Acceleration is typically measured in units of meters per second squared (m/s^2).
On a graph of acceleration, you would typically label the y-axis as "Acceleration (m/s^2)" and the x-axis as "Time (s)." This allows you to visually represent how acceleration changes with respect to time.
I believe gravity would fit that description.
Yes. Neglecting the effects of air resistance, all objects near the surface of the earth fall with the same constant acceleration, regardless of their mass/weight.
In a vacuum, objects would accelerate due to the force of gravity acting on them. The rate of acceleration would be the same for all objects, regardless of their mass, and would be equal to the acceleration due to gravity, which is approximately 9.8 m/s^2 near Earth's surface.
If objects are slowing down with time, the acceleration would be in the opposite direction of their motion. This would result in a negative acceleration, indicating deceleration or retardation.
On a graph of acceleration, you would typically label the y-axis as "Acceleration (m/s^2)" and the x-axis as "Time (s)." This allows you to visually represent how acceleration changes with respect to time.
On the moon, objects like a feather, a rock, and a hammer would fall with the same acceleration because there is no atmosphere to create air resistance that would affect their descent. This is known as the principle of equivalence, which states that in a vacuum, all objects experience the same acceleration due to gravity regardless of their mass.
I believe gravity would fit that description.
I believe gravity would fit that description.
Yes. Neglecting the effects of air resistance, all objects near the surface of the earth fall with the same constant acceleration, regardless of their mass/weight.
In a vacuum, objects would accelerate due to the force of gravity acting on them. The rate of acceleration would be the same for all objects, regardless of their mass, and would be equal to the acceleration due to gravity, which is approximately 9.8 m/s^2 near Earth's surface.
If objects are slowing down with time, the acceleration would be in the opposite direction of their motion. This would result in a negative acceleration, indicating deceleration or retardation.
Actually, objects moving around a circular path have two accelerations i.e. radial acceleration and tangential acceleration. Radial acceleration is towards the radius whereas tangential acceleration is the acceleration along the direction of the tangent to the path of the motion. So, I would say yes, they are accelerated towards the outer edge of the circle.
If mass increases and there is no friction, the acceleration of an object on an inclined plane would remain constant, assuming the incline angle and applied force remain the same. The acceleration is determined by the net force acting on the object, which in this case is equal to the component of the gravitational force parallel to the incline.
on the moon, which object would fall with the same acceleration
I believe gravity would fit that description.
I believe gravity would fit that description.