The period of a simple pendulum is given by
[tex]T= 2 \pi \sqrt{ \frac{L}{g} } [/tex]
where
L is the pendulum length
g is the acceleration of gravity
If we move the same pendulum from Earth to the Moon, its length L remains the same, while the acceleration of gravity g changes. So we can write the period of the pendulum on Earth as:
[tex]T_e= 2 \pi \sqrt{ \frac{L}{g_e} } [/tex]
where [tex]g_e[/tex] is the acceleration of gravity on Earth, while the period of the pendulum on the Moon is
[tex]T_m= 2 \pi \sqrt{ \frac{L}{g_m} } [/tex]
where [tex]g_m[/tex] is the acceleration of gravity on the Moon.
If we do the ratio of the two periods, we get
[tex] \frac{T_m}{T_e} = \sqrt{ \frac{g_e}{g_m} } [/tex]
but the gravity acceleration on the Moon is 1/6 of the gravity acceleration on Earth, so we can write [tex]g_e = 6 g_m[/tex] and we can rewrite the previous ratio as
[tex]\frac{T_m}{T_e} = \sqrt{ \frac{6 g_m}{g_m} }= \sqrt{6} [/tex]
so the period of the pendulum on the Moon is
[tex]T_m = \sqrt{6} T_e = \sqrt{6} (1.6 s)=3.9 s[/tex]
