/*! This file is auto-generated */ .wp-block-button__link{color:#fff;background-color:#32373c;border-radius:9999px;box-shadow:none;text-decoration:none;padding:calc(.667em + 2px) calc(1.333em + 2px);font-size:1.125em}.wp-block-file__button{background:#32373c;color:#fff;text-decoration:none} Problem 59 A 1.35-kg object is attached to ... [FREE SOLUTION] | 91Ó°ÊÓ

91Ó°ÊÓ

Log out

Learning Materials

Features

Discover

Chapter 14: Problem 59

A 1.35-kg object is attached to a horizontal spring of force constant 2.5 N/cm. The object is started oscillating by pulling it 6.0 cm from its equilibrium position and releasing it so that it is free to oscillate on a frictionless horizontal air track. You observe that after eight cycles its maximum displacement from equilibrium is only 3.5 cm. (a) How much energy has this system lost to damping during these eight cycles? (b) Where did the "lost" energy go? Explain physically how the system could have lost energy.

Short Answer

Expert verified
The system lost 0.297 J of energy due to damping, likely dissipated as heat due to air resistance or internal friction.

Step by step solution

01

Convert Units

First, convert the spring constant from N/cm to N/m. Given \( k = 2.5 \) N/cm, to convert to N/m, multiply by 100: \( k = 2.5 \times 100 = 250 \) N/m.
02

Calculate Initial Potential Energy

Use the formula for the potential energy stored in a spring: \( E_{initial} = \frac{1}{2} k x_0^2 \). Here, \( x_0 = 6.0 \) cm = 0.06 m. Thus, \( E_{initial} = \frac{1}{2} \times 250 \times (0.06)^2 \). Solve this to find the initial energy.
03

Solve for Initial Energy

Compute the initial potential energy: \( E_{initial} = \frac{1}{2} \times 250 \times 0.0036 = 0.45 \) J.
04

Calculate Final Potential Energy

The final potential energy after 8 cycles is calculated using \( x = 3.5 \) cm = 0.035 m, \( E_{final} = \frac{1}{2} k x^2 \). This becomes \( E_{final} = \frac{1}{2} \times 250 \times (0.035)^2 \). Solve this to find the final energy.
05

Solve for Final Energy

Compute the final potential energy: \( E_{final} = \frac{1}{2} \times 250 \times 0.001225 = 0.153125 \) J.
06

Determine Energy Loss

Subtract the final energy from the initial energy to find the energy lost: \( E_{lost} = E_{initial} - E_{final} = 0.45 - 0.153125 \). Solve this to find the lost energy.
07

Solve for Energy Loss

Calculate the energy lost: \( E_{lost} = 0.45 - 0.153125 = 0.296875 \) J. Round this to three significant figures for a final answer: \( E_{lost} = 0.297 \) J.
08

Explain Energy Loss

The energy was lost due to damping forces. Even though the track is frictionless, oscillations can be damped by air resistance or internal friction within the spring and object. The energy was dissipated as heat.

Unlock Step-by-Step Solutions & Ace Your Exams!

  • Full Textbook Solutions

    Get detailed explanations and key concepts

  • Unlimited Al creation

    Al flashcards, explanations, exams and more...

  • Ads-free access

    To over 500 millions flashcards

  • Money-back guarantee

    We refund you if you fail your exam.

Over 30 million students worldwide already upgrade their learning with 91Ó°ÊÓ!

Key Concepts

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

Energy Conservation
Energy conservation is a fundamental concept in physics, stating that energy cannot be created or destroyed, only transformed from one form to another. In the context of damped oscillations, even though we begin with a certain amount of total mechanical energy, some of it may transform into other forms due to damping effects.

In an idealized, frictionless system, like the oscillating spring problem described, one might initially expect no loss of energy. However, in real-world scenarios, energy is almost always exchanged, often with the environment,
leading to a reduction in the mechanical energy of the system.

In our exercise, despite the frictionless track, the energy loss occurs, likely through air resistance or internal friction. These are considered non-conservative forces as they do not store energy but convert it to thermal energy, perceived as a loss.
Potential Energy
Potential energy in a spring-coupled system is stored energy resulting from an object's position relative to equilibrium. This is critical in understanding oscillations, as it determines how 'stretched' or 'compressed' the spring is.

To calculate the potential energy stored in the spring, we use the formula:
  • \( E = \frac{1}{2} k x^2 \)...
where \( k \) is the spring constant (in N/m), and \( x \) is the displacement from the equilibrium position (in meters).

In the given exercise, the potential energy reduces over time due to damping. Initially, when the spring is at maximum stretch at 6.0 cm, it has the highest potential energy. After several cycles, with a reduced stretch of 3.5 cm, the potential energy also decreases accordingly. This change in energy helps us understand how much energy the system has dissipated.
Spring Constant
The spring constant \( k \) is a measure of a spring's stiffness. Essentially, it tells us how much force is needed to displace the spring by a certain distance. This parameter is vital as it directly affects the potential energy of the system.

In the exercise, the spring constant is given as 2.5 N/cm, which can be converted to 250 N/m for standard unit calculation. Knowing the spring constant allows us to properly apply the potential energy formula and assess how energy changes as the system oscillates.

The role of the spring constant is significant in determining how a spring will behave under force:
  • Higher spring constant: Stiffer spring, harder to stretch, more potential energy when displaced.
  • Lower spring constant: Less stiff spring, easier to stretch, less potential energy when displaced.
The constant is crucial for calculating accurate energy values, particularly in exercises where damping plays a role, as it helps quantify how energy is initially stored and subsequently dissipated.

One App. One Place for Learning.

All the tools & learning materials you need for study success - in one app.

Get started for free

Most popular questions from this chapter

A 5.00-kg partridge is suspended from a pear tree by an ideal spring of negligible mass. When the partridge is pulled down 0.100 m below its equilibrium position and released, it vibrates with a period of 4.20 s. (a) What is its speed as it passes through the equilibrium position? (b) What is its acceleration when it is 0.050 m above the equilibrium position? (c) When it is moving upward, how much time is required for it to move from a point 0.050 m below its equilibrium position to a point 0.050 m above it? (d) The motion of the partridge is stopped, and then it is removed from the spring. How much does the spring shorten?

In February 2004, scientists at Purdue University used a highly sensitive technique to measure the mass of a vaccinia virus (the kind used in smallpox vaccine). The procedure involved measuring the frequency of oscillation of a tiny sliver of silicon (just 30 nm long) with a laser, first without the virus and then after the virus had attached itself to the silicon. The difference in mass caused a change in the frequency. We can model such a process as a mass on a spring. (a) Show that the ratio of the frequency with the virus attached \((f_S+\,_V)\) to the frequency without the virus \((f_S)\) is given by \(f_S+\,_V/f_S = 1\sqrt{ 1 + (m_V/m_S) }\), where \(m_V\) is the mass of the virus and \(m_S\) is the mass of the silicon sliver. Notice that it is \(not\) necessary to know or measure the force constant of the spring. (b) In some data, the silicon sliver has a mass of 2.10 \(\times\) 10\(^{-16}\) g and a frequency of 2.00 \(\times\) 10\(^{15}\) Hz without the virus and 2.87 \(\times\) 10\(^{14}\) Hz with the virus. What is the mass of the virus, in grams and in femtograms?

An object is undergoing SHM with period 0.300 s and amplitude 6.00 cm. At \(t =\) 0 the object is instantaneously at rest at \(x =\) 6.00 cm. Calculate the time it takes the object to go from \(x =\) 6.00 cm to \(x = -\)1.50 cm.

You pull a simple pendulum 0.240 m long to the side through an angle of 3.50\(^\circ\) and release it. (a) How much time does it take the pendulum bob to reach its highest speed? (b) How much time does it take if the pendulum is released at an angle of 1.75\(^\circ\) instead of 3.50\(^\circ\)?

A uniform, solid metal disk of mass 6.50 kg and diameter 24.0 cm hangs in a horizontal plane, supported at its center by a vertical metal wire. You find that it requires a horizontal force of 4.23 N tangent to the rim of the disk to turn it by 3.34\(^\circ\), thus twisting the wire. You now remove this force and release the disk from rest. (a) What is the torsion constant for the metal wire? (b) What are the frequency and period of the torsional oscillations of the disk? (c) Write the equation of motion for \(\theta(t)\) for the disk.
See all solutions

Recommended explanations on Physics Textbooks

Nuclear Physics

Read Explanation

Work Energy and Power

Read Explanation

Electricity and Magnetism

Read Explanation

Further Mechanics and Thermal Physics

Read Explanation

Magnetism

Read Explanation

Modern Physics

Read Explanation
View all explanations

What do you think about this solution?

We value your feedback to improve our textbook solutions.

Study anywhere. Anytime. Across all devices.