No, the gravel sinks when placed in water and is therfore more dense than water. This means that given two equivalent volumes one of water , one of gravel, the mass of the gravel will be greater than that of the water.
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∙ 16y agoNo, they do not have the same mass. Gravel is much denser than water, so 100 ml of gravel will have a greater mass than 100 ml of water.
To find the mass of the beaker with water, you would need to know the mass of the empty beaker and the density of water. The mass of the water can be calculated by multiplying the volume of water (100 mL) by the density of water. Finally, add the mass of the empty beaker to the mass of the water to get the total mass of the beaker with water.
To find the mass of 100 ml of water, you can use the density of water, which is approximately 1 gram per milliliter. Therefore, the mass of 100 ml of water would be 100 grams.
The mass of the gas will still be 100 grams, as mass is conserved during phase changes. When water evaporates, it changes from a liquid to a gas but the total mass remains the same.
To find water by mass in a compound, you can calculate the difference in mass before and after heating the compound to drive off the water. The lost mass represents the mass of water present in the compound. You can then calculate the percentage of water in the compound by dividing the mass of water by the total mass of the compound and multiplying by 100.
The total amount of substance will remain the same when 100 grams of ice melt into water. Only the physical state of the substance changes from solid (ice) to liquid (water), but the mass remains constant.
Yes, the mass of 100 grams of water will remain the same regardless of changes in temperature. Mass is a measure of the amount of matter in an object, and it does not change with temperature variations.
The mass of 100 ml of water is approximately 100 grams. Water has a density of 1 gram per milliliter, so for every 1 ml of water, the mass is 1 gram.
To find the percent by mass of sugar: Mass of sugar = 35.8g Total mass of solution = 35.8g (sugar) + 125.35g (water) = 161.15g Percent by mass of sugar = (mass of sugar / total mass of solution) * 100 To find the percent by mass of water: Mass of water = 125.35g Total mass of solution = 161.15g (as calculated above) Percent by mass of water = (mass of water / total mass of solution) * 100
To find the mass of the beaker with water, you would need to know the mass of the empty beaker and the density of water. The mass of the water can be calculated by multiplying the volume of water (100 mL) by the density of water. Finally, add the mass of the empty beaker to the mass of the water to get the total mass of the beaker with water.
If all the water boils off, the mass of the steam will be 100 grams. Matter cannot be created or destroyed.
Pure water, standard temperature and pressure, etc. Mass of 100 ml of water = 100 grams
If you have pure water, standard temperature, and standard pressure,then 100 milliliters of water has 100 grams of mass.(Note: 'milliliters', not 'millimeters'.)
Find the mass of an empty container using a balance. Fill the container with 100 ml of water and measure the mass again, The difference between the two measurements is the mass of 100 ml of water.
100g of water has a greater volume than 100g of gold. This is because the density of gold is higher than the density of water, so the same mass of gold occupies less space than the same mass of water.
Steam at 100 C and liquid water at 100 C both have the same amount of heat energy per gram because they are both at their boiling point and are in thermal equilibrium. The heat energy is used to break the intermolecular forces holding the water molecules together, rather than increasing the temperature.
The mass of 100 millimeters of water is approximately 100 grams. This is because the density of water is very close to 1 gram per milliliter. Therefore, 100 milliliters of water would weigh around 100 grams.
Measure the amount of water: by volume or mass or whatever. Measure the total amount in the same units. Divide the first by the second and then multiply by 100.