Explain experimental determination of Young’s modulus.
Explain experimental determination of Young’s modulus.
A typical experimental arrangement to determine Young's modulus of a material of wire is shown as in figure.
It consists of two long straight wires of same length and equal radius suspended side by side from a fixed rigid support.
The wire$ A$ (reference wire) carries a millimeter main scale M and a pan to place a weight. The wire $B$ (experimental wire) of uniform area of cross-section also carries a pan in which known weights can be placed.
A vernier scale $\mathrm{V}$ is attached to a pointer at the bottom of the experimental wire $\mathrm{B}$ and the main scale $M$ is fixed to the reference wire $A$.
The weights placed in the pan exert a downward force and stretch the experimental wire under a tensile stress. The elongation of the wire is measured by the vernier arrangement. The reference wire is used to compensate for any change in length that may occur due to change in room temperature, any change in length of the reference wire will be accompanied by an equal change in experimental wire.
Both the reference and experimental wires are given an initial small load to keep the wires straight and the vernier reading is noted.
Now the experimental wire is gradually loaded with more weights to bring it under a tensile stress and the vernier reading is noted again.
The difference between two vernier readings gives the elongation produced in the wire.
Let $r$ and $\mathrm{L}$ be the initial radius and length of the experimental wire respectively then the area of cross-section of wire would be $\pi r^{2}$.
Similar Questions
A rod of length $l$ and area of cross-section $A$ is heated from $0°C$ to $100°C$. The rod is so placed that it is not allowed to increase in length, then the force developed is proportional to
A rod of length $l$ and area of cross-section $A$ is heated from $0°C$ to $100°C$. The rod is so placed that it is not allowed to increase in length, then the force developed is proportional to
A rigid massless rod of length $6\ L$ is suspended horizontally by means of two elasticrods $PQ$ and $RS$ as given figure. Their area of cross section, young's modulus and lengths are mentioned in figure. Find deflection of end $S$ in equilibrium state. Free end of rigid rod is pushed down by a constant force . $A$ is area of cross section, $Y$ is young's modulus of elasticity
A rigid massless rod of length $6\ L$ is suspended horizontally by means of two elasticrods $PQ$ and $RS$ as given figure. Their area of cross section, young's modulus and lengths are mentioned in figure. Find deflection of end $S$ in equilibrium state. Free end of rigid rod is pushed down by a constant force . $A$ is area of cross section, $Y$ is young's modulus of elasticity
Force constant of a spring $(K)$ is synonymous to
Force constant of a spring $(K)$ is synonymous to
A steel rod has a radius of $20\,mm$ and a length of $2.0\,m$. A force of $62.8\,kN$ stretches it along its length. Young's modulus of steel is $2.0 \times 10^{11}\,N / m ^2$. The longitudinal strain produced in the wire is $..........\times 10^{-5}$
A steel rod has a radius of $20\,mm$ and a length of $2.0\,m$. A force of $62.8\,kN$ stretches it along its length. Young's modulus of steel is $2.0 \times 10^{11}\,N / m ^2$. The longitudinal strain produced in the wire is $..........\times 10^{-5}$
- [JEE MAIN 2023]
Young's modulus is determined by the equation given by $\mathrm{Y}=49000 \frac{\mathrm{m}}{\ell} \frac{\text { dyne }}{\mathrm{cm}^2}$ where $\mathrm{M}$ is the mass and $\ell$ is the extension of wre used in the experiment. Now error in Young modules $(\mathrm{Y})$ is estimated by taking data from $M-\ell$ plot in graph paper. The smallest scale divisions are $5 \mathrm{~g}$ and $0.02$ $\mathrm{cm}$ along load axis and extension axis respectively. If the value of $M$ and $\ell$ are $500 \mathrm{~g}$ and $2 \mathrm{~cm}$ respectively then percentage error of $\mathrm{Y}$ is :
Young's modulus is determined by the equation given by $\mathrm{Y}=49000 \frac{\mathrm{m}}{\ell} \frac{\text { dyne }}{\mathrm{cm}^2}$ where $\mathrm{M}$ is the mass and $\ell$ is the extension of wre used in the experiment. Now error in Young modules $(\mathrm{Y})$ is estimated by taking data from $M-\ell$ plot in graph paper. The smallest scale divisions are $5 \mathrm{~g}$ and $0.02$ $\mathrm{cm}$ along load axis and extension axis respectively. If the value of $M$ and $\ell$ are $500 \mathrm{~g}$ and $2 \mathrm{~cm}$ respectively then percentage error of $\mathrm{Y}$ is :
- [JEE MAIN 2024]