The bulk modulus of a spherical object is 'B'. If it is subjected to uniform pressure 'P', the fractional decrease in radius is

Q: The bulk modulus of a spherical object is '$B$'. If it is subjected to uniform pressure '$P$', the fractional decrease in radius is

b Bulk modulus $B$ is given as $B = \frac{{ - pV}}{{\Delta V}}$ $...(i)$ The volume of a spherical object of radius $r$ is given as $V = \frac{4}{3}\pi {r^3}\,\,,\,\,\Delta V = \frac{4}{3}\pi \left( {3{r^2}} \right)\Delta r$ $\therefore - \frac{V}{{\Delta V}} = \frac{{\frac{4}{3}\pi {r^3}}}{{\frac{4}{3}\pi 3{r^2}\Delta r}}\,\,or\,\, - \frac{V}{{\Delta V}} = - \frac{r}{{3\Delta r}}$ Put this value in eqn. $(i)$, we get $B = - \frac{{pr}}{{3\Delta r}}$ Fractional decrease in radius is $ - \frac{{\Delta r}}{r} = \frac{p}{{3B}}$

SECTION - A [PHYSICS MCQ]

GSEB - English Medium

The bulk modulus of a spherical object is '$B$'. If it is subjected to uniform pressure '$P$', the fractional decrease in radius is

A$\frac{{3P}}{B}$
B$\;\frac{P}{{3B}}$
C$\;\frac{P}{B}$
D$\frac{B}{{3P}}$

NEET 2017, Medium

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

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