no the mass of the object would not even be able to calculate the measurment of density
Adding mass may increase or decrease the density if the substance added is different. Merely changing the mass will not affect the density.
Mass divided by volume equals density. For the same volume, if the mass is more then the density is higher.
If the distance remains constant between the center of mass in question and an alternate center of mass, the density of either mass will not affect the gravitational force between the two centers of mass.
By definition, Density = mass/volume If the mass is increased (as you stipulated) and assuming the volume remains the same, the density will likewise increase.
It will increase the total volume, but it will hardly affect total mass. Remember the definition of density as mass / volume.
If the mass increases, the density decreases. If the mass decreases, the density decreases.
Adding mass may increase or decrease the density if the substance added is different. Merely changing the mass will not affect the density.
Density=mass/volume
volume does affect the density because the formula of density= mass/ volume
Because density is DEFINED as mass/volume.
Mass divided by volume equals density. For the same volume, if the mass is more then the density is higher.
The density of a substance is its mass divided by its volume. So for the same volume the higher the mass, the higher the density.
Density is mass/volume. So for a given mass as the volume increases the density will reduce.
If the distance remains constant between the center of mass in question and an alternate center of mass, the density of either mass will not affect the gravitational force between the two centers of mass.
Density is mass/volume. So for a given mass as the volume increases the density will reduce.
By definition, Density = mass/volume If the mass is increased (as you stipulated) and assuming the volume remains the same, the density will likewise increase.
Yes, both do. Density = Mass/Volume, So density is directly proportional to mass and inversely proportional to volume.