Air pressure keeps liquid molecules from escaping as a gas.
Air pressure keeps liquid molecules from escaping as a gas.
See the two Web Links listed to the left of this answer to find a chart of the standard barometric pressure at different altitudes (SableSys.com). Also, I've linked a very easy to use calculator to find the boiling point of water at any given barometric pressure (PrimoGrill.com). Just enter the pressure (the absolute pressure, not relative) and it gives you the boiling point!
As an example, here are the numbers under standard conditions for 7000 ft:
At 7000 ft, the standard barometric pressure is 23.088 inches Hg, and so water boils at 199.3 degrees Fahrenheit or 199.3 °F, which is equal to 92.94 degrees Celsius, or 92.94 °C. However, the pressure at 7000 feet will not always be exactly 23.088 in Hg (for instance, if a weather pattern changes the barometric pressure). It is more precise to specify the barometric pressure and ask the boiling point. Here is an equation to calculate the boiling point of water at any barometric pressure:
boiling point = 49.161 * Ln (Pressure in inches Hg) + 44.932
(where "Ln" is the natural logarithm in base e)
Here are other values for the boiling point of water a various barometric pressures and the approximatealtitudes that corresponds to under normal conditions.
31 in. Hg: 214 °F or 101.1 °C (at approx -1000 ft or -305 m below sea level)
30 in. Hg: 212.15 °F or 100 °C (at approx sea level)
29 in. Hg: 210.3 °F or 99.06 °C (at approx 1000 ft or 305 m above sea level)
28 in. Hg: 208.44 °F or 98.02 °C (at approx 2000 ft or 610 m above sea level)
27 in. Hg: 206.59 °F or 96.99 °C (at approx 3000 ft or 914 m above sea level)
25 in. Hg: 202.89 °F or 94.94 °C (at approx 5000 ft or 1524 m above sea level)
23 in. Hg: 199.19 °F or 92.88 °C (at approx 7000 ft or 2134 m above sea level)
21 in. Hg: 195.48 °F or 90.82 °C (at approx 10,000 ft or 3048 m bove sea level)
19 in. Hg: 191.78 °F or 88.77 °C (at approx 12,000 ft or 3658 m above sea level)
17 in. Hg: 188.07 °F or 86.71 °C (at approx 15,000 ft or 4572 m above sea level)
10 in. Hg: 175.11 °F or 79.51 °C (at approx 27,000 ft or 8230 m above sea level)
5 in. Hg: 165.85 °F or 74.36 °C (at approx 42,000 ft 12,802 m above sea level)
NOTE: These pressure values are absolute values, as opposed to relative. Many types of pressure gauges measure relative pressure (such as the ones used to measure the pressure in bicycle or car tires). However, a barometer measures the absolute pressure (as well as most electronic pressure gauges). If using a relative gauge, you to find the absolute pressure, you must subtract the outside air pressure from the relative reading (so you must already know the outside air pressure using a barometer).
More InfoThe boiling point of any substance is the temperature at which the liquid phase changes to the gas phase. The phenomenon called boiling is the formation of vapor bubbles within the liquid. Since heat must be applied from the environment to change a liquid into a gas, the container is hotter than the contents, and pockets of gas are generated which then rise to the surface and are dispersed.The ambient air pressure affects how fast the molecules of the liquid must be moving to leave the liquid phase and enter into the gas phase. As the pressure drops, the speed, therefore the amount of energy, needed gets less, so the temperature at which the substance boils lowers
By the way, the reason a microwave oven can boil water without the cup getting very how is that the microwave energy heats the water molecules directly. So, rather than heating the container which transfers energy to the contents of the pot, the contents heat to boiling and then transfer energy to the container
boiling point of any fluid affected by the the surrounding pressure , as it is a condition for reaching boiling point for any fluid that its vapor pressure must equal to surrounding pressure , so the if u are at the earth , so the atmospheric pressure is about 1.012 bar so ur fluid must exert vapor of pressure 1.012 bar to boil , so u need too much energy like water it boil at the earth at 100 c to be able to exert vapor of pressure 1.012 bar to make boiling , but is u r at amountain of 1500 m height u will notice that water will boil at lower temperature due to the height of air column decreased so its pressure decreased , so it will need lower energy to reach to boiling
It does not very significantly because melting does not involve gas-phases molecules. Boiling, on the other hand, is strongly affected.
See the Related Questions for how the boiling point of water is affected by air pressure.
The boiling point of water is determined by a combination of the air pressure and the temperature. The lower the air pressure, which goes down as you go up in elevation, the less heat is required to get the 'rolling boil' necessary.
As elevation increases, boiling point decrease.
Boiling point is the point at which atmospheric pressure equals vapor pressure. The vapor pressure of a substance is...In a liquid, there are always some particles that have enough energy to switch to the gas phase. There are also gaseous atoms of the liquid constantly returning to the liquid. The pressure exerted by the gas when the amount of particles leaving the liquid is in equilibrium with the amount of particles entering the liquid is called vapor pressure. As heat increases, more particles have enough energy to change to the gas phase, increasing the vapor pressure. When the vapor pressure equals atmospheric pressure, the liquid boils.
As elevation increases, atmospheric pressure decreases because air is thinner at higher altitudes. Because the atmospheric pressure is lower, the vapor pressure of the liquid needs to be lower to reach boiling point. Therefore, less heat is required to equal the vapor pressure to the atmospheric pressure, and the boiling point is lower at higher altitude.
Higher altitude had lower pressure and lower the boiling point.
For thermodynamics information, boiling is about when the vapour pressure equal to surrounding pressure. Since pressure increase with Temperature, reduce atmospheric pressure would required lower temperature to get water vapour pressure to equal with atmospheric pressure.
Increasing the pressure the boiling point is increased; decreasing the pressure the boiling point decrease.
Water boils when the vapor pressure of water equals total atmospheric pressure.
As air pressure drops, so does the boiling point.
In a vacuum, water boils at "room temperature".
The boiling point of water at this altitude is 84,2 oC.
Depends on the altitude of the location. In salt lake city, the altitude is about 4330 feet, which makes the water boiling point about 96 degrees Celsius (or 205F).
What is the hypothesis on how will adding different flavors of koolaid affect the boiling point of water
The boiling point is that temperature when the SATURATEDvapor pressure of a liquidbecomes equal tothe surrounding pressure.Thus the higher the sorrounding pressure, the higher the boiling point.
It does not affect the temperature of the water, but solutes raise the boiling point and lower the freezing point.
The boiling point of water decrease when the altitude increase; the value at Johannesburg is near 94 0C.
The boiling point of water is lower at high altitude; the freezing point is practically not affected.
The boiling point of water at this altitude is 84,2 oC.
Pressure & Temperature :) Apex
The boiling point of water decrease when the altitude increase and the atmospheric pressure decrease.
high altitude
In general, the higher the altitude, the lower the pressure, and the lower the pressure the lower the boiling point.
Depends on the altitude of the location. In salt lake city, the altitude is about 4330 feet, which makes the water boiling point about 96 degrees Celsius (or 205F).
Any material added to water raise the boiling point.
All you have to do to reduce the boiling point of water is go to a higher altitude and boil it.
What is the hypothesis on how will adding different flavors of koolaid affect the boiling point of water
by incresening the destiny of the product of water