Copyright © 2011 R. R. Dickerson & Z.Q. Li 1 Continuing to build a cloud model: Consider a wet air parcel Parcel boundary As the parcel moves assume no.

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Copyright © 2011 R. R. Dickerson & Z.Q. Li 1 Continuing to build a cloud model: Consider a wet air parcel Parcel boundary As the parcel moves assume no mixing with environment. Pressure inside = pressure outside

Copyright © 2010 R. R. Dickerson & Z.Q. Li 2 We have already considered a dry parcel, now consider a parcel just prior to saturation (the book leaves out several steps): mass of parcel = m d + m v = m p Suppose we expand the parcel reversibly and adiabatically and condense out some mass of liquid = m L, keeping total mass constant. m p = m d + m v ’ + m L orm L + m v ‘ = m v Where m v ’ is the new mass of vapor in the parcel.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 3 m L = m v - m v ’ Let the mass ratio of liquid to dry air be . Since for this small change, w is the sum of water vapor and liquid; at w ’, the parcel is saturated. Consider the initial state to be just saturated: This is Eq in Rogers and Yau.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 4 Define  to be the adiabatic liquid water content, and d  is the increase in adiabatic liquid water mixing ratio.  increases from the LCL where it is zero to….  = w s (T c,p c ) - w s (T,p) at any other level. Define the parcel total water mixing ratio Q T : Q T = w s +  Q T is conserved in a closed system (the book uses just Q).

Copyright © 2010 R. R. Dickerson & Z.Q. Li 5 Consider an adiabatic displacement of a saturated parcel. Assume a reversible process with total mass conserved. The specific (per kg) entropy of cloudy air and vapor will be:

Copyright © 2010 R. R. Dickerson & Z.Q. Li 6 The system is closed so we can consider an isentropic process:

Copyright © 2010 R. R. Dickerson & Z.Q. Li 7 Adding together the entropy changes with temperature for dry and wet air with the entropy of evaporation, setting total entropy change to zero:

Copyright © 2010 R. R. Dickerson & Z.Q. Li 8 With further rearrangement:

Copyright © 2010 R. R. Dickerson & Z.Q. Li 9 Wet, Equivalent Potential Temperature,  q and Equivalent Potential Temperature,  e. θ q is the temperature a parcel of air would reach if all of the latent heat were converted to sensible heat by a reversible adiabatic expansion to w = 0 followed by a dry adiabatic compression to 1000 hPa.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 10 Because the previously derived quantity is a constant, we may define

Copyright © 2010 R. R. Dickerson & Z.Q. Li 11 Equivalent Potential Temperature  e If one assumes the latent heat goes only to heat dry air and not H 2 O, this is called a pseudo adiabatic process. Set Q T = 0, then one obtains the equation for the equivalent potential temperature.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 12 Pseudoadiabatic Process Consider a saturated parcel of air. Expand parcel from T, p, w o … …to T+dT, p+dp, w o +dw o (note: dT, dp, dw o are all negative) This releases latent heat = - L v dw o Assume this all goes to heating dry air, and not into the water vapor, liquid, or solid (rainout).

Copyright © 2010 R. R. Dickerson & Z.Q. Li 13 Assume all condensation products fall out of parcel immediately.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 14 Since dw 0 < 0,  increases for a pseudoadiabatic process.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 15 Integrate from the condensation level where T = T c,  original  o to a level where w s ~ 0

Copyright © 2010 R. R. Dickerson & Z.Q. Li 16 Use of Equivalent Potential Temperature  e  e is the temperature that a parcel of air would have if all of its latent heat were converted to sensible heat in a pseudoadiabatic expansion to low pressure, followed by a dry adiabatic compression to 1000 hPa.  e is conserved in both adiabatic and pseudoadiabatic processes. See Poulida et al., JGR, 1996.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 17 Adiabatic Equivalent Temperature T ea Adiabatic equivalent temperature (also known as pseudoequivalent temperature): The temperature that an air parcel would have after undergoing the following process: dry-adiabatic expansion until saturated; pseudoadiabatic expansion until all moisture is precipitated out; dry- adiabatic compression to the initial pressure. Glossary of Met., 2000.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 18 Adiabatic Equivalent Temperature T ea Instead of compressing to 1000 hPa, we go instead to the initial pressure.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 19 Note: Since T is in the range of K and w o is generally < 20 x Generally T ea and T ep (equivalent potential temp) are within 5 o C.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 20 Additional Temperature Definitions Wet Bulb Potential Temperature  w Defined graphically by following pseudo/saturated adiabats to 1000 hPa from P e, T c. This temp is conserved in most atmos. processes. Adiabatic Wet Bulb Temperature T wa (or T sw ) Follow pseudo/saturated adiabats from P e, T c to initial pressure. |T w - T wa | ~ 0.5 o or less.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 21 Conservative Properties of Air Parcels  CNC ee CC ww CC TdTd TwTw wC T*T* TeTe TcTc C f C qq CC Variable dry adiabatic saturated/pseudo adiabatic

Copyright © 2010 R. R. Dickerson & Z.Q. Li 22 Remember Thermodynamic Diagrams (lecture 4) A true thermodynamic diagram has Area  Energy T RlnP isotherms isobars Emagram T lnP Dry adiabats T-  gram

Copyright © 2010 R. R. Dickerson & Z.Q. Li 23 Skew T – LogP In the U.S. a popular meteorological thermodynamic diagram is the Skew T – LogP diagram: y = -RlnP x = T + klnP k is adjusted to make the angle between isotherms and dry adiabats nearly 90 o. See Hess for more complete information.

Copyright © 2010 R. R. Dickerson & Z.Q. Li 24