Q. No.1. \(\frac{{AY}}{\alpha \Delta{T}}\)
2. \(\text {A}Y\alpha \Delta {T}\)
3. \(l^2 {Y}\alpha \Delta {T}\)
4. \(l {A}{Y} \alpha\Delta{T}\)
1. \(5\times10^{-4}~^{\circ}\text C^{-1}\)
2. \(2\times10^{-4}~^{\circ}\text C^{-1}\)
3. \(1\times10^{-4}~^{\circ}\text C^{-1}\)
4. \(0.5\times10^{-4}~^{\circ}\text C^{-1}\)
A uniform cylindrical rod of length \(L\) and radius \(r,\) is made from a material whose Young’s modulus of Elasticity equals \(Y.\) When this rod is heated by temperature \(T\) and simultaneously subjected to a net longitudinal compressional force \(F,\) its length remains unchanged. The coefficient of volume expansion, of the material of the rod, is (nearly) equal to:
| 1. | \(\dfrac{3F}{\pi r^2YT}\) | 2. | \(\dfrac{6F}{\pi r^2YT}\) |
| 3. | \(\dfrac{F}{\pi r^2YT}\) | 4. | \(\dfrac{9F}{\pi r^2YT}\) |
1. \( \dfrac{F} { {A} \alpha \Delta{T}}\)
2. \( \dfrac{F} { {A} \alpha (\Delta{T}-273)}\)
3. \( \dfrac{F} { 2{A} \alpha \Delta{T}}\)
4. \( \dfrac{2F} { {A} \alpha \Delta{T}}\)
When the temperature of a metal wire is increased from \(0^\circ ~\mathrm{C}\) to \(10^\circ ~\mathrm{C}\), its length increases by \(0.02\%\). The percentage change in its mass density will be closest to:
1. \(0.008\)%
2. \(0.06\)%
3. \(0.8\)%
4. \(2.3\)%
Two different wires having lengths \(L_1\) and \(L_2\), and respective temperature coefficient of linear expansion \(\alpha_1\) and \(\alpha _2\), are joined end-to-end. Then the effective temperature coefficient of linear expansion is:
1. \( 4 \frac{\alpha_1 \alpha_2}{\alpha_1+\alpha_2} \frac{L_2 L_1}{\left(L_2+L_1\right)^2} \)
2. \( 2 \sqrt{\alpha_1 \alpha_2} \)
3. \( \frac{\alpha_1+\alpha_2}{2} \)
4. \( \frac{\alpha_1 L_1+\alpha_2 L_2}{L_1+L_2}\)
A cube is constructed from a metal sheet such that each of its sides has a length \(a\) at room temperature \(T.\) The coefficient of linear expansion of the metal is \(\alpha.\) The entire cube is then heated uniformly so that its temperature increases by a small amount \(\Delta T,\) making the new temperature \(T+\Delta T.\) Assuming the expansion is small and isotropic, what is the cube's volume increase due to this heating?
| 1. | \( 3 {a}^3 \alpha \Delta{T} \) | 2. | \( 4{a}^3 \alpha \Delta{T} \) |
| 3. | \( 4 \pi{a}^3 \alpha \Delta {T} \) | 4. | \( \dfrac{4}{3} \pi{a}^3 \alpha \Delta {T} \) |
1. \(2.4 \times 10^6 \mathrm{~cm}^3 \)
2. \(1.2 \times 10^5 \mathrm{~cm}^3 \)
3. \(6.0 \times 10^4 \mathrm{~cm}^3 \)
4. \(4.8 \times 10^5 \mathrm{~cm}^3\)
| 1. | \(125.7^\circ\text{C}\) | 2. | \(91.7^\circ\text{C}\) |
| 3. | \(425.7^\circ\text{C}\) | 4. | \(152.7^\circ\text{C}\) |
\(\left(\alpha_{\text {iron }}=1.2 \times 10^{-5} \mathrm{~K}^{-1} \text { and } \alpha_{\text {brass }}=1.8 \times 10^{-5} \mathrm{~K}^{-1}\right)\).
1. \(20\) cm
2. \(40\) cm
3. \(60\) cm
4. \(80\) cm
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