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Prof. Fred Remer University of North Dakota Water in the Atmosphere
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Prof. Fred Remer University of North Dakota Reading l Hess –pp 43 - 44 –pp 58 – 60 l Tsonis –pp 93 – 97 l Wallace & Hobbs –pp 66 – 67 –pp 79 – 84 l Bohren & Albrecht –pp 181-188
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Prof. Fred Remer University of North Dakota Objectives l Be able to define water vapor pressure l Be able to define virtual temperature l Be able to define specific humidity l Be able to define mixing ratio
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Prof. Fred Remer University of North Dakota Objectives l Be able to calculate the water vapor pressure l Be able to calculate virtual temperature l Be able to calculate specific humidity l Be able to calculate mixing ratio
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Prof. Fred Remer University of North Dakota Water In the Atmosphere l Unique Substance l Occurs in Three Phases Under Normal Atmospheric Pressures and Temperatures l Gaseous State –Variable 0 – 4% H H O
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Prof. Fred Remer University of North Dakota Water in the Atmosphere l Remember Dalton’s Law? –Law of Partial Pressures –Let’s look at the contribution of water p = p1 + p2 + p3 + ….
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Ideal Gas Law for Dry Air l Ideal Gas Law for Water Vapor p = pressure of dry air d = specific volume of dry air R d = gas constant for dry air e = vapor pressure of water vapor v = specific volume of water vapor R v = gas constant for water vapor
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Partial pressure that water vapor exerts Total Pressure p = p O 2 +p N 2 +p H 2 O v Water Vapor Pressure e = p H 2 O v
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Gas Constant of Water Vapor H H O Molecular Weight (M w ) Hydrogen = 1kg kmol -1 Oxygen = 16 kg kmol -1 Hydrogen = 1kg kmol -1 Oxygen = 16 kg kmol -1 Water = 18 kg kmol -1
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l The temperature dry air must have in order to have the same density as moist air at the same pressure l Fictitious temperature
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Dry Air Total Pressure = p Total Pressure = p Volume = V Temperature = T Mass of Air = m d
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Moist Air (Mixture) Total Pressure = p Total Pressure = p Volume = V Temperature = T Mass of Air = m d + m v
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Density of mixture
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Ideal Gas Law –For Dry Air –For Water Vapor Alone or or
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Substitute into density expression
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Dalton’s Law of Partial Pressure or
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Substitute or
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Remove R d
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) Define
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Remove p
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Rearrange terms
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l By definition, virtual temperature is the temperature dry air must have in order to have the same density as moist air (mixture) at the same pressure Instead of or Use p = total (mixture) pressure = mixture density
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Substitution of l Into l Produces
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Rearrange
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Start Canceling!
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Still looks Ugly! Simplify!
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) Virtual Temperature (T v ) p = total (atmospheric) pressure e = water vapor pressure T = temperature
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Moist air (mixture) is less dense than dry air l Virtual temperature is greater than actual temperature l Small difference
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l Ratio of the density of water vapor in the air to the (total) density of the air
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l The mass of water vapor (m v ) to the mass of dry air Mass of Dry Air = m d Mass of Water Vapor = m v
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l The mass of water vapor (m v ) to the mass of dry air Mass of Dry Air = m d Mass of Water Vapor = m v
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Expressed in g/kg –Dry Air l 1 to 2 g/kg –Tropical Air l 20 g/kg
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Can mixing ratio be expressed in terms of water vapor pressure? l Sure as it will rain on a meteorologist’s picnic!
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l By definition l Divide top and bottom by volume (V)
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l But density is so..... w = mixing ratio v = density of water vapor in air d = density of dry air
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Ideal Gas Law or or
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Substitute
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Simplify l Remember
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Substitute into l But p = total pressure of air (mixture)
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Substitute into l Ta-Da!
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Expression for Mixing Ratio (w) –Water Vapor Pressure (e) in any units –Atmospheric Pressure (p) in any units
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Prof. Fred Remer University of North Dakota Mixing Ratio (w) l Can be used to determine other water variables l Let’s look at –Specific Humidity –Water Vapor Pressure (e) –Virtual Temperature (T v )
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l By definition l But q = specific humidity v = density of water vapor in air = density of air d = density of dry air
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l Substitute into l Results in l But
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l Substitute into l Results in
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l Eliminate V
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l Divide top and bottom by m d
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l But so
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Prof. Fred Remer University of North Dakota Specific Humidity (q) l Expression for specific humidity (q) –Mixing Ratio (w) in kg kg -1
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Pressure exerted by water vapor is a fraction of total pressure of air l Fraction is proportional to # of moles in mixture e = water vapor pressure f = fractional amount of water vapor p = total pressure of air
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l How many moles of water are in a sample of air? l Number of moles of water n v = # of moles m v = mass of water molecules M w = molecular weight of water
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l How many moles of dry air are in a sample of air? l Number of moles of dry air n d = # of moles m d = mass of dry air M d = mean molecular weight of dry air
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l How many moles of air are in a sample of air? l Number of moles of air
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l What is the molar fraction of water vapor in the air? l Substitute into
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Yikes! Let’s make this more manageable!
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Multiply top and bottowm by M w /m d
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Canceling out
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l But Mixing Ratio and
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e)
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Prof. Fred Remer University of North Dakota Water Vapor Pressure (e) l Expression for water vapor pressure (e) –Mixing Ratio (w) in kg kg -1 –Atmospheric Pressure (p)
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Derive an expression for virtual temperature (T v ) using mixing ratio (w)
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Expression for water vapor pressure or
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Substituting
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Expand
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) Common denominator w+
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Group
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Simplify
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) l Divide numerator by denominator (polynomial division) and eliminate w 2 terms
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Prof. Fred Remer University of North Dakota Virtual Temperature (T v ) Substitute =.622
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Prof. Fred Remer University of North Dakota Virtual Temperature (Tv) l Expression for virtual temperature –Mixing Ratio (w) in kg kg -1
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Prof. Fred Remer University of North Dakota Review of Water Variables l Water Vapor Pressure
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Prof. Fred Remer University of North Dakota Review of Water Variables l Virtual Temperature
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Prof. Fred Remer University of North Dakota Review of Water Variables l Mixing Ratio
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Prof. Fred Remer University of North Dakota Review of Water Variables l Specific Humidity
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Prof. Fred Remer University of North Dakota Water in the Atmosphere l Moisture Variables –Water Vapor Pressure –Virtual Temperature –Mixing Ratio –Specific Humidity l Amount of Moisture in the Atmosphere
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Prof. Fred Remer University of North Dakota Water in the Atmosphere l Unanswered Questions –How much water vapor can the air hold? –When will condensation form? –Is the air saturated? l The Beer Analogy
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Prof. Fred Remer University of North Dakota The Beer Analogy l You are thirsty! l You would like a beer. l Obey your thirst!
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Prof. Fred Remer University of North Dakota The Beer Analogy l Pour a glass but watch the foam
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Prof. Fred Remer University of North Dakota The Beer Analogy l Wait! l Some joker put a hole in the bottom of your Styrofoam cup! l It is leaking!
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Prof. Fred Remer University of North Dakota The Beer Analogy l Having had many beers already, you are intrigued by the phenomena!
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Prof. Fred Remer University of North Dakota The Beer Analogy Rate at beer flows from keg is constant
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Prof. Fred Remer University of North Dakota The Beer Analogy Rate at beer flows from keg is constant Rate at beer flows from cup depends on height
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Prof. Fred Remer University of North Dakota The Beer Analogy The higher the level of beer in the cup, the faster it leaks!
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Prof. Fred Remer University of North Dakota The Beer Analogy l The cup fills up l Height becomes constant l Equilibrium Reached Inflow (Constant) Leakage (Varies with Height)
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Prof. Fred Remer University of North Dakota The Beer Analogy l What do you do? Inflow (Constant) Leakage (Varies with Height)
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Prof. Fred Remer University of North Dakota The Beer Analogy l Get a new cup!
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Prof. Fred Remer University of North Dakota Overview l Similar to what happens to water in the atmosphere
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Prof. Fred Remer University of North Dakota Overview l Molecules in liquid water attract each other l In motion
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Prof. Fred Remer University of North Dakota Overview l Collisions l Molecules near surface gain velocity by collisions
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Prof. Fred Remer University of North Dakota Overview l Fast moving molecules leave the surface l Evaporation
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Prof. Fred Remer University of North Dakota Overview l Soon, there are many water molecules in the air
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Prof. Fred Remer University of North Dakota Overview l Slower molecules return to water surface l Condensation
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Prof. Fred Remer University of North Dakota Overview l Net Evaporation –Number leaving water surface is greater than the number returning –Evaporation greater than condensation
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Prof. Fred Remer University of North Dakota Overview l Molecules leave the water surface at a constant rate l Depends on temperature of liquid
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Prof. Fred Remer University of North Dakota Overview l Molecules return to the surface at a variable rate l Depends on mass of water molecules in air
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Prof. Fred Remer University of North Dakota Overview l Rate at which molecule return increases with time –Evaporation continues to pump moisture into air –Water vapor increases with time
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Prof. Fred Remer University of North Dakota Overview l Eventually, equal rates of condensation and evaporation l “Air is saturated” l Equilibrium
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Prof. Fred Remer University of North Dakota Overview l Derive a relationship that describes this equilibrium
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Prof. Fred Remer University of North Dakota Clausius-Clapeyron Equation
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