0.961 g/mL
I have no clue. Sorry. :( ^^ Ignore that ^^ I think Density = mass/volume.
Its density. Density is mass per unit volume.
Mass and volume are extensive properties, which are dependent upon the size of the sample. A larger sample will have a greater mass and volume than a smaller sample. Density is an intensive property, which does not depend on the size of the sample. Density is a ratio of mass to volume, which does not vary with the size of the sample. The density of a larger sample will be the same as the density of a smaller sample.
density = mass / volume
Two measurements are needed - you must find its mass and its volume. Density is mass divided by volume.
I have no clue. Sorry. :( ^^ Ignore that ^^ I think Density = mass/volume.
Volume of a sample = (its mass) divided by (its density)
Its density. Density is mass per unit volume.
Density of a substance = (mass of a sample of it)/(volume of the same sample)
You have to know two out of three ... mass, volume, density ... then you can find the missing one. If density is missing . . . Density = (mass)/(volume) If mass is missing . . . Mass = (density) x (volume) If volume is missing . . . Volume = (mass)/(density)
Density = mass / volume As sample size increases, both mass and volume increase in the same ratio.
its density
The density is the ratio between the mass and the volume of a sample.
-- Get a piece of the material. It doesn't matter what size it is. -- Measure the mass of the sample. -- Measure the volume of the sample. -- Divide the mass by the volume. The result is the density of the material.
The volume of the sample whose mass is 20 g and density is 4 g/ml is 5 milliliters.
density= mass/volume 30g/7500cm3=.004g/cm3
Mass and volume are extensive properties, which are dependent upon the size of the sample. A larger sample will have a greater mass and volume than a smaller sample. Density is an intensive property, which does not depend on the size of the sample. Density is a ratio of mass to volume, which does not vary with the size of the sample. The density of a larger sample will be the same as the density of a smaller sample.