(2) From assumption (c), the velocity (v) at time (t) of the water droplet is 3. v' + t+ro If the water drops from stationary, solve for v(t).

Question No. 2. 

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A water droplet evaporates before they reach the ground. ond orde E Figure 1: Water droplets [source] In this situation, a few assumptions are made: a) At initial point, a typical water droplet is in sphere shape with radius r and remain spherical while evaporating. b) The rate of evaporation (when it loses mass (m)) is proportional to the surface area, S. c) There is no air-resistance and downward direction is the positive direction. quati To describe this problem, given that p is the mass density of water, rois the radius of water before it drops, m is the water mass, V is the water volume and k is the constant of proportionality. QUESTION: (1) From assumption (b), show that the radius of the water droplet at time t is on er r(t) = () t + ro- %3D (or (Hint: m = pV,V =nr³, S = 4r2). 4 %3D 3 %3D (2) From assumption (c), the velocity (v) at time (t) of the water droplet is ou 3 v' + t+ro If the water drops from stationary, solve for v(t). (3) Determine the time when the water droplet has evaporated entirely, given that ro = 3mm. Then, 10 seconds after the water drops, the radius r = 2mm.