7.6.2 Reason PIVOTAL CIass |= 1.2 m A pendulum consisting of a light string and an object (mass 2 kg) is released from a horizontal position and swings down (see the figure at right). Find the speed of the object when the pendulum reaches the bottom of its swing (as shown by the dashed lines in the figure) using your knowledge of energy. Could you figure this out using kinematics? Why, or why not?

7.6.2 Reason PIVOTAL CIass |= 1.2 m A pendulum consisting of a light string and an object (mass 2 kg) is released from a horizontal position and swings down (see the figure at right). Find the speed of the object when the pendulum reaches the bottom of its swing (as shown by the dashed lines in the figure) using your knowledge of energy. Could you figure this out using kinematics? Why, or why not?

Related questions

Q: 2. A 60 kg skier slides down a hill, and their potential energy versus horizontal position (x) is…

Q: If m = 3.5 kg, F = 18 N, θ = 25 degrees, d = 2.25 m, and the surface is frictionless, A. What is…

A: (a) The expression for work done by applied force is given by Wappliedforce=F·d=Fdcosθ=18 N2.25…

Q: 3 KIPP:SCIENCE HNOLOGY, ENGINEERING 5 min | Exit Ticket 34 35 36 37 A bicycle rider is traveling up…

A: The objective of the question is to understand the relationship between potential energy and kinetic…

Q: Can you please solve this without using calculus? There has to be a way to use the formulas for…

A: a) In order for two protons to come close enough for fusion to occur, their electrostatic repulsion…

Q: the situation where a ball is fal l n rest and then falls to a height of 15 mete gy of 120J. When…

A: Given:- The height of the ball is h = 15 m The total energy of the ball at the height h is E =…

Q: 1. A 6.2kg box is moving at 2.4m/s to the left. a) What is its kinetic energy? 2.4m/s 6.2kg b) How…

A: Given data: Mass (m) = 6.2 kg Initial velocity (u) = 2.4 m/s Work done by the friction (W) = -4 J…

Q: A 70-kg student climb stair as shown, Δy = 12 m and it is completed in 6.0s. Use g = 10 m/s2. A.)…

A: mass of student 70 kg Δy = 12 m g = 10 m/s2. t=6 s

Q: Mass of skater (m) height (h) velocity (v). Kinetic Energy (KE) Potential Energy (PE) 20. kg 14 m 12…

A: Given data: Height (h) = 6.0 m Velocity (v) = 5.0 m/s Potential Energy (PE) = 600 J Required: Mass…

Q: 2. There is a bell at the top of a tower that is 45m high. The bell has a mass of 20kg. The bell has…

A: There is a bell at the top of a tower that is 45 m high. The bell has a mass of 20 kg. The bell has…

Q: assume the object has a mass of 0.55kg. calculate the gravitational potential energy and kinetic…

A: Given: The mass of the object is 0.55 kg. The height of the object is 4.99 m. The speed of the…

Q: 2. A student observes an apple falling from a tree and makes the following statement: "The Earth…

A: Hello. Since you have posted multiple questions and not specified which question needs to be solved,…

Q: 300 The mass of a pendulum bob is 0-2 kg, and it is suspended by a string 1 m long. It is pulled…

Q: 1.) A 15 kg mass is dropped from rest a distance of 18 m above the ground. Make certain you show all…

Q: 1. A car travels at a speed of 60.0 km/h and has a mass of 1 005 kg. What is its kinetic energy? 60…

A: Speed of the car is V = 16.67 m/s Mass of the car is M = 1005 kg

Q: a. Determine the work a hiker must do on a 15 kg backpack to carry it up a hill of height h = 14 m;…

A: Mass of the backpack m=15 kg, height of the hill h=14 m and acceleration due to gravity. Let us take…

Question

7.6.2 Reason
PIVOTAL Cass
1=1,2 m
A pendulum consisting of a light string and an object
(mass 2 kg) is released from a horizontal position and
swings down (see the figure at right). Find the speed
of the object when the pendulum reaches the bottom of
its swing (as shown by the dashed lines in the figure)
23
using your knowledge of energy.
Could you figure this out using kinematics? Why or why not?

Expert Solution

Step 1

At the horizontal position (initially) the pendulum has potential energy is zero. Since here the object is at rest, therefore, the kinetic energy will be zero.

When the pendulum reaches the bottom its potential energy becomes zero, and it has maximum kinetic energy.

Therefore, using conservation of energy

$\begin{array}{rcl} E_{f i n a l} & = & E_{f i n a l} \\ m g h & = & \frac{1}{2} m v^{2} \\ v & = & \sqrt{2 g h} \\ v & = & \sqrt{2 g l} \end{array}$