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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.
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.
When masss gets smaller inertia also gets smaller.
The greater the mass of an object the greater it's inertia The greater the mass of an object the greater it's inertia The greater the mass of an object the greater it's inertia
inertia just depends on mass. Big mass=hard to move.
Larger land mass, smaller than a comtinent
It would be smaller. The force on the particles will be the same. However, their bigger mass (inertia) will mean that their sideways acceleration is less than for lighter particles. They travel in a larger arc
A truck is heavier, has more mass. So at the same speed, the more massive object has more inertia. A scientific word for inertia is Momentum, defined as mass times speed, and is equal to force times time. So a 1 kilogram mass operated on by a 1 Newton force for 1 second would move at 1 metre per second and would have a momentum of 1 kg-N.
Inertia states that an object in motion will stay in motion unless another force acts against this object. The larger the mass the object has, the more force must be used to go against its movement. In this way, mass relates to inertia.
yes. gravitational force will act more powerfully on larger mass drop while on smaller mass drop less gravity acts.