1 kg.
4 kg is the mass of the water. Thus, 4 kg of water has a mass of 4 kg.
The pumpkin's mass is 4.8 kg, and 0.9 of its mass is water. This means 0.1 of its mass is not water. To find the mass of water: 4.8 kg x 0.9 = 4.32 kg of water To find the mass of not water: 4.8 kg - 4.32 kg = 0.48 kg of not water
Full mass = 52.2 kgEmpty mass = 3.64 kgFull mass = (MT mass) + (water mass)52.2 = (3.64) + (water mass)Water mass = 52.2 - 3.64 = 48.56 kg
The buoyant force on the iceberg when the 360 kg mass is placed on it is equal to the weight of the added mass. We can use the concept of relative density (or specific gravity) to find the mass of the iceberg, knowing that it displaces its own weight in water. By applying the principle of buoyancy, we can calculate the iceberg's mass to be around 400 kg.
10 kg of mass is equivalent to 10 liters of water, assuming the water has a density of 1 kg/L.
Assuming that the water in the can is pure water (ie. with a specific gravity of 1) then the mass of the water in the can is 5.5kg (1L of pure water has a mass of 1kg), leaving the mass of the can to be 850g.
The formula to find the mass of water is: mass = volume x density Where: volume is the amount of water in liters or cubic meters density of water is approximately 1 g/cm³ or 1000 kg/m³
Mass is THE AMOUNT OF MATTER IN AN OBJECT.
472 kg refers to mass, which is a measure of the amount of matter in an object.
The mass of water that will occupy 1.5 L of volume is 1.5 kg. The density of water is 1 kg/L, so 1.5 L of water would have a mass of 1.5 kg.
The ratio of mass / volume is called density. Example: Water has a density of 1 kg/liter, 1 gram/cm3, or (to use SI units) 1000 kg/m3.
Yes, a 2 kg iron brick has twice as much mass as a 1 kg iron brick. Mass is a measure of the amount of matter in an object, so doubling the mass means doubling the amount of matter present in the object.