![]() ![]() The gravitational field strength is a property of the location within Earth's gravitational field and not a property of the baby elephant nor the mouse. This ratio (F net/m) is sometimes called the gravitational field strength and is expressed as 9.8 N/kg (for a location upon Earth's surface). The ratio of force to mass (F net/m) is the same for the elephant and the mouse under situations involving free fall. And thus, the direct effect of greater force on the 1000-kg elephant is offset by the inverse effect of the greater mass of the 1000-kg elephant and so each object accelerates at the same rate - approximately 10 m/s/s. This increased mass has an inverse effect upon the elephant's acceleration. The 1000-kg baby elephant obviously has more mass (or inertia). But acceleration depends upon two factors: force and mass. This greater force of gravity would have a direct effect upon the elephant's acceleration thus, based on force alone, it might be thought that the 1000-kg baby elephant would accelerate faster. If Newton's second law were applied to their falling motion, and if a free-body diagram were constructed, then it would be seen that the 1000-kg baby elephant would experiences a greater force of gravity. But why? Consider the free-falling motion of a 1000-kg baby elephant and a 1-kg overgrown mouse. Under such conditions, all objects will fall with the same rate of acceleration, regardless of their mass. Objects that are said to be undergoing free fall, are not encountering a significant force of air resistance they are falling under the sole influence of gravity. a) will be applied to analyze the motion of objects that are falling under the sole influence of gravity (free fall) and under the dual influence of gravity and air resistance.Īs learned in an earlier unit, free fall is a special type of motion in which the only force acting upon an object is gravity.To answer the above questions, Newton's second law of motion (F net = m In situations in which there is air resistance, why do more massive objects fall faster than less massive objects?.Why do objects that encounter air resistance ultimately reach a terminal velocity?.In particular, two questions will be explored: In addition to an exploration of free fall, the motion of objects that encounter air resistance will also be analyzed. ![]() because the air resistance is the same for each? Why? These questions will be explored in this section of Lesson 3. But why do all objects free fall at the same rate of acceleration regardless of their mass? Is it because they all weigh the same?. This particular acceleration value is so important in physics that it has its own peculiar name - the acceleration of gravity - and its own peculiar symbol - g. In a previous unit, it was stated that all objects ( regardless of their mass) free fall with the same acceleration - 9.8 m/s/s. ![]()
0 Comments
Leave a Reply. |