F=mxa, m = can be small or large, a = change the motion (acceleration), F = the cause of the change the motion F1 changes the motion of m1 at a F2 changes the motion of m2 at a (same force, same size mass) (F1+F2) changes the motion of (m1 +m2) at a So it takes twice the force (F1+F2) to move twice the mass (m1 + m2) at the same change in motion (acceleration). If (F1 + F2) were to move smaller mass (m1) the acceleration would be larger. The "why" is hidden in the formula.
The amount of force required to change the motion of an object depends on its mass and the desired change in motion (acceleration). This relationship is described by Newton's second law of motion, which states that force is equal to mass multiplied by acceleration (F = ma). Therefore, a larger mass or a greater change in motion will require a greater force.
The more mass an object has, the more inertia it has. It is harder to change the motion of an object that has more mass.
It takes no force to 'move' an object. There are trillions of objects that are moving right now with no forces acting on them. It only takes force to 'accelerate' an object ... to change its motion, by changing its speed or the direction of its motion. force=mass*acceleration As mass increases, so does the force needed to change the object's motion.
MASS
The extent of resistance to a change of motion is determined by an objects mass. The mass of the object is measured in kilograms.
F=mxa, m = can be small or large, a = change the motion (acceleration), F = the cause of the change the motion F1 changes the motion of m1 at a F2 changes the motion of m2 at a (same force, same size mass) (F1+F2) changes the motion of (m1 +m2) at a So it takes twice the force (F1+F2) to move twice the mass (m1 + m2) at the same change in motion (acceleration). If (F1 + F2) were to move smaller mass (m1) the acceleration would be larger. The "why" is hidden in the formula.
Inertia resists the change in its motion/ velocity, and is proportional to its mass.
The amount of force required to change the motion of an object depends on its mass and the desired change in motion (acceleration). This relationship is described by Newton's second law of motion, which states that force is equal to mass multiplied by acceleration (F = ma). Therefore, a larger mass or a greater change in motion will require a greater force.
If your mass has 40 kg on earth what is your mass on moon
The inertia. This is directly related to the object's mass.
Due to the greater mass, the momentum will high, hence making its motion difficult to change.
Changes in motion are affected by the mass of the object. Newton's Second Law of Motion states that Force = (mass)(acceleration), or F=ma. This can be rewritten as: acceleration = Force/mass, or a=F/m. Acceleration is a measure of the rate of change of velocity of an object. If the same force is used, the objects with a bigger mass will accelerate at a lower rate.
Light has nothing to do with mass. Also note that mass is the resistance of a body to a change in motion.
Because it is lighter.
According to Newton's laws of motion, it is not.
The more mass an object has, the more inertia it has. It is harder to change the motion of an object that has more mass.