8.00 m/s.
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41
A small dense object is suspended from the rear view mirror in a car by a lightweight fiber.As the car is accelerating at 1.90 m/s2,what angle does the string make with the vertical?
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42
An airplane pilot experiences weightlessness as she passes over the top of a loop-the-loop maneuver.If her speed is 200 m/s at the time,find the radius of the loop.
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43
A skydiver of 75 kg mass has a terminal velocity of 60 m/s.At what speed is the resistive force on the skydiver half that when at terminal speed?

A)15 m/s
B)49 m/s
C)30 m/s
D)42 m/s
E)36 m/s
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44
A car enters a level,unbanked semi-circular hairpin turn of 300 m radius at a speed of 40 m/s.The coefficient of friction between the tires and the road is μ = 0.25.If the car maintains a constant speed of 40 m/s,it will

A)attempt to dig into the road surface.
B)tend to veer toward the center of the semicircle.
C)arrive safely at the end of the semicircle.
D)tend to veer toward the outside of the circle.
E)veer toward the center for the first quarter-circle,then veer toward the outside for the second quarter-circle.
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45
If a dense 20.0-kg object is falling in air at half its terminal velocity,what is the drag force on the object at this moment?

A)24.5 N
B)49.0 N
C)69.3 N
D)98.0 N
E)139 N
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46
An airplane flies in a horizontal circle of radius 500 m at a speed of 150 m/s.If the radius were changed to 1000 m,but the speed remained the same,by what factor would its centripetal acceleration change?

A)0.25
B)0.50
C)1.00
D)2.00
E)4.00
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47
An airplane flies in a horizontal circle of radius 500 m at a speed of 150 m/s.If the plane were to fly in the same 500 m circle at a speed of 300 m/s,by what factor would its centripetal acceleration change?

A)0.25
B)0.50
C)1.00
D)2.00
E)4.00
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48
If a 20-kg object dropped in air has a terminal speed of 60 m/s,what was its acceleration at 30 m/s?

A)9.80 m/s2
B)7.35 m/s2
C)4.90 m/s2
D)2.45 m/s2
E)More information is needed to answer this question.
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49
An airplane flies in a horizontal circle of radius 500 m at a speed of 150 m/s.If the plane were to fly in the same 1000 m circle at a speed of 300 m/s,by what factor would its centripetal acceleration change?

A)0.25
B)0.50
C)1.00
D)2.00
E)4.00
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50
A sample of blood is placed into a centrifuge of radius 15.0 cm.The mass of a red corpuscle is 3.0 × 10−16 kg,and the centripetal force required to make it settle out of the plasma is 4.0 × 10−11 N.At how many revolutions per second should the centrifuge be operated?
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51
A space station in the form of a large wheel,120 m in diameter,rotates to provide an "artificial gravity" of 3.00 m/s2 for persons located at the outer rim.Find the rotational frequency of the wheel (in revolutions per minute)that will produce this effect.
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52
What is the net force on a 10-kg solid steel sphere falling in air at terminal speed?

A)980 N
B)200 N
C)98 N
D)49 N
E)Some value other than those given above.
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53
A car enters a level,unbanked semi-circular hairpin turn of 100 m radius at a speed of 28 m/s.The coefficient of friction between the tires and the road is μ = 0.800.If the car maintains a constant speed of 28 m/s,it will

A)attempt to dig into the road surface.
B)tend to veer toward the center of the semicircle.
C)arrive safely at the end of the semicircle.
D)tend to veer toward the outside of the circle.
E)veer toward the center for the first quarter-circle,then veer toward the outside for the second quarter-circle.
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54
The following equation was obtained by solving a physics problem: <strong>The following equation was obtained by solving a physics problem:   The best physical representation of the situation is</strong> A)A car traveling at 16.0 m/s is 19.2° into a turn of a quarter circle on a level road. B)A mass on a string that is originally horizontal has fallen to where the angle between the string and the vertical direction is 19.2°. C)A mass on a string originally horizontal has fallen 19.2° from the horizontal direction. D)A car traveling at 16.0 m/s is on a circular curve banked at 19.2°. E)A car traveling at 16.0 m/s and going over a semicircular mountain-top road is 19.2° down from the top.
The best physical representation of the situation is

A)A car traveling at 16.0 m/s is 19.2° into a turn of a quarter circle on a level road.
B)A mass on a string that is originally horizontal has fallen to where the angle between the string and the vertical direction is 19.2°.
C)A mass on a string originally horizontal has fallen 19.2° from the horizontal direction.
D)A car traveling at 16.0 m/s is on a circular curve banked at 19.2°.
E)A car traveling at 16.0 m/s and going over a semicircular mountain-top road is 19.2° down from the top.
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55
A race car starts from rest on a circular track of radius 400 m.Its speed increases at the constant rate of 0.500 m/s2.At the point where the magnitudes of the radial and tangential accelerations are equal,determine (a)the speed of the race car,and (b)the elapsed time.
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