1
MHT CET 2021 20th September Evening Shift
+1
-0

A hollow charged metal sphere has radius 'R'. If the potential difference between its surface and a point at a distance '5 R' from the centre is $$\mathrm{V}$$, then magnitude of electric field Intensity at a distance '5R' from the centre of sphere is

A
$$\frac{V}{2 R}$$
B
$$\frac{\mathrm{V}}{20 \mathrm{R}}$$
C
$$10 \mathrm{VR}$$
D
$$20 \mathrm{VR}$$
2
MHT CET 2021 20th September Morning Shift
+1
-0

An electric dipole having dipole moment $$\mathrm{P}=\mathrm{q} \times 2 \ell$$ is placed in a uniform electric field '$$\mathrm{E}$$'. The dipole moment is along the direction of the field. The force acting on it and its potential energy are respectively

A
$$\mathrm{qE}$$ and minimum
B
$$\mathrm{qE}$$ and maximum
C
$$2 \mathrm{qE}$$ and minimum
D
zero and minimum
3
MHT CET 2021 20th September Morning Shift
+1
-0

A uniformly charged half ring of a radius ' $R$ ' has linear charge density '$$\sigma$$'. The electric potential at the centre of the half ring is ( $$\epsilon_0=$$ permittivity of free space)

A
$$\frac{\sigma}{6 \epsilon_0}$$
B
$$\frac{\sigma}{2 \epsilon_0}$$
C
$$\frac{\sigma}{\epsilon_0}$$
D
$$\frac{\sigma}{4 \epsilon_0}$$
4
MHT CET 2021 20th September Morning Shift
+1
-0

A spherical conducting shell of inner radius 'r$$_1$$' and outer radius 'r$$_2$$' has a charge 'Q'. A charge $$-$$q is placed at the centre of the shell. The surface charge density on the inner and outer surface of the shell will be A
$$\frac{q}{4 \pi r_1^2}$$ and $$\frac{\mathrm{Q}-\mathrm{q}}{4 \pi \mathrm{r}_2^2}$$
B
$$\frac{q}{4 \pi r_1^2}$$ and $$\frac{Q}{4 \pi r_2^2}$$
C
$$\frac{-q}{4 \pi r_1^2}$$ and $$\frac{Q+q}{4 \pi r_2^2}$$
D
zero and $$\frac{\mathrm{Q}-\mathrm{q}}{4 \pi \mathrm{r}_2^2}$$
MHT CET Subjects
Physics
Mechanics
Optics
Electromagnetism
Modern Physics
Chemistry
Physical Chemistry
Inorganic Chemistry
Organic Chemistry
Mathematics
Algebra
Trigonometry
Calculus
Coordinate Geometry
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