A75-kg snowboarder has an initial velocity of 5.0 m/s at the top of a 28 ∘ incline. after sliding down the 110-m long incline (on which the coefficient of kinetic friction is μk = 0.18), the snowboarder has attained a velocity v. the snowboarder then slides along a flat surface (on which μk = 0.15) and comes to rest after a distance x. part a use newton's second law to find the snowboarder's acceleration while on the incline and while on the flat surface.

Let the following denote:m - mass of the snowboarder, g -  acceleration due to gravity, F - friction force, a - acceleration down the slope, R - normal reaction of the slope, u - coefficient of friction on the slope, v0 - snowboarder's initial speed, v - snowboarder's speed at the base of the slope, F1 - friction force on the level, a1- acceleration on the level, 

Resolving parallel and perpendicular to the slope: mg sin(a) - F = ma would be equation 1 mg cos(a) = R would be equation 2F = uR would be equation 3
From (2) and (3): F = umg cos(a). 
Substituting this in (1): mg[ sin(a) - u cos(a) ] = ma a = g[ sin(a) - u cos(a) ] = 9.81[ sin(28) - 0.18 cos(28) ] = 3.05 m/s^2. 
v^2 = v0^2 + 2as v = sqrt(5.0^2 + 2 * 3.05 * 110) = 26.4 m/s. 
F1 = - u1 mg - u1 mg = m a1 a1 = - u1 g = - 0.15 * 9.81 = - 1.47 m/s^2 

It indicates no change in temperature and the process of matter changing its state

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