Hmmm ... this is true, conditionally: a larger NET force gives rise to a proportional acceleration.
That is to say, when you're done adding up ALL of the forces acting on a body, making sure to take direction into account, the resultant force can be related to the acceleration the body will experience with the (famous) equation:
ΣF = m * a
This is Newton's second Law, a candidate for the most important equation in all of physics.
Remember, "F" and "a" are vectors (direction must be considered).
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 slope represents a change in velocity, or acceleration. The acceleration is the gradient (steepness) of the line. A larger gradient means faster acceleration. if the gradient points down and is negative then it represents deceleration.
Increasing speed is acceleration. It could be classed as walking faster, or driving faster (keeping within the speed limit, of course!).
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 greater the acceleration of the object the larger the force that is acting upon an object. This can be proven by Newton's second law.
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 larger sail area causes a larger foil to pull the boat faster.
The Sun has a much larger gravitational pull , an asteroid would be pulled faster toward the sun, if it were in the same proximity.
The slope represents a change in velocity, or acceleration. The acceleration is the gradient (steepness) of the line. A larger gradient means faster acceleration. if the gradient points down and is negative then it represents deceleration.
Larger stars have a larger mass and stronger gravity, which means their cores are more compressed. The greater compression leads to a higher core temperature, which causes faster fusion.
Increasing speed is acceleration. It could be classed as walking faster, or driving faster (keeping within the speed limit, of course!).
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.
nonono bigger is not always faster. the answer to ur question is newtons law of motion, go look it up
The greater the acceleration of the object the larger the force that is acting upon an object. This can be proven by Newton's second law.
gravity
The smaller object will have a larger acceleration than the larger object. This is because, from Newton's second law, the acceleration of a body is given by: a = F/m where a is acceleration F is resultant force and m is mass F is constant, so acceleration is inversely proportional to mass. Hence, the smaller object will have a larger acceleration.
Air resistance