If the ratio of diameters, lengths and Young's modulus of steel and copper wires shown in the figure are p, q and s respectively, then

Q: If the ratio of diameters, lengths and Young's modulus of steel and copper wires shown in the figure are $p, q$ and $s$ respectively, then the corresponding ratio of increase in their lengths would be

b $As\,Y = \frac{{FL}}{{A\Delta L}} = \frac{{4FL}}{{\pi {D^2}\Delta L}}$ $\Delta L = \frac{{4FL}}{{\pi {D^2}Y}}$ $\therefore \frac{{\Delta {L_s}}}{{\Delta {L_c}}} = \frac{{{F_S}}}{{{F_C}}}\frac{{{L_S}}}{{{L_C}}}\frac{{D_C^2}}{{D_S^2}}\frac{{{Y_C}}}{{{Y_S}}}$ Where subscripts $'S'$ and $'C'$ refer to copper and steel respectively. $Here,\,{F_S} = \left( {5m + 2m} \right)g = 7mg$ ${F_C} = 5mg$ $\frac{{{L_S}}}{{{L_C}}} = q,\frac{{{D_S}}}{{{D_C}}} = p,\frac{{{Y_S}}}{{{Y_C}}} = s$ $\therefore \frac{{\Delta {L_S}}}{{\Delta {L_C}}} = \left( {\frac{{7mg}}{{5mg}}} \right)\left( q \right){\left( {\frac{1}{p}} \right)^2}\left( {\frac{1}{s}} \right) = \frac{{7q}}{{5{p^2}s}}$

SECTION - A [PHYSICS MCQ]

GSEB - English Medium

If the ratio of diameters, lengths and Young's modulus of steel and copper wires shown in the figure are $p, q$ and $s$ respectively, then the corresponding ratio of increase in their lengths would be

A$\frac{{5q}}{{7{p^2}s}}$
B$\;\frac{{7q}}{{5{p^2}s}}$
C$\;\frac{{2q}}{{5sp}}$
D$\;\frac{{7q}}{{5sp}}$

Diffcult

STD 11 Science
JEE
STD 11- 8. mechanical properties of solids
Physics

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