Since the length of the rod does not change, the increment due to increase in temperature will be balanced by the compression due to applied force.
Y=lΔlAF⇒lΔl=AYF
Also lΔl=αΔT
∴AYF=αΔT
Y=AαΔTF
A rod, of length L at room temperature and uniform area of cross section A, is made of a metal having coefficient of linear expansion α/∘C It is observed that an external compressive force F is applied on each of its ends, prevents any change in the length of the rod when its temperature rises by ΔTK Young's modulus, Y for this metal is:
Held on 9 Jan 2019 · Verified 6 Jul 2026.
Aα(ΔT−273)F
AαΔT2F
AαΔTF
2AαΔTF
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