The boiling point of water at 5 895 m (Kilimanjaro Mountain) is 79,52 0C.
As a liquid is under more and more pressure it's boiling point gets higher and higher. This is because it take more energy to move the molocules in a closed space. The opposite effect can be seen when water is placed in a vaccuum. If strong enough, the water can boil at room temperature because it's boiling point gets so low. The boiling point will increase. The reverse is also true. The boiling point of water on top of Mt. Everest is around 70 degrees celcius because the pressure is so low.
The boiling point is lower on the top of Mt. Everest because the atmospheric pressure at higher altitudes is lower than at sea level. As a result, water molecules can escape into the air more easily, requiring less heat energy to reach the boiling point.
The boiling point of water decreases at higher elevations where atmospheric pressure is lower. This is because the lower pressure makes it easier for water molecules to escape into the air, requiring less energy to reach the boiling point.
Higher pressure increases boiling point. This means that as the pressure increases, the liquid must become hotter to boil. From a theoretical point of view, with the water being heated equally throughout, the water at the top of the pot would boil first because it is under less pressure than the water at the bottom.
As pressure decreases, the boiling point of water will also decrease. Backpackers camping in the high mountains are familiar with the phenomena when they get water boiling - and find that it is still only lukewarm because the atmospheric pressure at their high altitude is so low.
1800degrees celsius
At sea level the boiling temperature of water is 212o Fahrenheit. At different air pressures the boiling temperature changes. Higher air pressures require higher temperatures to boil. For example, if you go to a mountain top you could lower air pressure until water could boil at say 99o Fahrenheit. If you change substances, from water to something else, that substance would have its own individual boiling temperature, the point at which it changes from liquid to gas.
That depends, the boiling point of water changes with altitude. As you go higher, the boiling temperature decreases. At sea level, the boiling point of water is 212° F (100° C). As a general rule, the boiling point temperature decreases by 1 degree F for every 540 feet of altitude (0.56° C for every 165 meters). On top of the 14,000 foot Pike's Peak, for example, the boiling point of water is only 187° F (86° C).
AnswerImpurities tend to increase the boiling point and lower the freezing point.in a way boiling point of salty water > boiling point of fresh waterfreezing properties of salty water < freezing properties of fresh watermelting properties of salty water < melting properties of fresh water.Salt water, contains NaCl, which ionizes into Na and Cl ions. when ions are added to a solvent, such as water, they tend to increase the boiling point and lower the melting point.
Boiling point of water is inversely proportional to atmospheric pressure, which depends on altitude and weather. Higher altitude, lower boiling point. Water boils at 100 C at sea level. Go below sea level (ocean level) to the Dead Sea and the boiling point will actually be greater than 100 C.
As a liquid is under more and more pressure it's boiling point gets higher and higher. This is because it take more energy to move the molocules in a closed space. The opposite effect can be seen when water is placed in a vaccuum. If strong enough, the water can boil at room temperature because it's boiling point gets so low. The boiling point will increase. The reverse is also true. The boiling point of water on top of Mt. Everest is around 70 degrees celcius because the pressure is so low.
The boiling point is lower on the top of Mt. Everest because the atmospheric pressure at higher altitudes is lower than at sea level. As a result, water molecules can escape into the air more easily, requiring less heat energy to reach the boiling point.
The boiling point of water decreases at higher elevations where atmospheric pressure is lower. This is because the lower pressure makes it easier for water molecules to escape into the air, requiring less energy to reach the boiling point.
im not sure but im pretty sure it is neither. it is your face.
Higher pressure increases boiling point. This means that as the pressure increases, the liquid must become hotter to boil. From a theoretical point of view, with the water being heated equally throughout, the water at the top of the pot would boil first because it is under less pressure than the water at the bottom.
Water boils faster at sea level because there is higher atmospheric pressure, which increases the boiling point of water. At higher altitudes, such as on top of a mountain, the lower atmospheric pressure causes water to boil at a lower temperature, which means it takes longer to boil.
Pressure is much lower at the top of Mount Everest. PV=nRT. If pressure, P, goes down, then T, temperature, goes down. More temperature must be added.