21ST CENT.AST.W/WKBK+SMARTWORK >BI<
21ST CENT.AST.W/WKBK+SMARTWORK >BI<
6th Edition
ISBN: 9780309341523
Author: Kay
Publisher: NORTON
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Chapter 11, Problem 35QP

(a)

To determine

The surface are and the volume of the moon Io.

(a)

Expert Solution
Check Mark

Answer to Problem 35QP

The surface are of the moon is 4.16×1013m2 and the volume of the moon is 2.52×1019m3.

Explanation of Solution

The surface of the moon Io is considered to be perfectly spherical.

Write the expression for the surface area for the spherical body.

  A=4πR2        (I)

Here, A is the surface are of the moon Io and R is the radius of the moon.

Write the expression for the volume of the spherical body.

  V=43πR3        (II)

Here, V is the volume of the moon.

Conclusion:

Substitute 1820km for R in equation (I).

  A=4π(1820km(1000m1km))2=12.56(3.31×1012)m2=4.16×1013m2

Substitute 1820km for R in equation (II).

  V=43π(1820km(1000m1km))3=4.188(6.028×1018)m3=2.52×1019m3

Thus, the surface are of the moon is 4.16×1013m2 and the volume of the moon is 2.52×1019m3.

(b)

To determine

The volume of the volcanic material deposited on Io’s surface every year.

(b)

Expert Solution
Check Mark

Answer to Problem 35QP

The volume of volcanic material deposited on the moon is one year is 1.24×1011m3.

Explanation of Solution

The thickness of the layer of lava and ash on the surface of the Io per year is about 3mm.

Write the expression for the volume of the volcanic material deposited on the moon.

  V=A×d        (III)

Here, V is the volume of volcanic material deposited and d is the average depth of deposition per year.

Conclusion:

Substitute 4.16×1013m2 for A and 3mm for d in equation (III).

  V=(4.16×1013m2)(3mm(1m1000mm))=1.24×1011m3

Thus, the volume of volcanic material deposited on the moon is one year is 1.24×1011m3.

(c)

To determine

The time taken for the volcanic deposition equal to that of the  volume of the moon.

(c)

Expert Solution
Check Mark

Answer to Problem 35QP

The time taken for the volcanic eruption to be equal to the volume of the moon is 2.03×108years.

Explanation of Solution

Write the expression for the time taken for volcanic deposition equal to mass of moon Io.

  t=VV        (IV)

Here, t is the time taken for the deposition of the volcanic material.

Conclusion:

Substitute 2.52×1019m3 for V and 1.24×1011m3 for V in equation (IV).

  t=2.52×1019m31.24×1011m3/year=2.03×108years

Thus, the time taken for the volcanic eruption to be equal to the volume of the moon is 2.03×108years.

(d)

To determine

The number of times the moon had turned inside out all over the age of the solar system.

(d)

Expert Solution
Check Mark

Answer to Problem 35QP

The moon could be turned inside out for 20 times for all over the age of the solar system.

Explanation of Solution

The moon takes 2.03×108years for the total volume of the volcanic eruption to be equal to its mass. Therefore, the number of times it had turned inside out all through the age of the solar system will be the ratio of the total age to the time taken to turn out once.

The age of the solar system is 4.0billionyears or 4×109years.

Write the expression for the number of times the moon turned inside out over the age of solar system.

  n=Tt        (V)

Here, n is the number of times the moon turned inside out and T is the total age of the solar system.

Conclusion:

Substitute 4×109years for T  and 2.03×108years for t in equation (V).

  n=4×109years2.03×108years20

Thus, the moon could be turned inside out for 20 times for all over the age of the solar system.

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