A 3.38 kg ball is pushed against a horizontal spring whose force constant is 1047 N/m, compressing the spring to x=0.23 m. When the system is released, the ball traveled along the horizontal surface whose coefficient of kinetic friction is 0.234 and then up a frictionless plane inclined at -28.1° above the horizontal. If the ball has reached a distance of d=0.76 m along the plane before sliding back downwards, how far did the ball travel the moment it leaves the spring until it reached the bottom of the inclined?

College Physics
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Chapter1: Units, Trigonometry. And Vectors
Section: Chapter Questions
Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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A 3.38 kg ball is pushed against a horizontal spring whose force constant is 1047 N/m,
compressing the spring to x=0.23 m. When the system is released, the ball traveled along
the horizontal surface whose coefficient of kinetic friction is 0.234 and then up a frictionless
plane inclined at -28.1° above the horizontal. If the ball has reached a distance of d=0.76
m along the plane before sliding back downwards, how far did the ball travel the moment it
leaves the spring until it reached the bottom of the inclined?
-x-
d
O 2.04 m
O 0.0950 m
O 3.34 m
O 1.81 m
x = 0
Ө
Transcribed Image Text:A 3.38 kg ball is pushed against a horizontal spring whose force constant is 1047 N/m, compressing the spring to x=0.23 m. When the system is released, the ball traveled along the horizontal surface whose coefficient of kinetic friction is 0.234 and then up a frictionless plane inclined at -28.1° above the horizontal. If the ball has reached a distance of d=0.76 m along the plane before sliding back downwards, how far did the ball travel the moment it leaves the spring until it reached the bottom of the inclined? -x- d O 2.04 m O 0.0950 m O 3.34 m O 1.81 m x = 0 Ө
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