livethere said:
However I'm wondering if the greater mass of those two objects would be attracted more and would therefore be moved faster than the object with lesser mass towards the main attractive object.
Post #3 showed very simply that the rate of acceleration by gravitational force is
independent of the mass of the object being accelerated.
That is the answer to your question. Call the main attractive object ## M ##, and your two smaller objects ## m_1 ## and ## m_2 ##, then run through the derivation shown in post 3 again. You should end up with the acceleration for
both ## m_1 ## and ## m_2 ## being equal to ## \frac{GM}{R^2}##. If they have the same acceleration, they fall with the same speed when dropped from rest. Period.
Perhaps what is confusing you is that the
more massive object would feel a larger force. That is true! The more massive object
would feel a larger force if placed in the same gravitational field as the smaller object. But that larger force is accelerating a
more massive object, compared to the force accelerating the less massive object, and therefore gets less "bang for its buck" in the acceleration department.
The ratios work out in such a way that the acceleration each experiences is the same.