Abaseball (radius = .0366 in, mass = .145 kg) is dropped from rest at the top of the empire state building (height = 1250
ft). calculate (a) the initial potential energy of the baseball, (b) its nal kinetic energy, and (c) the total energy dissipated by
the falling baseball by computing the hue integral of the force of air resistance along the baseball’s total distance of fall.
compare this last result to the difference between the baseballs initial potential energy and its nal kinetic energy. (hint: in
part (c) make approximations when evaluating the hyperbolic functions obtained in carrying out the line integral.)

A2000 kg car is rounding a curve of radius 200 m on a level road. the maximum frictional force the road can exert on the tires of the car is 4000 n. what is the highest speed at which the car can round the curve?

(a) assume the equation x = at^3 + bt describes the motion of a particular object, with x having the dimension of length and t having the dimension of time. determine the dimensions of the constants a and b. (use the following as necessary: l and t, where l is the unit of length and t is the unit of time.) (b) determine the dimensions of the derivative dx/dt = 3at^2 + b. (use the following as necessary: l and t, where l is the unit of length and t is the unit of time.)

Intro: a solid ball of radius rb has a uniform charge density ρ. part a: what is the magnitude of the electric field e(r) at a distance r> rb from the center of the ball? express your answer in terms of ρ, rb, r, and ϵ0. part b: what is the magnitude of the electric field e(r) at a distance r express your answer in terms of ρ, rb, r, and ϵ0. part c: let e(r) represent the electric field due to the charged ball throughout all of space. which of the following statements about the electric field are true? check all that apply. e(0) = 0 e(rb)=0 limr→∞e(r)=0 the maximum electric field occurs when r=0 the maximum electric field occurs when r=rb the maximum electric field occurs as r→∞.