The orbital period of the artificial satellite is 1.5 hours.
Given the data in the question;
Acceleration due to gravity; [tex]a = 9.00 m/s^2[/tex]
Orbital period of the satellite; [tex]T =\ ?[/tex]
To determine the orbital period of the satellite, we make use of Kepler's third law:
[tex]T^2= [\frac{4\pi ^2}{GM_E}]r^3[/tex]
First we find the orbital radius of the artificial satellite
Using Newton's law of universal gravitation
[tex]F = \frac{Gm_Em}{r^2}[/tex]
Where m is mass of satellite, [tex]m_E[/tex] is mass of earth ( [tex]5.972 * 10^{24} kg[/tex] ), G is the universal gravitational constant( [tex]6.67430*10^{-11} N.m^2/kg^2[/tex] ) and r is the orbital radius.
We know that, Force; [tex]F = mass *gravity = mg[/tex]
So
[tex]mg = \frac{Gm_Em}{r^2}\\\\g = \frac{Gm_E}{r^2}\\\\r^2 = \frac{Gm_E}{g}\\\\r = \sqrt{\frac{Gm_E}{g}}[/tex]
We substitute in the values
[tex]r = \sqrt{\frac{(6.67430*10^{-11}N.m^2/kg^2)(5.972*10^{24}kg}{9.00m/s^2}}\\\\r = 6.65*10^6 m[/tex]
Now, using the of Kepler's third law:
[tex]T^2= [\frac{4\pi ^2}{GM_E}]r^3[/tex]
We substitute our values into the equation
[tex]T^2 = [\frac{4\pi ^2}{6.67430*10^{-11}N.m^2/kg^2)(5.972*10^{24}kg} ](6.65*10^6m)^3\\\\T^2 = 2.9127*10^{7}s^2\\\\T = \sqrt{2.9127*10^{7}s^2}\\\\T = 5396.94s\\\\T = 1.5hrs[/tex]
Therefore, the orbital period of the artificial satellite is 1.5 hours.
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