To achieve more acceleration, you need more force.
Acceleration is negative.
It is the velocity that increases.
Newton's secong law indicates that an object accelerates in the presence of a net force on it. But it doesn't mean that an object should accelerate when two forces act on it. It depends more on the orientation or direction of force. Say if 2 forces act in opposite directions then the net force would be 0 and thus no acceleration is caused. Hence take NET FORCE, not just force acting into consideration.
Increasing the temperature the number of particles remain constant and the pressure increase.
F = M A Acceleration is directly proportional to force. When force applied to an object is reduced to one third, the object's acceleration is reduced to one third.
its acceleration will be increased
If you increase the force on an object acceleration increases . As F = m*a, where F = Force , m = mass of the object & a = acceleration
If you increase the force on an object acceleration increases . As F = m*a, where F = Force , m = mass of the object & a = acceleration
In that case, the acceleration will also increase.
F=m.a , a=F/m; acceleration is directly proportional with force. acceleration increase while force increase.
it is tripled
The force also increases.
If the mass of an object increases, what happens to the acceleration?
Speed increase constantly.
Speed increase constantly.
From Newton's Second Law of Motion, I know that Fnet=manet. anet is the net acceleration. From this equation, I know that Fnet is proportional to anet. THis means that if I decrease the net force, I decrease the net acceleration. If I increase the net force, I increase the net acceleration. If your Fnet equation is Fnet=Fapp-Ff, then increasing the applied force would also increase the net acceleration. Therefore, more applied fore, more acceleration.
The same as the relation between acceleration and any other force. Force = (mass) x (acceleration) If the force happens to be gravitational, then the acceleration is down, and the formula tells you the size of the acceleration. If the acceleration is down and there are no rocket engines strapped to the object, then it's a pretty safe bet that the force is gravitational, and the formula tells you the size of the force.