Increasing the mass of an object means adding more material to it. For instance, you could increase the mass of a pillow by adding more feathers to the stuffing.
On Earth, where the gravitational constant is 9.8 m/s2, adding mass is roughly equivalent to adding weight. However, in physics, weight is a force and mass is a measure of quantity.
Increasing the mass of an object refers to adding more matter to the object, making it heavier. This can be done by adding more material to the object or by increasing the density of the material already present in the object.
Increasing the speed of an object does not affect that object's mass. Mass is an intrinsic property of an object and remains constant regardless of its speed.
You can increase the momentum of an object by either increasing its mass or its velocity. By increasing the mass of the object, the momentum will increase proportionally. Alternatively, increasing the velocity of the object will also increase its momentum.
Increasing the mass of an object will increase its inertia. Also, increasing the speed at which an object is spinning will increase its rotational inertia. Additionally, increasing the distance of an object from the axis of rotation will increase its rotational inertia.
No, increasing mass does not increase acceleration. Acceleration is dependent on the force applied to an object and the object's mass. In the equation F = ma, where F is the force, m is the mass, and a is the acceleration, increasing mass would actually decrease acceleration if the force remains constant.
The acceleration of an object can be increased by either increasing the force acting on the object or by decreasing the mass of the object.
Increasing the speed of an object does not affect that object's mass. Mass is an intrinsic property of an object and remains constant regardless of its speed.
You can increase the momentum of an object by either increasing its mass or its velocity. By increasing the mass of the object, the momentum will increase proportionally. Alternatively, increasing the velocity of the object will also increase its momentum.
Increasing the mass of an object will increase its inertia. Also, increasing the speed at which an object is spinning will increase its rotational inertia. Additionally, increasing the distance of an object from the axis of rotation will increase its rotational inertia.
increasing mass affects the force of objects in motion because it will slow the object down than its neighbor
No, increasing mass does not increase acceleration. Acceleration is dependent on the force applied to an object and the object's mass. In the equation F = ma, where F is the force, m is the mass, and a is the acceleration, increasing mass would actually decrease acceleration if the force remains constant.
This is a poorly stated question. What do you mean by size? Volume or mass? By your question, if all other factors are constant, increasing the size, (whatever you mean by that) will have no effect. If you mean that you have a mass at a certain temperature and you double the mass at that temperature, then the total energy doubles.
The acceleration of an object can be increased by either increasing the force acting on the object or by decreasing the mass of the object.
Increasing volume without increasing mass usually means the object becomes less dense. This can happen by adding air or expanding the space the object occupies. The mass remains the same, but the density decreases.
Increasing the speed of an object will increase its momentum as well (momentum=mass*velocity).
if you increase the mass of an object density is affected because now the object is MORE dense.
1)increasing the roughness of the surface 2)increasing the mass of the object
Since the force of gravity is directly proportional to mass, then increasing the mass of an object increases the force of gravity it produces.Since accceleration = force/mass, then increasing the mass of an object means it will have a smaller acceleration for the same force (or alternatively that you need more force to produce the same acceleration).