At a given temperature there is a certain maximum level of water vapour in air, any more and it will condense out. That maximum goes up with temperature. That is your 100%. Lower amounts can be quoted as percentage of the maximum.

Technically it can be any gas or none, its the maximum amount of water in a given volume, called the saturated vapour pressure.

Cooler air doesn’t like to hold water.

Warmer air likes to hold water.

100% humidity means that air can’t hold more water.

Then, you can’t cool off by donating your heat/sweat to the air.

Cooler air doesn’t like to hold water.

Warmer air likes to hold water.

100% humidity means that air can’t hold more water.

Then, you can’t cool off by donating your heat/sweat to the air.

At a given temperature there is a certain maximum level of water vapour in air, any more and it will condense out. That maximum goes up with temperature. That is your 100%. Lower amounts can be quoted as percentage of the maximum.

Technically it can be any gas or none, its the maximum amount of water in a given volume, called the saturated vapour pressure.

At a given temperature there is a certain maximum level of water vapour in air, any more and it will condense out. That maximum goes up with temperature. That is your 100%. Lower amounts can be quoted as percentage of the maximum.

Technically it can be any gas or none, its the maximum amount of water in a given volume, called the saturated vapour pressure.

Cooler air doesn’t like to hold water.

Warmer air likes to hold water.

100% humidity means that air can’t hold more water.

Then, you can’t cool off by donating your heat/sweat to the air.

When you see someone say “80% relative humidity” that just means the air is at 80% capacity of how much water it can hold. At 100% evaporation will be essentially stopped, while at 0%, condensation cannot occur. For reference, maximal humidity doesn’t really go over 5% of the actual composition of the air.

When you see someone say “80% relative humidity” that just means the air is at 80% capacity of how much water it can hold. At 100% evaporation will be essentially stopped, while at 0%, condensation cannot occur. For reference, maximal humidity doesn’t really go over 5% of the actual composition of the air.

When you see someone say “80% relative humidity” that just means the air is at 80% capacity of how much water it can hold. At 100% evaporation will be essentially stopped, while at 0%, condensation cannot occur. For reference, maximal humidity doesn’t really go over 5% of the actual composition of the air.

It’s not quite that air has a fixed amount of water it can hold. At the point where liquid water touches air, there are two things going on; some of the liquid molecules have enough energy to escape and become gas, and some gas water molecules hit the surface of the water and go back to being a liquid. The hotter the environment, the more likely the liquid molecules are to evaporate. The more water there is in the air, the more likely a gas water molecule will hit the surface and go back to being a liquid.
Because the rates of those processes are difficult to measure, we measure the vapor pressure as a stand-in for the rate of evaporation, and the partial pressure of water as a stand-in for the rate of condensation. Relative humidity is how those two pressures relate to each other; a partial pressure of 10% means that the partial pressure of water in the air is 10% the vapor pressure of water at that temperature.
Over 100% humidity means that water is condensing faster than it is evaporating. This is when fog happens; the water in the air starts to condense with itself to form small water droplets. However, this condensation does take time, so the atmosphere does spend some time over 100%