1
MHT CET 2024 9th May Evening Shift
MCQ (Single Correct Answer)
+1
-0

The fringe width in an interference pattern is ' X '. The distance between the sixth dark fringe from one side of central bright band to the fourth bright fringe on other side is

A
1.5 X
B
2 X
C
5.5 X
D
9.5 X
2
MHT CET 2024 9th May Evening Shift
MCQ (Single Correct Answer)
+1
-0

A particle is executing a linear simple harmonic motion. Let ' $\mathrm{V}_1$ ' and ' $\mathrm{V}_2$ ' are its speed at distance ' $x_1$ ' and ' $x_2$ ' from the equilibrium position. The amplitude of oscillation is

A
$\sqrt{\frac{V_1^2 x_2^2-V_2^2 x_2^2}{V_1^2-V_2^2}}$
B
  $\sqrt{\frac{V_1^2-V_2^2}{V_1^2 x_2^2-V_2^2 x_1^2}}$
C
$\sqrt{\frac{V_1^2 x_2^2-V_2^2 x_1^2}{V_1^2-V_2^2}}$
D
$\sqrt{\frac{V_1^2 x_1^2-V_2^2 x_2^2}{V_1^2-V_2^2}}$
3
MHT CET 2024 9th May Evening Shift
MCQ (Single Correct Answer)
+1
-0

In hydrogen atom, if $\mathrm{V}_{\mathrm{n}}$ and $\mathrm{V}_{\mathrm{p}}$ are orbital velocities in $\mathrm{n}^{\text {th }}$ and $\mathrm{p}^{\text {th }}$ orbit respectively, then the ratio $\mathrm{V}_{\mathrm{p}}: \mathrm{V}_{\mathrm{n}}$ is

A
$\mathrm{p}: \mathrm{n}$
B
$\mathrm{n}: \mathrm{p}$
C
$\mathrm{p}^2: \mathrm{n}^2$
D
$\mathrm{n}^2: \mathrm{p}^2$
4
MHT CET 2024 9th May Evening Shift
MCQ (Single Correct Answer)
+1
-0

The work done in splitting a water drop of radius R into 64 droplets is ( $\mathrm{T}=$ Surface tension of water)

A
$6 \pi \mathrm{TR}^2$
B
$12 \pi \mathrm{TR}^2$
C
$8 \pi \mathrm{TR}^2$
D
$24 \pi \mathrm{TR}^2$
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