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2 years ago

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An object moves in a circle of radius R at constant speed with a period T. If you want to change only the period in order to cut

the object's acceleration in half, the new period should be A) Th/2 B) 7V2. C) T/4. D) 4T E) TI2

1 answer:

vladimir1956 [14]2 years ago

3 0

Answer: Option (B) is the correct answer.

Explanation:

Expression for centripetal acceleration is as follows.

a = $r \omega^{2}$ .......... (1)

Also, we know that

$\omega = \frac{2 \pi}{T}$ ........... (2)

Putting the value from equation (2) into equation (1) as follows.

a = $r (\frac{2 \pi}{T})^{2}$

= $r \frac{2 (\pi)^{2}}{4}$

As, $a \propto \frac{1}{T^{2}}$

a = $\frac{k}{T^{2}}$

or, $aT^{2} = k$

Now, we will reduce a to $\frac{a}{2}$ . So, new value of $T^{2}$ will be equal to $2T^{2}$ .

Therefore, value of new period will be as follows.

$T' = \sqrt{2T^{2}}$

= $\sqrt{2}T$

Thus, we can conclude that the new period is equal to $T \sqrt{2}$ .

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Explanation:

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Calculate the distance d from the center of the sun at which a particle experiences equal attractions from the earth and the sun

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Mass of earth = m = $5.976\times 10^{24} kg$

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Let the mass of the particle be m' which x distance from Sun.

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