EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 8220100581557
Author: Jewett
Publisher: Cengage Learning US
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Chapter 16, Problem 16.15P

A transverse wave on a siring is described by the wave function

y = 0.120 sin ( π 8 x + 4 π t )

where x and y are in meters and t is in seconds. Determine (a) the transverse speed and (b) the transverse acceleration at t = 0.200 s for an element of the string located at x = 1.60 m. What are (c) the wavelength, (d) the period, and (e) the speed of propagation of this wave?

(a)

Expert Solution
Check Mark
To determine

The transverse speed for an element located at 1.60m .

Answer to Problem 16.15P

The transverse speed for an element located at 1.60m is 1.51m/s .

Explanation of Solution

Given info: The wave function of the wave is y=0.120sin(π8x+4πt) .

The standard equation of the transverse wave is,

y=Asin(kxωt) . (1)

Here,

A is amplitude of wave.

k is angular wave number of wave.

ω is angular velocity of wave.

The wave function give is,

y=0.120sin(π8x+4πt) . (2)

Compare the equation (1) and equation (2).

A=0.120mk=π8ω=4πrad/s

The formula to calculate frequency is,

f=ω2π

Substitute 4πrad/s for ω in the above expression.

f=4πrad/s2π=2.00Hz

The change in position with respect to time gives the transverse speed of the wave.

v=dydt

Here,

dy is change in position.

dt is change in time.

Substitute 0.120sin(π8x+4πt) for y in the above expression.

v=d(0.120sin(π8x+4πt))dt

Differentiate and solve the above expression for v ,

=(0.120)dsin(π8x+4πt)+sin(π8x+4πt)d(0.120)dtdt=(0.120)cos(π8x+4πt)(4π)+0 (1)

Substitute 0.200s for t and 1.6m for x in the above expression.

=(0.120)cos(π8(1.6m)+4π(0.200s))(4π)+0=(0.120)(4π)cos(0.2π+0.8π)=1.5072m/s1.51m/s

Conclusion:

Therefore, the transverse speed for an element located at 1.60m is 1.51m/s .

(b)

Expert Solution
Check Mark
To determine

To write: The transverse acceleration of the wave.

Answer to Problem 16.15P

The transverse acceleration of the wave is 0 .

Explanation of Solution

Given info: The wave function of the wave is y=0.120sin(π8x+4πt) . The time of the wave is 0.200s and the position of element is 1.60m .

The change in velocity with respect to time gives the acceleration.

a=dvdt (2)

Here,

dv is change in velocity.

dt is change in time.

From equation (1), the speed is,

v=(0.120)cos(π8x+4πt)(4π)+0

Substitute (0.120)cos(π8x+4πt)(4π)+0 for v in equation (2).

a=d(0.120)cos(π8x+4πt)(4π)+0dt

Differentiate and solve the above expression for a .

a=d(0.120)cos(π8x+4πt)(4π)+0dt=(0.120)×(sin((π8x+4πt))×(4π)2)+0

Substitute 0.200s for t and 1.60m for x in the above expression.

(0.120)×(sin((π8(1.60m)+4π(0.200s)))×(4π)2)+0

Solve the above expression.

=(0.120)×(sin((π8(1.60m)+4π(0.200s)))×(4π)2)+0=(0.120)(4π)2(sin(π))=0

Conclusion:

Therefore, the transverse acceleration of the wave is 0 .

(c)

Expert Solution
Check Mark
To determine

The wavelength of the wave.

Answer to Problem 16.15P

The wavelength of the wave is 16.0m .

Explanation of Solution

Given info: The wave function of the wave is y=0.120sin(π8x+4πt) .

The formula to calculate wavelength of the wave is,

λ=2πk

Here,

k is angular wave number of wave.

Substitute π8 for k in the above expression.

λ=2π(π8)

Solve the above expression for λ .

λ=2π(π8)=2×8m=16.0m

Conclusion:

Therefore, the wavelength of the wave is 16.0m .

(d)

Expert Solution
Check Mark
To determine

The period of the wave.

Answer to Problem 16.15P

The period of the wave is 0.500s .

Explanation of Solution

Given info: The wave function of the wave is y=0.120sin(π8x+4πt) .

The formula to calculate frequency is,

f=ω2π

Here,

ω is angular frequency of wave.

Substitute 4πrad/s for ω in the above expression.

f=4πrad/s2π=2Hz

The formula to calculate time period of the wave is,

t=1f

Here,

f is frequency of wave.

Substitute 2Hz for f in the above expression.

t=12Hz=0.500s

Conclusion:

Therefore, the period of the wave is 0.500s .

(E)

Expert Solution
Check Mark
To determine

The speed of propagation of wave.

Answer to Problem 16.15P

The speed of propagation of wave is 32.0m/s .

Explanation of Solution

Given info: The wave function of the wave is y=0.120sin(π8x+4πt) .

The formula to calculate speed of propagation of wave is,

s=fλ

Here,

s is speed of propagation of wave.

f is frequency of wave.

Substitute 2s1 for f and 16.0m for λ in the above expression.

s=(2s1)(16.0m)=32.0m/s

Conclusion:

Therefore, the speed of propagation of wave is 32.0m/s .

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Chapter 16 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

Ch. 16 - Which of the following statements is not...Ch. 16 - Prob. 16.7OQCh. 16 - Prob. 16.8OQCh. 16 - The distance between two successive peaks of a...Ch. 16 - Prob. 16.1CQCh. 16 - (a) How would you create a longitudinal wave in a...Ch. 16 - When a pulse travels on a taut string, does it...Ch. 16 - Prob. 16.4CQCh. 16 - If you steadily shake one end of a taut rope three...Ch. 16 - (a) If a long rope is hung from a ceiling and...Ch. 16 - Why is a pulse on a string considered to be...Ch. 16 - Does the vertical speed of an element of a...Ch. 16 - In an earthquake, both S (transverse) and P...Ch. 16 - A seismographic station receives S and P waves...Ch. 16 - Ocean waves with a crest-to-crest distance of 10.0...Ch. 16 - At t = 0, a transverse pulse in a wire is...Ch. 16 - Two points A and B on the surface of the Earth are...Ch. 16 - A wave is described by y = 0.020 0 sin (kx - t),...Ch. 16 - A certain uniform string is held under constant...Ch. 16 - A sinusoidal wave is traveling along a rope. The...Ch. 16 - For a certain transverse wave, the distance...Ch. 16 - Prob. 16.9PCh. 16 - When a particular wire is vibrating with a...Ch. 16 - The string shown in Figure P16.11 is driven at a...Ch. 16 - Consider the sinusoidal wave of Example 16.2 with...Ch. 16 - Prob. 16.13PCh. 16 - (a) Plot y versus t at x = 0 for a sinusoidal wave...Ch. 16 - A transverse wave on a siring is described by the...Ch. 16 - A wave on a string is described by the wave...Ch. 16 - A sinusoidal wave is described by the wave...Ch. 16 - A sinusoidal wave traveling in the negative x...Ch. 16 - (a) Write the expression for y as a function of x...Ch. 16 - A transverse sinusoidal wave on a string has a...Ch. 16 - Review. The elastic limit of a steel wire is 2.70 ...Ch. 16 - A piano siring having a mass per unit length equal...Ch. 16 - Transverse waves travel with a speed of 20.0 m/s...Ch. 16 - A student taking a quiz finds on a reference sheet...Ch. 16 - An Ethernet cable is 4.00 in long. The cable has a...Ch. 16 - A transverse traveling wave on a taut wire has an...Ch. 16 - A steel wire of length 30.0 m and a copper wire of...Ch. 16 - Why is the following situation impossible? An...Ch. 16 - Tension is maintained in a string as in Figure...Ch. 16 - Review. A light string with a mass per unit length...Ch. 16 - Prob. 16.31PCh. 16 - In a region far from the epicenter of an...Ch. 16 - Transverse waves are being generated on a rope...Ch. 16 - Sinusoidal waves 5.00 cm in amplitude are to be...Ch. 16 - A sinusoidal wave on a string is described by die...Ch. 16 - A taut tope has a mass of 0.180 kg and a length...Ch. 16 - A long string carries a wave; a 6.00-m segment of...Ch. 16 - A horizontal string can transmit a maximum power...Ch. 16 - The wave function for a wave on a taut siring is...Ch. 16 - A two-dimensional water wave spreads in circular...Ch. 16 - Prob. 16.41PCh. 16 - Prob. 16.42PCh. 16 - Show that the wave function y = eb(x vt) is a...Ch. 16 - Prob. 16.44PCh. 16 - Prob. 16.45APCh. 16 - The wave is a particular type of pulse that can...Ch. 16 - A sinusoidal wave in a rope is described by the...Ch. 16 - The ocean floor in underlain by a layer of basalt...Ch. 16 - Review. A 2.00-kg I Jock hangs from a rubber cord,...Ch. 16 - Review. A block of mass M hangs from a rubber...Ch. 16 - A transverse wave on a sting described by the wave...Ch. 16 - A sinusoidal wave in a string is described by the...Ch. 16 - Review. A block of mass M, supported by a string,...Ch. 16 - An undersea earthquake or a landslide can produce...Ch. 16 - Review. A block of mass M = 0.450 kg is attached...Ch. 16 - Review. A block of mass M = 0.450 kg is attached...Ch. 16 - Prob. 16.57APCh. 16 - Prob. 16.58APCh. 16 - A wire of density is tapered so that its...Ch. 16 - A rope of total mass m and length L is suspended...Ch. 16 - Prob. 16.61APCh. 16 - Prob. 16.62APCh. 16 - Review. An aluminum wire is held between two...Ch. 16 - Assume an object of mass M is suspended from the...Ch. 16 - Prob. 16.65CPCh. 16 - A string on a musical instrument is held under...Ch. 16 - If a loop of chain is spun at high speed, it can...
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