55/2.5 = 22 (f=ma)
A force is not measured in kilograms. The kilogram is a unit of mass; forces are measured in newtons. You can get the force with Newton's Second Law. In this problem, you will need some additional information, specifically, the object's mass.
in the same direction as the net force, directly proportional to it, and inversely proportional to the object's mass.
Which object exerts more gravitational force, object A with a mass of 25 grams and a density of 2 g/cm3 or object B with a mass of 55 grams and a density of 0.5 g/cm3? Gravitational force is dependant on the mass and the mass alone. Object B mass 55 g will exert a force on say a mass of 1g at a say 1 meter over twice that of object A . In the gravitational field of earth one would weigh 55g and the other 25g As the gravitational force between two masses is is G X (M1 X M2)/R2 where R is the distance between them there is will be an attractive force between the two objects that that acts on both objects. In the absence of any other forces they will move towards each, g the 25 g object accelerating more quickly.
gravitational mass
Mass is the amount of matter in an object. Weight is the force of gravity on an object.
Hold on there. Mass doesn't control the force. Force controls the acceleration. As the mass of an object decreases, less force is required to produce the same acceleration. If the accelerating force is gravitational, that force will decrease. If it is not, then the force will not decrease.
If we neglect the effect of air resistance, an object is accelerating toward the ground at 9.8 m/s^2. When you determine an object's weight, you multiply its mass by this number. My point is that weight is the downward force on an object.
45000 m/ s squared
force=mass*accelaration force/mass=accelaration 4/2=2m/s2
No!! Force is how much work is being exerted on an object. NOT how much grav. pull (mass) or how much its accelerating (velocity)!
If the forces are balanced, the net force is zero. This also means that the object is not accelerating. (net force = mass x acceleration)
the rate of acceleration depends on mass and force , in the equation a= f/m ie halve the mass = twice the acceleration double the force = twice the acceleration
A force is not measured in kilograms. The kilogram is a unit of mass; forces are measured in newtons. You can get the force with Newton's Second Law. In this problem, you will need some additional information, specifically, the object's mass.
There is no minimum mass at which point an object (celestial or otherwise) begins to have a gravitational force. Any object with mass has an associated gravitational force. The magnitude of that force is proportional to to the mass of the object - lots of mass results in lots of gravitational force; little masses result in only little gravitational force.
Mass is the quantity of matter in an object. If an object is subject to an accelerating force, then it has weight. Your weight on the Moon will be about one-seventh of that on the Earth. Because of its much lower gravitational force.
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
Any falling object, or object that rolls downwards, can gain speed. This can easily be explained by Newton's Third Law: acceleration = force / mass. Force refers to the net force. So, as long as there is a net force downward, the object will continue accelerating. Only when the upwards forces (basically, friction) become as strong as the downward force of gravity will the object start accelerating. In that case, the object is said to have achieved "terminal velocity".