force directly proportional to acceleration. so F/a is remains constant. which is equal to mass of an object
No, acceleration is not directly proportional to weight. Weight is the force of gravity acting on an object, while acceleration depends on the net force acting on the object, which can be influenced by factors other than weight, such as friction or applied forces.
No. To have an acceleration, you need a non-zero NET FORCE. That is, the sum of all objects acting on the box must not be equal to zero.
According to Newton's 2nd law of motion, both the basketball and baseball would travel the same distance if equal force were applied to them. This is because the acceleration of an object is directly proportional to the force applied to it, assuming the masses of the two objects are the same.
Well, first let's look at what gravity is. If we consider "gravity" as gravitational force, then force=mass x acceleration, and mass x gravity does NOT equal acceleration. Acceleration is the change of velocity, so an object could accelerate without being affected by gravity, maybe just another force, like jet engines or something. Basically, no.
Newton's Second Law: force = mass x acceleration. Solving for acceleration: acceleration = force / mass. In other words, other things (i.e., the mass) being equal, the acceleration is proportional to the force.
When an objects net force is zero, its acceleration is zero. No force , no acceleration.
There is no reason it should be the same.Acceleration is the rate of change in velocity.To change acceleration a force is required and the change of acceleration depends on the force applied and the mass of the object on which the force is acting.
Firstly, force is equal to mass of the object into it's acceleration, so acceleration is not a force.Next, the change in velocity of a body over time is called acceleration, so yes, acceleration does affecta body's velocity.
The acceleration of an object is equal to the net force acting on the object divided by the object's mass. This relationship is described by Newton's second law of motion. It means that the greater the force applied to an object or the smaller its mass, the greater its acceleration will be.
The significance of the gravitational force (Fg) versus the acceleration due to gravity (g) in physics lies in their relationship. Gravitational force (Fg) is the force of attraction between two objects due to their mass, while acceleration due to gravity (g) is the acceleration an object experiences when falling under the influence of gravity. The value of acceleration due to gravity (g) is approximately 9.81 m/s2 on Earth. Understanding and calculating these forces are crucial in various physics applications, such as calculating the motion of objects, designing structures, and predicting the behavior of celestial bodies.
The force of friction between the two objects decreases their acceleration when they are moving against each other. Friction opposes the motion of the objects and reduces their acceleration by creating a resistive force that acts in the opposite direction to their movement.
The force that decreases the acceleration of two objects moving against each other is the force of friction. Friction acts in the opposite direction to the motion of the objects and reduces their acceleration by creating resistance.
I believe gravity would fit that description.
If you increase the force on an object acceleration increases . As F = m*a, where F = Force , m = mass of the object & a = acceleration
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