physics 101 please solve question 16 Q11: Block A, with a mass 5 kg, rests on the incline. Thecoefficient of static friction between the incline and block A is0.4. The largest mass of the block B (in kg) for which Aremains at rest is:a) 4.5b) 3.5c) 5.9d) 9.0012 The horizontal surface on which a 2 kg block slides isfrictionless. The speed of the block before it touches the spring is7 m/s. How fast is the block moving at the instant the spring hasbeen compressed 0.1 m ? k = 1000 N/m.(a) 3.3 m/s (b) 4.5 m/s (c) 5.6 m/s(d) 6.6 m/sQ13: A 6 kg mass is projected down a rough (shown.)circular track (R = 2 m) asThe speed of the mass at point A is 4 m/s, and at point B, it is 6 m/s.How much work is done on the mass between A and B by the force offriction?a)-20b)-40c) -30d) -60e) -9Q14: A constant force of (51) N acts on a 4.0-kg object as it moves from the origin to the point(61-81) m. How much work is done by the given force during this displacement?a) 30 Jb) 84 Jc) 72 Jd) 48 JQ15: A 6.0-kg cart is moving horizontally at 6.0m/s. In order to change its speed to 10.0m/s, the network done on the cart must be:a) 160 Jb) 90 Jc) 40 Jd) 192JQ16: The potential energy of a 0.10-kg particle moving along the x axis is given byU(x)=(8x²-2x). When the particle is at x = 1m its acceleration is:b)-80m/s² c) -40m/s²a) 40m/s²d) 80m/s²Q17: A 1500 kg car moving on a flat, horizontal road negotiates a curve of 45 m radius. If themaximum speed the car can have to turn the curve successfully is 15m/s. Find the coefficient ofstatic friction (us) between the tires and road.a) 0.50b) 0.57c) 0.66d) 0.4235⁰wB2.0 kg

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Description: physics 101 please solve question 16 Q11: Block A, with a mass 5 kg, rests on the incline. Thecoefficient of static friction between the incline and block A is0.4. The largest mass of the block B (in kg) for which Aremains at rest is:a) 4.5b) 3.5c) 5

We have a particle of mass m=0.10 kg which is moving along the x axis with a potential energy…

Answered: Q16: The potential energy of a 0.10-kg…

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Q16: The potential energy of a 0.10-kg particle moving along the x axis is given by U(x)=(8x²-2x). When the particle is at x = 1m its acceleration is: a) 40m/s² b)-80m/s² c)-40m/s² d) 80m/s²

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter6: Applications Of Newton’s Laws Of Motion

Section: Chapter Questions

Problem 64PQ: A box rests on a surface (Fig. P6.64). A force Fapp is applied to the box in two different ways. In...

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Review. A block of mass m = 2.00 kg is released from rest at h = 0.500 m above the surface of a table, at the top of a = 30.0 incline as shown in Figure P5.101. The frictionless incline is fixed on a table of height H = 2.00 m. (a) Determine the acceleration of the block as it slides down the incline, (b) What is the velocity of the block as it leaves the incline? (c) How far from the table will the block hit the floor? (d) What time interval elapses between when the block is released and when it hits the floor? (e) Does the mass of the block affect any of the above calculations?
Two boxes of fruit on a frictionless horizontal surface are connected by a light string as in Figure P4.85, where m1 = 10.0 kg and m2 = 20.0 kg. A force of 50.0 N is applied to the 20.0-kg box. (a) Determine the acceleration of each box and the tension in the string. (b) Repeat the problem for the case where the coefficient of kinetic friction between each box and the surface is 0.10. Figure P4.85
A skier starts at rest at the top of a large hemispherical hill (Fig. P7.63). Neglecting friction, show that the skier will leave the hill and become airborne at a distance h = R/3 below the top of the hill. Hint: At this point, the normal force goes to zero. Figure P7.63
A 1.00-kg glider on a horizontal air track is pulled by a string at an angle . The taut string runs over a pulley and is attached to a hanging object of mass 0.500 kg as shown in Figure P5.40. (a) Show that the speed vx of the glider and the speed vy of the hanging object are related by vx = uvy, where u = z(z2 h02)1/2. (b) The glider is released from rest. Show that at that instant the acceleration ax of the glider and the acceleration ay of the hanging object are related by ax = uay. (c) Find the tension in the string at the instant the glider is released for h0 = 80.0 cm and = 30.0. Figure P5.40
A box rests on a surface (Fig. P6.64). A force Fapp is applied to the box in two different ways. In both cases. Fapp has the same magnitude, but in case 1 the force is directed below the horizontal, whereas in case 2 it is directed above the horizontal. a. Draw a free-body diagram for both cases. b. Now Fapp is increased in both cases until the box just barely remains at rest. Compare Fs, max for each free-body diagram. c. Use your answer to part (b) to find a best way to move a heavy desk. Describe and explain your solution.
A boy coasts down a hill on a sled, reaching a level surface at the bottom with a speed of 7.00 m/s. If the coefficient of friction between the sleds runners and the snow is 0.050 0 and the boy and sled together weigh 600. N, how far does the sled travel on the level surface before coming to rest?
As shown in Figure CQ5.22, student A, a 55-kg girl, sits on one chair with metal runners, at rest on a classroom floor. Student B, an 80-kg boy, sits on an identical chair. Both students keep their feet off the floor. A rope runs from student As hands around a light pulley and then over her shoulder to the hands of a teacher standing on the floor behind her. The low-friction axle of the pulley is attached to a second rope held by student B. All ropes run parallel to the chair runners. (a) If student A pulls on her end of the rope, will her chair or will Bs chair slide on the floor? Explain why. (b) If instead the teacher pulls on his rope end, which chair slides? Why this one? (c) If student B pulls on his rope, which chair slides? Why? (d) Now the teacher ties his end of the rope to student As chair. Student A pulls on the end of the rope in her hands. Which chair slides and why? Figure CQ5.22
An automobile driver traveling down an 8% grade slams on his brakes and skids 30 m before hitting a parked car. A lawyer hires an expert who measures the coefficient of kinetic friction between the tires and road to be k = 0.45. Is the lawyer correct to accuse the driver of exceeding the 25-MPH speed limit? Explain.
A 0.450-kg hammer is moving horizontally at 7.00 m/s when it strikes a nail and comes to rest after driving the nail 1.00 cm into a board. Assume constant acceleration of the hammer-nail pair. a. Calculate the duration of the impact. b. What was the average force exerted on the nail?
A box with mass m1 = 6.00 kg sliding on a rough table with a coefficient of kinetic friction of 0.220 is connected by a mass-less cord strung over a mass-less, frictionless pulley to a second box of mass m2 = 12.0 kg hanging from the side of the table (Fig. P5.51). What is the tension in the cord connecting the boxes?
In Example 5.7, we pushed on two blocks on a table. Suppose three blocks are in contact with one another on a frictionless, horizontal surface as shown in Figure P5.43. A horizontal force F is applied to m1. Take m1 = 2.00 kg, m2 = 3.00 kg, m3 = 4.00 kg, and F = 18.0 N. (a) Draw a separate free-body diagram for each block. (b) Determine the acceleration of the blocks. (c) Find the resultant force on each block. (d) Find the magnitudes of the contact forces between the blocks. (e) You are working on a construction project. A coworker is nailing up plasterboard on one side of a light partition, and you are on the opposite side, providing backing by leaning against the wall with your back pushing on it. Every hammer blow makes your back sting. The supervisor helps you put a heavy block of wood between the wall and your back. Using the situation analyzed in parts (a) through (d) as a model, explain how this change works to make your job more comfortable.
The front 1.20 m of a 1 400-kg car is designed as a crumple zone that collapses to absorb the shock of a collision. If a car traveling 25.0 m/s stops uniformly in 1.20 m, (a) how long does the collision last, (b) what is the magnitude of the average force on the car, and (c) what is the acceleration of the car? Express the acceleration as a multiple of the acceleration of gravity.