Dew point

The dew point is the temperature to which a given parcel of air must be cooled, at constant barometric pressure, for water vapor to condense into water. The condensed water is called dew. The dew point is a saturation point.

When the dew point temperature falls below freezing it is often called the frost point, as the water vapor no longer creates dew but instead creates frost or hoarfrost by deposition.

The dew point is associated with relative humidity. A high relative humidity indicates that the dew point is closer to the current air temperature. Relative humidity of 100% indicates that the dew point is equal to the current temperature (and the air is maximally saturated with water). When the dew point stays constant and temperature increases, relative humidity will decrease.

At a given barometric pressure, independent of temperature, the dew point indicates the mole fraction of water vapor in the air, and therefore determines the specific humidity of the air.

The dew point is an important statistic for general aviation pilots, as it is used to calculate the likelihood of carburetor icing and fog, and estimate the height of the cloud base.

Explanation

The graph above shows the maximum percentage (by mass) of water vapor that can exist in air at sea level across a range of temperatures. The behavior of water vapor does not depend on the presence of other gases in air. The formation of dew would occur at the dew point even if the only gas present is water vapor.

Constant pressure

At a given barometric pressure, independent of temperature, the dew point indicates the mole fraction of water vapor in the air, or, put differently, determines the specific humidity of the air. If the barometric pressure rises without changing this mole fraction, the dew point will rise accordingly, and water condenses at a higher temperature. Reducing the mole fraction, i.e. making the air dryer, will bring the dew point back down to its initial value. In the same way, increasing the mole fraction after a pressure drop brings the dew point back up to its initial level. For this reason, the same dew point in New York, NY and Denver, CO (which is at a much higher altitude) will imply that a higher fraction of the air in Denver consists of water vapor than in New York.

Varying pressure

At a given temperature but independent of barometric pressure, the dew point indicates the absolute humidity of the air. If the temperature rises without changing the absolute humidity, the dew point will rise accordingly, and water condenses at a higher pressure. Reducing the absolute humidity will bring the dew point back down to its initial value. In the same way, increasing the absolute humidity after a temperature drop brings the dew point back up to its initial level. Coming back to the New York - Denver example, this means that if the dew point and temperature in both cities are the same, then the mass of water vapor per cubic meter of air will also be the same in those cities.

Human reaction to high dew points

Humans tend to react with discomfort to a high dew point (> 60 °F). The body perspires and produces sweat to cool down. High relative humidity and consequently high dew point, prevent the evaporation of sweat and reduce evaporative cooling. As a result, the body may overheat, resulting in discomfort.

Discomfort also exists when dealing with low dew points. The drier air can cause skin to crack and become irritated more easily.

Lower dew points (< 50 °F) correlate with lower ambient temperatures, and the body requires less cooling. A lower dew point can go along with a high temperature only at extremely low relative humidity (see graph below), allowing for relative effective cooling.

Those accustomed to continental climates often begin to feel uncomfortable when the dew point reaches between 15 and 20 °C (59 to 68 °F). Most inhabitants of these areas will consider dew points above 21 °C (70 °F) to be oppressive.

Dew Point °C	Dew Point °F	Human Perception	Rel. Humidity at 90°F (32.2°C)
>24°C	>75°F	Extremely uncomfortable, pretty oppressive	62%
21 - 24°C	70 - 74°F	Very humid, quite uncomfortable	52% - 60%
18 - 21°C	65 - 69°F	Somewhat uncomfortable for most people at upper edge	44% - 52%
16 - 18°C	60 - 64°F	OK for most, but all perceive the humidity at upper edge	37% - 46%
13 - 16°C	55 - 59°F	Comfortable	31% - 41%
10 - 12°C	50 - 54°F	Very comfortable	31% - 37%
<10°C	<49°F	A bit dry for some	30%

^[1]

Extreme dew points

A dew point of 35 °C (95 °F) was reported in Dhahran, Saudi Arabia at 3 p.m. July 8, 2003. The temperature was 42 °C (108 °F), resulting in an apparent temperature or heat index of 80 °C (176 °F).^[2]

Calculating the dew point

Graph of the dependence of the dewpoint upon air temperature for several levels of relative humidity. Based on the August-Roche-Magnus approximation.

A well-known approximation used to calculate the dew point T_d given the relative humidity RH and the actual temperature T of air is:

${\displaystyle T_{d}={\frac {b\ \gamma (T,RH)}{a-\gamma (T,RH)}}}$

where

${\displaystyle \gamma (T,RH)={\frac {a\ T}{b+T}}+\ln(RH/100)}$

where the temperatures are in degrees Celsius and "ln" refers to the natural logarithm. The constants are:

a = 17.271

b = 237.7 °C

This expression is based on the August-Roche-Magnus approximation for the saturation vapor pressure of water in air as a function of temperature.^[3] It is considered valid for

0 °C < T < 60 °C

1% < RH < 100%

0 °C < T_d < 50 °C

Simple approximation

There is also a very simple approximation which allows conversion between the dew point, the dry bulb temperature and the relative humidity, which is accurate to within about ±1 °C as long as the relative humidity is above 50%.

The equation is:

${\displaystyle T_{d}=T-{\frac {(100-RH)}{5}}}$

or

${\displaystyle RH=100-5(T-T_{d}).}$

This can be expressed as a simple rule of thumb:

For every 1 °C difference in the dew point and dry bulb temperatures, the relative humidity decreases by 5%, starting with RH=100% when the dew point equals the dry bulb temperature.

where in this case RH is in percent, and T and T_d are in degrees Celsius.

The derivation of this, a discussion of its accuracy, comparisons to other approximations, and more information on the history and applications of the dew point are given in the Bulletin of the American Meteorological Society ^[4].

In Fahrenheit.

${\displaystyle Tf_{d}=Tf-{\frac {(100-RH)}{2.778}}}$

For example, a relative humidity of 100% means dew point is same as air temp. For 90% RH dew point is 3 degrees Fahrenheit lower than air temp. For every 10 percent lower, dew point drops 3 °F.

TF_d is in degrees Fahrenheit; RH same as above.

Closer approximation

A calculation used by the NOAA is:^[5]

${\displaystyle e_{s}=6.112\exp \left({17.67T \over T+243.5}\right)}$

${\displaystyle e_{w}=6.112\exp \left({17.67T_{w} \over T_{w}+243.5}\right)}$

${\displaystyle e=e_{w}-p_{sta}\left(T-T_{w}\right)0.00066\left[1+(0.00115T_{w})\right]}$

${\displaystyle RH=100{e \over e_{s}}}$

${\displaystyle T_{d}={243.5\log(e/6.112) \over 17.67-\log(e/6.112)}}$

where:

RH is relative humidity and ${\displaystyle T_{d}}$ is dew point in degrees Celsius

${\displaystyle T}$ and ${\displaystyle T_{w}}$ are the dry-bulb and wet-bulb temperatures respectively in degrees Celsius

${\displaystyle e_{s}}$ is the saturated water vapor pressure, in units of millibar, at the dry-bulb temperature

${\displaystyle e_{w}}$ is the saturated water vapor pressure, in units of millibar, at the wet-bulb temperature

${\displaystyle e}$ is the actual water vapor pressure, in units of millibar

${\displaystyle p_{sta}}$ is "station pressure" (absolute barometric pressure at the site that humidity is being calculated for) in units of millibar (which is also hPa).

for greater accuracy use the Arden Buck Equation to find the water vapor pressures

Dewpoint in coating applications

Dewpoint measurement is one of the most critical analysis performed during in field application of paint systems. TQC is the original invertor of the dewpoint gauge specially redesigned for the coating industry. Since the introduction of the Dewcheck it is the mostly used gauge for dewpoint measurement in the coating industry.

See also

• Thermodynamic diagrams
• Carburetor heat
• Heat index
• Hydrocarbon dew point
• Dewcheck

References

1. Horstmeyer, Steve (2006-08-15). "Relative Humidity....Relative to What? The Dew Point Temperature...a better approach". Steve Horstmeyer, Meteorologist, WKRC TV, Cincinnati, Ohio, USA.
2. Burt, Christopher C. Extreme Weather: A Guide & Record Book. W. W. Norton & Company. ISBN 0393326586. {{cite book}}: External link in |title= (help)
3. "MET4 AND MET4A CALCULATION OF DEW POINT". Paroscientific, Inc. 4500 148th Ave. N.E. Redmond, WA 98052. 2007-09-13.
4. M. G. Lawrence, "The relationship between relative humidity and the dew point temperature in moist air: A simple conversion and applications", Bull. Am. Meteorol. Soc., 86, 225-233, 2005
5. http://www.srh.noaa.gov/epz/wxcalc/formulas/rhTdFromWetBulb.pdf

External links

• Free Windows Program, Dewpoint Units Conversion Calculator - PhyMetrix
• Free dewpoint calculator
• What is the dew point?
• NOAA Dew point
• dew point formula
• Windows program for Heat Index, Dew Point, etc
• Often Needed Answers about Temp, Humidity & Dew Point from the sci.geo.meteorology Usenet newsgroup
• FREE Humidity & Dewpoint Calculator - Vaisala
• Dewcheck homepage