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What is law of acceleration and example?
The law of acceleration states that the acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass. This means that the greater the force applied to an object, the greater its acceleration will be, and the more massive an object is, the less it will accelerate for a given force. An example is when a car accelerates from rest when the driver steps on the gas pedal.
Is you use the same force on a less massive object what happens to the acceleration?
If you apply the same force to a less massive object, it will experience a greater acceleration compared to a more massive object. This is because acceleration is inversely proportional to mass when force is constant (Newton's second law of motion, F=ma).
What is the relationship between the mass and velocity of an object in uniform acceleration?
The relationship between the mass and velocity of an object in uniform acceleration is that the mass of the object does not directly influence its acceleration, but it does affect the force required to produce that acceleration. In other words, a more massive object will require a greater force to accelerate it to a given velocity compared to a less massive object. However, once the force is applied, both objects will accelerate at the same rate, assuming no other external forces are present.
If you use the same force on less massive object what happened to the acceleration?
Force equals mass times acceleration, so an alternative formula is acceleration equals force divided by mass. Therefore if the mass is decreased, the acceleration goes up. Thus a 100 HP engine on a motor cycle produces more acceleration than the same engine on a car.
Suppose you observe the two rotation curves shown at left, which galaxy is more massive?
The galaxy with the steeper rotation curve is more massive.
What is law of acceleration and example?
The law of acceleration states that the acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass. This means that the greater the force applied to an object, the greater its acceleration will be, and the more massive an object is, the less it will accelerate for a given force. An example is when a car accelerates from rest when the driver steps on the gas pedal.
Is you use the same force on a less massive object what happens to the acceleration?
If you apply the same force to a less massive object, it will experience a greater acceleration compared to a more massive object. This is because acceleration is inversely proportional to mass when force is constant (Newton's second law of motion, F=ma).
What is the relationship between the mass and velocity of an object in uniform acceleration?
The relationship between the mass and velocity of an object in uniform acceleration is that the mass of the object does not directly influence its acceleration, but it does affect the force required to produce that acceleration. In other words, a more massive object will require a greater force to accelerate it to a given velocity compared to a less massive object. However, once the force is applied, both objects will accelerate at the same rate, assuming no other external forces are present.
If you use the same force on less massive object what happened to the acceleration?
Force equals mass times acceleration, so an alternative formula is acceleration equals force divided by mass. Therefore if the mass is decreased, the acceleration goes up. Thus a 100 HP engine on a motor cycle produces more acceleration than the same engine on a car.
If the same force is constantly applied to two movable objects what will the more massive one do?
If the same force is constantly applied to two movable objects, the more massive one will accelerate. Also, the more massive one will accelerate more slowly than the less massive one.
Suppose you observe the two rotation curves shown at left, which galaxy is more massive?
The galaxy with the steeper rotation curve is more massive.
What affect does mass have on acceleration?
this equation might help force = mass * acceleration the more massive an object is the more force is required to accelerate it
Why is the acceleration is faster in small objects than in large objects?
The difference is due to inertia. Inertia is the resistance to a change in motion (acceleration). A more massive object will have greater inertia, and therefore a greater resistance to a change in motion, resulting in a slower acceleration. A less massive object has lower inertia, and therefore less of a resistance to a change in motion, resulting in a faster acceleration.
Do massive objects free fall at the same rate of acceleration as a less massive object?
Yes, in the absence of air resistance, all objects fall at the same rate of acceleration due to gravity, regardless of their mass. This principle is known as Galileo's principle of the equivalence of inertia and gravitation.
What is meant by acceleration due to gravity?
Earth being a massive body attracts every other massive body. This force of attraction is named as weight of the body. But force is equated to the expression m*a Here m is the mass of the body and a is the acceleration. So the general a is to be replaced by g a symbol meant for the acceleration due to gravity. Its average value is 9.8 m/s2
Was there ever a fault in the olympic games?
Yes, the sky fell on the chicken, causing a massive decline in the acceleration of the runners!
What does it mean a less massive object will speed up more quickly than a more massive object subjected to the same force?
For example, if you push a canoe for 10 seconds with a certain force, and if you push an ocean liner for 10 seconds with the same force, the canoe will be moving faster, because it has less mass.
