No, the density of a rubber stopper is less than the density of water. Rubber has a lower density compared to water, so a rubber stopper would float on water.
The volume of the stopper can be calculated by subtracting the initial volume of the water from the final volume. In this case, the volume of the rubber stopper would be 30.9 ml - 25 ml = 5.9 ml. Now, divide the mass of the rubber stopper (8.46 g) by its volume (5.9 ml) to find its density. Density = Mass/Volume, so the density of the rubber stopper would be 8.46g / 5.9ml = 1.43 g/ml.
No, rubber is denser than water, so a rubber stopper would sink in water.
From top to bottom, the order would be: cork, rubber stopper, mineral oil, water, mercury, and lead. This is based on the densities of the substances, with cork being the least dense and lead being the most dense.
To remove a glass stopper, start by gently tapping the sides with a rubber mallet to loosen it. Then, carefully twist the stopper while pulling it upwards to remove it from the bottle. If the stopper is still stuck, try using hot water to expand the glass before attempting to remove it again.
No, the density of a rubber stopper is less than the density of water. Rubber has a lower density compared to water, so a rubber stopper would float on water.
The volume of the stopper can be calculated by subtracting the initial volume of the water from the final volume. In this case, the volume of the rubber stopper would be 30.9 ml - 25 ml = 5.9 ml. Now, divide the mass of the rubber stopper (8.46 g) by its volume (5.9 ml) to find its density. Density = Mass/Volume, so the density of the rubber stopper would be 8.46g / 5.9ml = 1.43 g/ml.
No, rubber is denser than water, so a rubber stopper would sink in water.
Mercury Iron Carbon tetrachloride Rubber stopper Water Cork Oil Air You might want to think of something better than a rubber stopper; they tend to gum up and dissolve into the carbon tet layer after a while.
From top to bottom, the order would be: cork, rubber stopper, mineral oil, water, mercury, and lead. This is based on the densities of the substances, with cork being the least dense and lead being the most dense.
The buoyant force acting on the glass stopper in water is 0.4 N (2.4 N - 2 N). The buoyant force is equal to the weight of the water displaced by the stopper, so the volume of water displaced is 0.4 kg (0.4 N / 1000 N/kg). Using the formula density = mass/volume, the density of the glass stopper is 2400 kg/m^3 (2.4 kg / 0.001 m^3).
The water would have the same density anywhere it is.
Ice is less dense than liquid water.
Ice is less dense than liquid water.
It is greater than water. It sinks.
When inserting a glass tubing into a rubber stopper, make sure to wear gloves and safety goggles to protect against potential breakages. Lubricate the glass tubing with a small amount of glycerin or water to help it slide into the stopper smoothly. Hold the glass tubing securely and apply gentle pressure while inserting it to prevent breakage.
Average density of the object compare to density of water. If denser than water, it will sink.