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Chapter 11: Problem 36

A mass of \(0.20 \mathrm{~kg}\) on the end of a spring oscillates with a period of \(0.45 \mathrm{~s}\) and an amplitude of \(0.15 \mathrm{~m} .\) Find (a) the velocity when it passes the equilibrium point, (b) the total energy of the system, (c) the spring constant, and (d) the maximum acceleration of the mass.

Short Answer

Expert verified
(a) 2.09 m/s, (b) 0.44 J, (c) 39.0 N/m, (d) 29.2 m/s².

Step by step solution

01

Calculate Angular Frequency

The angular frequency \( \omega \) of the spring-mass system is given by the formula \( \omega = \frac{2\pi}{T} \), where \( T \) is the period of oscillation. Substituting the given period, \( T = 0.45 \) s, we have: \[ \omega = \frac{2\pi}{0.45} \approx 13.96 \, \text{rad/s}. \]
02

Velocity at Equilibrium Point

At the equilibrium point, the velocity of a mass in simple harmonic motion is maximum, calculated by the formula \( v_{max} = \omega A \), where \( A \) is the amplitude. Substituting the given amplitude and angular frequency: \[ v_{max} = 13.96 \times 0.15 \approx 2.09 \, \text{m/s}. \]
03

Calculate Total Energy

The total mechanical energy \( E \) in a spring-mass system is given by \( E = \frac{1}{2} m \omega^2 A^2 \). Substituting the known values (\( m = 0.20 \, \text{kg} \), \( \omega \approx 13.96 \, \text{rad/s} \), and \( A = 0.15 \, \text{m} \)): \[ E = \frac{1}{2} \times 0.20 \times (13.96)^2 \times (0.15)^2 \approx 0.44 \, \text{J}. \]
04

Calculate Spring Constant

The spring constant \( k \) is related to the angular frequency and mass by \( \omega = \sqrt{\frac{k}{m}} \). Rearranging this gives \( k = m \omega^2 \). Substituting for \( m \) and \( \omega \), we find: \[ k = 0.20 \times (13.96)^2 \approx 39.0 \, \text{N/m}. \]
05

Maximum Acceleration

The maximum acceleration \( a_{max} \) occurs at maximum displacement and is given by \( a_{max} = \omega^2 A \). Using the established angular frequency and amplitude, we find: \[ a_{max} = (13.96)^2 \times 0.15 \approx 29.2 \, \text{m/s}^2. \]

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Understanding Angular Frequency
In simple harmonic motion, angular frequency, denoted by \( \omega \, \), plays a crucial role. It describes how quickly an object oscillates back and forth. The formula to calculate angular frequency is \[ \omega = \frac{2\pi}{T} \]where
  • \( \omega \): Angular frequency (in radians per second)
  • \( T \): Period of oscillation (time taken for one complete cycle)
In our example, the period \( T \) is given as 0.45 seconds. Calculating, we find that \( \omega \approx 13.96 \, \) rad/s. This tells us that every second, the mass completes about 14 radians of its path. Angular frequency is crucial for determining maximum velocity and acceleration in oscillatory systems. It's what connects the motion of the mass to the characteristics of the spring.
Spring Constant: The Measure of Stiffness
The spring constant, denoted by \( k \, \), is a measure of the stiffness of a spring. It tells us how much force is needed to stretch or compress the spring by a unit length. It's a fundamental property in Hooke's Law. To find the spring constant, we use the relationship: \[ k = m \omega^2 \]where:
  • \( k \): Spring constant (N/m)
  • \( m \): Mass attached to the spring (kg)
  • \( \omega \): Angular frequency (rad/s)
Substituting the values \( m = 0.20 \, \) kg and \( \omega = 13.96 \, \) rad/s, we get \( k \approx 39.0 \, \) N/m. This indicates a relatively stiff spring, as a fairly substantial force is needed to change its length.
Total Mechanical Energy in Oscillatory Motion
Mechanical energy in a system is always conserved, assuming no external forces like friction act on it. For a simple harmonic oscillator, the mechanical energy consists of potential energy (when the spring is stretched or compressed) and kinetic energy (when the mass is moving). The formula for total mechanical energy \( E \, \) is: \[ E = \frac{1}{2} m \omega^2 A^2 \]where:
  • \( E \): Total energy (Joules)
  • \( A \): Amplitude of motion (m)
In our calculation, using \( m = 0.20 \, \) kg, \( \omega = 13.96 \, \) rad/s, and \( A = 0.15 \, \) m, we found \( E \approx 0.44 \, \) J. This is the energy the mass exchanges between potential and kinetic forms as it oscillates, ping ponging back and forth due to the restoring force of the spring.
Maximum Acceleration in Simple Harmonic Motion
Maximum acceleration in simple harmonic motion occurs at the points of maximum displacement. It's directly tied to the angular frequency and amplitude of the oscillation. The formula to calculate maximum acceleration \( a_{max} \, \) is: \[ a_{max} = \omega^2 A \]where:
  • \( a_{max} \): Maximum acceleration (m/s²)
  • \( \omega \): Angular frequency (rad/s)
  • \( A \): Amplitude of oscillation (m)
Substituting in \( \omega = 13.96 \, \) rad/s and \( A = 0.15 \, \) m, the maximum acceleration comes out to \( a_{max} \approx 29.2 \, \) m/s². This peak acceleration tells us how strong the forces acting on the mass are at the extreme points of its path, giving an idea of the dynamic nature of the motion.

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Most popular questions from this chapter

Crude oil with a bulk modulus of \(2.35 \mathrm{GPa}\) is leaking from a deep- sea well \(2250 \mathrm{~m}\) below the surface of the ocean, where the water pressure is \(2.27 \times 10^{7} \mathrm{~Pa}\). Suppose 35,600 barrels of oil leak from the wellhead; assuming all that oil reaches the surface, how many barrels will it be on the surface?

Effect of diving on blood. It is reasonable to assume that the bulk modulus of blood is about the same as that of water ( \(2.2 \mathrm{GPa}\) ). As one goes deeper and deeper in the ocean, the pressure increases by \(1.0 \times 10^{4} \mathrm{~Pa}\) for every meter below the surface. (a) If a diver goes down \(33 \mathrm{~m}\) (a bit over \(100 \mathrm{ft}\) ) in the ocean, by how much does each cubic centimeter of her blood change in volume? (b) How deep must a diver go so that each drop of blood compresses to half its volume at the surface? Is the ocean deep enough to have this effect on the diver?

The effect of jogging on the knees. High-impact activities such as jogging can cause considerable damage to the cartilage at the knee joints. Peak loads on each knee can be eight times body weight during jogging. The bones at the knee are separated by cartilage called the medial and lateral meniscus. Although it varies considerably, the force at impact acts over approximately \(10 \mathrm{~cm}^{2}\) of this cartilage. Human cartilage has a Young's modulus of about 24 MPa (although that also varies). (a) By what percent does the peak load impact of jogging compress the knee cartilage of a \(75 \mathrm{~kg}\) person? (b) What would be the percentage for a lower-impact activity, such as power walking, for which the peak load is about four times body weight?

(a) If a pendulum has period \(T\) and you double its length, what is its new period in terms of \(T ?\) (b) If a pendulum has a length \(L\) and you want to triple its frequency, what should be its length in terms of \(L ?\) (c) Suppose a pendulum has a length \(L\) and period \(T\) on earth. If you take it to a planet where the acceleration of freely falling objects is 10 times what it is on earth, what should you do to the length to keep the period the same as on earth? (d) If you do not change the pendulum's length in part (c), what is its period on that planet in terms of \(T ?\) (e) If a pendulum has a period \(T\) and you triple the mass of its bob, what happens to the period (in terms of \(T\) )?

A pendulum on Mars. A certain simple pendulum has a period on earth of \(1.60 \mathrm{~s}\). What is its period on the surface of Mars, where the acceleration due to gravity is \(3.71 \mathrm{~m} / \mathrm{s}^{2} ?\)
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