Suppose the Sun contracts (collapses) to a pulsar. Estimate the minimum radius of the pulsar and its period of rotation. The period of revolution of the Sun about its axis is 25.38 days (1 day = 24 hours).

Suppose the Sun contracts (collapses) to a pulsar. Estimate the minimu

1.	Suppose the Sun contracts (collapses) to a pulsar. Estimate the minimum radius of the pulsar and its period of rotation. The period of revolution of the Sun about its axis is 25.38 days (1 day = 24 hours).
Answer» Solution :Applying the law of conservation of momentum we can find the relation between the pulsar radius and its period of revolution. We have `I_(o.)omega_(o.)=IOMEGA, "or " 2/5MR_(o.)^2(2pi)/(T_(o.))=2/5MR_(o.)^2(2pi)/T` Hence `R_(o.)^2/T_(o.)=R^2/T` To prevent the escape of matter as the speed of rotation is increased the force of GRAVITY should exceed the centrifugal force, i.e.`momega^2RltR_(GR) ` Hence `(4pi^2mR)/(T^2)lt(gammamM_(o.))/(R^2)` THEREFORE the second relation sought between the pulsar radius and its period of revolution is of the form p`R^3/T^2lt(gammaM_(o.))/(4pi^2)` Eliminating the pulsar period from both equations, we obtain `Rge(4pi^2R_(o.)^1)/(gammaM_(o.)T_(o.)^2)=(4pi^2xx7^4xx10^(32))/(6.67xx10^(-11) xx2xx10^(30) xx2.2^(2) xx10^(12)) ~~15km` `T ~~ R^2T _(o.)//R_(o.)^2 ~~10^(-3)8`

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Suppose the Sun contracts (collapses) to a pulsar. Estimate the minimum radius of the pulsar and its period of rotation. The period of revolution of the Sun about its axis is 25.38 days (1 day = 24 hours).

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