The force is determined by the machine or the muscle that's applying the force.
The mass of an object has no effect on it. You can easily apply the same force
to a battleship, a brick wall, or a little red wagon.
The response to the force (acceleration) is determined by the mass, and also by
any other forces that may also be acting on it at the same time.
When the distance between the two object increases the gravitational force increases because gravitational force is inversely proportional to distance and also the mass of the object increases than force also increases because this force is directly proportional to mass.
If the mass of an object increases, its gravitational field will become stronger. This is because the strength of the gravitational field is directly proportional to the mass of the object. The increased mass will result in a greater gravitational force exerted by the object on other objects around it.
No, the gravitational force between two objects is determined by their masses and the distance between them according to the universal law of gravitation. As the mass of an object increases, its gravitational force on other objects will also increase.
Gravitational force is directly proportional to the product of masses. So as mass is increased then force too increases
Well mass is the size of an object and if you have a large mass then you are heavy and if you have a smaller mass then yu are light. Mass affects the objects gravitational pull because if you have lrg mass then you weigh more cus of your size. and if you are small you can slip through air faster and if your mass is lrgr then you can sometimes be slower then the smaller mass. Ex. mice are fast and glide across the floor while elephants are large and dont get to places very fast bcus of there weit.
Acceleration is a net force that is inversely dependent on mass, therefore if an object mass increases ,acceleration decreases
F=ma, or force equals the product of mass and acceleration. Assuming that the mass of the object does not change, then acceleration increases as force increases.
The force of gravity is directly related to the mass of every object in the system. Therefore, if any object in the system decreases in mass, the force of gravity also decreases.
My bad, im asking why the formula isnt acceleration= force - mass
If your mass increases, your weight also increases.
Increasing mass increases the force because force is directly proportional to mass according to Newton's second law of motion (F=ma). Therefore, as mass increases, the force required to move or accelerate the object also increases.
I'm guessing this question relates to the formula Force=mass*acceleration. in this case if the mass stays the same, then Force and acceleration are directly proportional (if one goes up, then by mathematical law, the other one also has to)
If the force on an object increases, the acceleration of the object will also increase. This relationship is described by Newton's second law of motion, which states that the acceleration of an object is directly proportional to the net force acting on it.
They are directly related. As with Newton's second law, Force = mass times acceleration, you can see that as force increases, the mass increases and vice versa. F=m*a. If you keep the acceleration constant, then as the mass increases, the force will increase as well.
When the mass increases, the force required to accelerate the object also increases according to Newton's second law of motion, F = ma. This means that a greater force is needed to accelerate a heavier object at the same rate as a lighter object.
The force required to accelerate an object increases as the mass of the object increases. This relationship is described by Newton's second law of motion, which states that force is directly proportional to mass and acceleration. So, as mass increases, more force is needed to achieve the same acceleration.
If the force applied to a mass increases, its acceleration will also increase, assuming the mass stays constant. This is described by Newton's Second Law, (F = ma), where force is directly proportional to acceleration when mass is constant. Conversely, if the force decreases, the acceleration will also decrease as per the relationship defined by the law.