4 times as great
mass moment of inertia for a solid sphere: I = (2 /5) * mass * radius2 (mass in kg, radius in metres)
The lower the frequency, the larger mass and longer length, The higher the frequency, the smaller the mass, and shorter the length.
No, an electron is MUCH smaller than a neutron. About 1/1836 or something like that. Just Google "mass of an electron".
four times the other's Because Rotational Inertia for a flywheel with its axis through the center is I=mr^2; I=m(2r)^2 I =m4r^2
no. Inertia is directly proportional to mass. So twice the mass, twice the inertia, etc. So, the larger the mass, the greater the inertia.
It depends on the object's mass.
The larger car has greater inertia because inertia is directly related to an object's mass. As mass increases, so does inertia. Therefore, the larger car moving at the same speed as the smaller car would have greater inertia.
Inertia decreases as mass gets smaller. Inertia is a measure of an object's resistance to changes in its state of motion, and is directly proportional to mass. As mass decreases, so does the inertia of the object.
Inertia is directly related to mass. More mass means more inertia.
By Newton's first law of motion, it can be concluded that inertia of an object is inversely proportional to the mass of the object. In other words, larger the mass smaller the inertia and vice-versa.
The inertia of a body is affected by its mass and distribution of mass, where more mass or mass distributed farther from the axis of rotation leads to greater inertia. Additionally, the shape and size of a body can also influence its inertia, where elongated or larger bodies typically have greater inertia compared to smaller or compact bodies.
It is easier to change the motion of an object with a smaller mass because it has less inertia, which is the tendency of an object to resist changes in its motion. Objects with larger mass have more inertia and resist changes in motion more strongly. This means it takes more force to change the motion of an object with a larger mass compared to one with a smaller mass.
the force required to accelerate it, according to Newton's second law of motion (F = ma). This means that objects with larger mass require more force to achieve the same acceleration as objects with smaller mass.
A larger and heavier ball would have greater inertia compared to a smaller and lighter ball. Inertia is the tendency of an object to resist changes in its motion, so objects with more mass will have greater inertia.
An object with greater mass has greater inertia. This means that an object with a larger mass will have the greatest inertia.
A larger mass has greater inertia than a smaller mass. Inertia is the resistance of an object to changes in its motion, and it is directly proportional to the mass of the object. Therefore, the larger the mass, the greater the inertia.