no, water is lighter than mercury
No, the volumes of Mercury and water are not the same. Mercury is denser than water and will occupy less volume for an equivalent mass.
No, water and vinegar weigh the same in equal volumes. Vinegar is a mixture of water and acetic acid, so the weight of the two substances in equal volumes would be the same.
The density of water is 1 g/cm3 and the density of mercury is 13.6 g/cm3. To find the volume of water that would weigh the same as 150 cm3 of mercury, you would use the equation: mass = density x volume. Since the two substances have different densities, you cannot directly compare their volumes in this way.
The reaction between hydrogen and oxygen to form water is given by the equation: 2H2 + O2 -> 2H2O. This means that 2 volumes of hydrogen react with 1 volume of oxygen to produce 2 volumes of water vapor. Therefore, from 10 volumes of hydrogen and 5 volumes of oxygen, 10 volumes of water vapor can be produced.
Both 3 kg and 7 kg of water have the same density because the density of water is constant at approximately 1000 kg/m^3 regardless of the amount of water.
Water, oil, and mercury are arranged in increasing order of density. Water is less dense than oil, which is less dense than mercury. So the order would be water (less dense), oil, and then mercury (most dense).
The level of saltiness in the oceans can vary depending on factors such as evaporation, precipitation, and river runoff. Salinity can be higher in regions where evaporation is high and lower in areas with more rainfall or freshwater input from rivers. This variability results in different salinity levels in different locations within the oceans.
Both 3 kg and 7 kg of water have the same density because the density of water is constant at approximately 1000 kg/m^3 regardless of the amount of water.
There's no such thing as "mercury vacuum". A volume of space can have solid mercury, liquid mercury, or mercury vapor in it, or it can be a vacuum. The weight of the "standard atmosphere" on any area is the same as the weight of a column of mercury 29.92 inches high on that same area, with no air above the mercury.
Dispersing pollutants in larger volumes of water is called dilution.
The density of mercury is 13.534, compared to '1' for water. So the water columnis 13.534 times as high as the mercury column at the same pressure.(30 inches of water) x (25.4 millimeters/inch) / 13.534 = 56.3 millimeters of mercury
Diameter of Mercury is 3031 miles; mass 3.250x1020. Diameter of Earth is 7926 miles (at Equator); mass 5.288x1021. Earth's mass is therefore about 16 times that of Mercury. Volumes can be calculated from diameters.
You can separate oxygen from a mixture of oxygen and ammonia by a process called fractional distillation. This involves heating the mixture to separate the components based on their boiling points, as oxygen has a lower boiling point than ammonia. By selectively distilling off the oxygen gas, it can be collected and separated from the ammonia.
The result of mixing equal MASSES of water at different temperatures will be the mean of the two temperatures. Unless you are being very sophisticated and are taking the thermal expansion into account, the same will apply to volumes.
The reason the cinder block sinks in water is because its density is higher than that of water. In contrast, mercury is denser than the cinder block, causing it to float in mercury due to the principle of buoyancy—objects with lower density than the fluid they are in will float.
Mercury is used in thermometers because it expands and contracts uniformly with temperature changes, providing accurate measurements. Additionally, mercury has a high boiling point, allowing for use in a wide temperature range. Colored water would not provide as precise measurements due to its variable expansion rates with temperature.
in mercury the molecules are closser with respect to the molecular structure of the water. so when both of them are heated , there will be more molecular collision in mercury than in water. that's why , when both of them are heated to the same extend mercury produces more heat than water.
The volume of water displaced will be the same for both the lead and glass samples, regardless of their densities or masses. This is because the volume of water displaced is equal to the volume of the object submerged. Thus, both the lead and glass samples will displace 1.0 cm3 of water each.