Answer:
a. 87.7° b. It is less than 0.10g
Step-by-step explanation:
a. Angle of incline
To find the angle of incline,we resolve the weight of the sphere into its horizontal and vertical component. mgcosθ and mgsinθ respectively. The horizontal component provides a torque along the incline which produces the linear acceleration, a of the center of mass.
The torque, τ = mgRcosθ = Iα
where m = mass of sphere, R = radius of sphere, θ = angle of incline, I = moment of inertia of sphere = 2/5MR² and α = angular acceleration of sphere = a/R where a = linear acceleration of center of mass of sphere
So, MgRcosθ = Iα = Ia/R
MgRcosθ = 2/5MR²a/R
MgRcosθ = 2aMR/5
gcosθ = 2a/5
a = 5gcosθ/2 if a = 0.10g
0.10g = 5gcosθ/2
2 × 0.10g/5 = gcosθ
2 × 0.10/5 = cosθ
cosθ = 0.04
θ = cos⁻¹0.04 = 87.7°
So, the angle of incline must be 87.7°
b
If a frictionless block were to slide down the incline at that angle, the magnitude of its acceleration would less than 0.10g. This is because the component of acceleration along the incline is gcosθ = gcos87.7° = 0.04g.
So, it is obviously less.