Yes, water has mass. All matter, of which water is one kind, has mass.
Mass movements of water are called currents. This is equally true for surface water or deeper water.
The mass of water does not increase when copper sulfate is added to the water, unless the copper sulfate is hydrated. The mass of the mixture of water and copper sulfate, of course, does increase.
A warm air mass and a cold air mass holds the same amount water vapor but the air mass is smaller
55.91% The mass of NaSo4 is 142.05 plus the mass of 10 H2O molecules (180.16) is 332.21. Divide the mass o water overthe total mass to get .5591 or 55.91%
Hello,Ice does have the same mass as water before it melts. You can (almost) never lose or gain mass without adding orsubtractingmass from the system. Mass just can't appear ordisappearfromnowhere.According in water the volume that ice occupies is greater than that of water due to the arrangements of the molecules of ice. This is why you would be led to thinkthereis a change in mass.However, according to this Law of conservation of mass, the number of particles in an ice cube and water are the same. Only the state has changed, not the mass.
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
3.6
mass of liqid water before evaporation=mass of liquid water after evaporates + mass of gaseous water.
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 mass of water is 1g per cm3
because when it contain water the mass of water will be the one to be obtained
4 kg is the mass of the water. Thus, 4 kg of water has a mass of 4 kg.
No
The mass and the volume of the water are directly proportional. When the volume of water increased, the mass of water increased too and vice versa. Because when we divide the mass and the volume of water, we get the constant value called density of water.
The mass of 2 moles of water is 36 g.
As the more energetic form of water -- water vapor -- is formed, the liquid water chills. Thus conservation of energy is preserved. Mass of course remains the same.
The volume of water is the same as the mass of water. So if you have 100ml of water you actually have 100g of water.