A uniform heavy rod of mass 20,kg. Cross sectional area 0.4,m ^{2} and length 20,m is hanging from a fixed support. Neglecting the lateral contraction,

Q: A uniform heavy rod of mass $20\,kg$. Cross sectional area $0.4\,m ^{2}$ and length $20\,m$ is hanging from a fixed support. Neglecting the lateral contraction, the elongation in the rod due to its own weight is $x \times 10^{-9} m$. The value of $x$ is (Given. Young's modulus $Y =2 \times 10^{11} Nm ^{-2}$ અને $\left.g=10\, ms ^{-2}\right)$

b $Y =\frac{ T }{ A } \frac{ dx }{ dy }$ $m =20\,kg$ $A =0.4\,m^{2}$ $1=20\,m$ let extension is $dy$ in length $dx$ $Y =\frac{\text { stress }}{\text { strain }}$ $Y =\frac{\frac{ T }{ A }}{\frac{ d }{ dx }}=\frac{ T }{ A } \cdot \frac{ dx }{ dy }$ $dy =\frac{ Tdx }{ AY }$ Tension at a distance $x$ from lower end $=\frac{ mg }{\ell} x$ So. $\int_{0}^{\Delta l} dy =\int_{0}^{\ell} \frac{ mg }{\ell} x \frac{ dx }{ AY }$ $\Delta \ell=\frac{ mg }{\ell AY }\left[\frac{ x ^{2}}{2}\right]_{0}^{\ell}$ $\Delta \ell=\frac{ mg \ell}{2\,AY }$ $\Delta \ell=\frac{20 \times 10 \times 20}{2 \times 0.4 \times 2 \times 10^{11}}$ $2500 \times 10^{-11}$ $\Delta \ell=25 \times 10^{-9}$ $= x \times 10^{-9}$

SECTION - A [PHYSICS MCQ]

GSEB - English Medium

A uniform heavy rod of mass $20\,kg$. Cross sectional area $0.4\,m ^{2}$ and length $20\,m$ is hanging from a fixed support. Neglecting the lateral contraction, the elongation in the rod due to its own weight is $x \times 10^{-9} m$. The value of $x$ is

(Given. Young's modulus $Y =2 \times 10^{11} Nm ^{-2}$ અને $\left.g=10\, ms ^{-2}\right)$

A$28$
B$25$
C$24$
D$23$

JEE MAIN 2022, Diffcult

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

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