A small, stationary sphere carries a net charge Q. You perform the following experiment to measure Q: From a large distance you fire a small particle with mass m = 4.00 Ã 10-4 kg and charge q = 5.00 Ã 10-8 C directly at the center of the sphere. The apparatus you are using measures the particleâs speed v as a function of the distance x from the sphere. The sphereâs mass is much greater than the mass of the projectile particle, so you assume that the sphere remains at rest. All of the measured values of x are much larger than the radius of either object, so you treat both objects as point particles. You plot your data on a graph of v2 versus (1/x) (Fig. P23.80). The straight line v2 = 400 m2/s2 â [(15.75 m3/s2)/x] gives a good fit to the data points.
Figure P23.80:
(a) Explain why the graph is a straight line.
(b) What is the initial speed v0 of the particle when it is very far from the sphere?
(c) What is Q?
(d). How close does the particle get to the sphere? Assume that this distance is much larger than the radii of the particle and sphere, so continue to treat them as point particles and to assume that the sphere remains at rest.
v² (m²/s²) 350 300 250 200 150 100 50 (m¯1) 2 4 6 8 10 12 14 16 18
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