MHT CET 2022 11th August Evening Shift | MHT CET Year Wise Previous Years Questions

The masses and radii of the moon and the earth are $$\mathrm{M_1, R_1}$$ and $$\mathrm{M_2, R_2}$$ respectively. Their centres are at a distance $$\mathrm{d}$$ apart. What should be the minimum speed with which a body of mass '$$m$$' should be projected from a point midway between their centres, so as to escape to infinity?

$$\frac{\mathrm{G}\left(\mathrm{M}_1+\mathrm{M}_2\right)}{\mathrm{d}}$$

$$\sqrt[2]{\frac{G\left(M_1+M_2\right)}{d}}$$

$$\sqrt{\frac{G d}{M_1+M_2}}$$

$$\sqrt{\frac{M_1+M_2}{G d}}$$

MHT CET 2022 11th August Evening Shift

MCQ (Single Correct Answer)

-0

A monoatomic gas $$\left(\gamma=\frac{5}{3}\right)$$ initially at $$27^{\circ} \mathrm{C}$$ having volume '$$\mathrm{V}$$' is suddenly compressed to one-eighth of its original volume $$\left(\frac{\mathrm{V}}{8}\right)$$. After the compression its temperature becomes

580 K

1200 K

1160 K

927 K

MHT CET 2022 11th August Evening Shift

MCQ (Single Correct Answer)

-0

Two parallel conducting wires of equal length are placed distance 'd' apart, carry currents '$$\mathrm{I}_1$$' and '$$\mathrm{I}_2$$' respectively in opposite directions. The resultant magnetic field at the midpoint of the distance between both the wires is

$$\frac{\mu_0\left(I_1-I_2\right)}{\pi \mathrm{d}}$$

$$\frac{\mu_0\left(I_1+I_2\right)}{2 \pi d}$$

$$\frac{\mu_0\left(I_1-I_2\right)}{2 \pi \mathrm{d}}$$

$$\frac{\mu_0\left(I_1+I_2\right)}{\pi d}$$

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