A 350 g block is attached to a vertical spring whose stiffness constant is 12 N/m . The block is released at the position where the spring is unextended.

Fspring = -kx where x is extension up
= -12 x N

m = 0.35 kg

Weight = .35 * 9.8 = 3.45 N

How far will it drop before the force up = the force down? (the equilibrium position)
-k (-x) + m g = 0
12 x = -3.45
x = -.2875
How much potential energy did it lose going from x = 0 to x = -.2875 ?
m g h = 3.45 * .2875 = .992 Joules
that is kinetic energy as it passes the equilibrium point where x = -.2875
(1/2) m v^2 = .992
(1/2) .35 v^2 = .992
v = 2.38 m/s as it passes through equilibrium point
The total energy in the spring increases when it stops at the bottom to start back up> That increase is
.992 J
so the total energy stored in the spring is (1/2) 12 (.2875^2)+ .992
= 1.488 Joules
(1/2)(12) (total extension)^2 = 1.488
total extension = .4980 meters

amplitude of motion = .4980 - .2875 = .2105 meters

b) (1/2) period
where
period = 2 pi sqrt (M/k)
T = 2 pi sqrt(.35/12) = 1.07 seconds
so
0.5 seconds