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Chapter 13: Q4Q (page 359)

Question: In the relation \(\Delta l = \alpha {l_{\rm{o}}}\Delta T\), should \({l_{\rm{o}}}\) be the initial length, the final length, or does it matter?

Short Answer

Expert verified

\({l_{\rm{o}}}\) should be the initial length of the object.

Step by step solution

01

Meaning of thermal expansion

Thermal expansion may be defined as the change in the shape and size of an object accompanying a temperature change.

In the case of the solid object, all types of thermal expansion (linear, volume, and area) happen.

02

Formula for the final length of the object for linear expansion

The expression for the linear expansion of an object is as follows:

\(\Delta l = \alpha {l_{\rm{o}}}\Delta T\)

Here, \(\Delta l\) is the change in length; \(\Delta T\) is the change in the temperature; \(\alpha \) is the coefficient of linear expansion; \({l_{\rm{o}}}\) is the initial length of the object.

The change in length depends upon the initial length of the object. So, the final length of the object is equal to the initial length plus the change in length of the object.

\(l = {l_{\rm{o}}} + \alpha {l_{\rm{o}}}\Delta T\)

Here, \(l\) is the final length of the object.

If the temperature change is negative, the final length of the object decreases, but the initial length of the object will not change.

Thus, we can conclude that \({l_{\rm{o}}}\) should be the initial length of the object.

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Most popular questions from this chapter

Question:(II) A certain car has 14.0 L of liquid coolant circulating at a temperature of 93°C through the engine’s cooling system. Assume that, in this normal condition, the coolant completely fills the 3.5-L volume of the aluminum radiator and the 10.5-L internal cavities within the aluminum engine. When a car overheats, the radiator, engine, and coolant expand and a small reservoir connected to the radiator catches any resultant coolant overflow. Estimate how much coolant overflows to the reservoir if the system goes from 93°C to 105°C. Model the radiator and engine as hollow shells of aluminum. The coefficient of volume expansion for coolant is\({\bf{410}} \times {\bf{1}}{{\bf{0}}^{{\bf{ - 6}}}}\;{\bf{/^\circ C}}\).

(II) A sealed metal container contains a gas at 20.0°C and 1.00 atm. To what temperature must the gas be heated for the pressure to double to 2.00 atm? (Ignore the expansion of the container.)

(II) A tire is filled with air at 15°C to a gauge pressure of 230 kPa. If the tire reaches a temperature of 38°C, what fraction of the original air must be removed if the original pressure of 230 kPa is to be maintained?

Question:Estimate the number of air molecules in a room of length 6.0 m, width 3.0 m, and height 2.5 m. Assume the temperature is 22°C. How many moles does that correspond to?

Question: (II)Show that for a mixture of two gases at the same temperature, the ratio of their rms speeds is equal to the inverse ratio of the square roots of their molecular masses,\(\frac{{{{\bf{v}}_{\bf{1}}}}}{{{{\bf{v}}_{\bf{2}}}}}{\bf{ = }}\sqrt {\frac{{{{\bf{M}}_{\bf{2}}}}}{{{{\bf{M}}_{\bf{1}}}}}} \).
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