To find the volume of gas produced by 36g of water, you would need to know the chemical reaction involved. When water decomposes, it produces hydrogen gas and oxygen gas. The ideal gas law (PV = nRT) can be used to calculate the volume of gas produced if you know the moles of the gas produced and the conditions (pressure and temperature) under which the reaction occurs.
Water displacement is used to find the volume of irregularly shaped solids because when the solid is immersed in water, it displaces an amount of water equal to its volume. By measuring the change in water level before and after immersing the solid, you can calculate the volume of the solid.
To find the volume of the bottle, you need to subtract the weight of the water from the total weight of the bottle and water. Then, divide this difference by the density of water to find the volume displaced by the water and consequently the volume of the bottle.
Well, darling, to find the volume of 100mL of water, you simply measure out 100mL using a graduated cylinder or measuring cup. The volume of the water is already given to you as 100mL, so there's no need to do any calculations. Just pour yourself a drink and enjoy!
To find the volume of the alloy, use the formula for density: Density = Mass / Volume. First, calculate the volume of water displaced by the alloy when immersed: Volume of water displaced = Mass in air - Mass in water. Then, use the density of water (1g/cm^3) to find the volume, as the volume of water displaced equals the volume of the alloy. Finally, calculate the density of the alloy by dividing its mass by the volume obtained.
The density is the ratio between mass and volume.
To find the volume of an irregularly shaped object that would dissolve in water, you can use the water displacement method. Fill a known volume of water in a container, note the initial water level, then submerge the object in the water and measure the new water level. The difference in water levels is the volume of the object.
using water displacement method
You can find the volume of an irregularly shaped object, like a rock, by using the water displacement method. Submerge the object in a known volume of water in a container. Measure the increase in water level, which equals the volume of the rock.
When you are trying to find the volume of an irregularly shaped object.
water displacement
To find the density of an object, you would use a graduated cylinder to find the volume of the object by water displacement. By subtracting the initial water volume from the final water volume, you can determine the volume of the object. Density is then calculated by dividing the object's mass by its volume.
You can find the volume of the irregular cork by immersing it in a known volume of water and measuring the amount the water level rises. The volume of water displaced is equal to the volume of the cork.
Water A measuring tape and a calculator
To find the density of an irregularly shaped object like a rock, you can use the water displacement method. First, measure the volume of water displaced when the rock is submerged in a known volume of water. Then, divide the mass of the rock by the volume of water displaced to calculate the density.
To find the density of a quarter, you would first measure its mass using a scale. Then, you would measure its volume by water displacement, where you would measure the amount of water the quarter displaces when submerged. Finally, divide the mass by the volume to calculate the density of the quarter.
Yes, water displacement can be used to find the volume of solid objects that do not dissolve in water. By measuring the change in water level before and after submerging the object, you can calculate its volume based on the amount of water displaced.
First, if it happened to be a floating soap, it would have to be forced down to displace its full volume of water. Otherwise, it would only displace its own weight of water. Whatever tool was used to force it down also would have volume, and its volume would have to be subtracted from the volume of water displaced. Second, since soaps are made so that they break down in the presence of water, part of its volume would be lost to the water and would have to be accounted for: both the portion that remained in the water container (no problem), and more problematic, the portion that flowed out.