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Transcript
AOSS 401, Fall 2007 Lecture 6 September 19, 2007 Richard B. Rood (Room 2525, SRB) [email protected] 734-647-3530 Derek Posselt (Room 2517D, SRB) [email protected] 734-936-0502 Class News • Homework 1 graded • Homework 2 due today • Homework 3 posted on ctools between now and Friday Weather • NCAR Research Applications Program – http://www.rap.ucar.edu/weather/ • National Weather Service – http://www.nws.noaa.gov/dtx/ • Weather Underground – http://www.wunderground.com/modelmaps/m aps.asp?model=NAM&domain=US Outline 1. Review from Monday • • Continuity Equation Scale Analysis 2. Conservation of Energy • • • Thermodynamic energy equation and the first law of thermodynamics Potential temperature and adiabatic motions Adiabatic lapse rate and static stability From last time Conservation of Mass • Conservation of mass leads to another equation; the continuity equation • Continuity Continuous • No holes in a fluid • Another fundamental property of the atmosphere • Need an equation that describes the time rate of change of mass (density) Eulerian Form of the Continuity Equation u t Dz In the Eulerian point of view, our parcel is a fixed volume and the fluid flows through it. Dy Dx Lagrangian Form of the Continuity Equation 1 D u Dt The change in mass (density) following the motion is equal to the divergence Convergence = increase in density (compression) Divergence = decrease in density (expansion) Scale Analysis of the Continuity Equation • Define a background pressure field • “Average” pressure and density at each level in the atmosphere • No variation in x, y, or time • Hydrostatic balance applies to the background pressure and density p0 p0 ( z ) 0 0 ( z) dp0 ( z ) 0 ( z) g dz Scale Analysis of the Continuity Equation Total pressure and density = sum of background + perturbations (perturbations vary in x, y, z, t) p p0 ( z ) p' ( x, y, z, t ) 0 ( z ) ' ( x, y, z, t ) Start with the Eulerian form of the continuity equation, do the scale analysis, and arrive at 0u 0 Scale Analysis of the Continuity Equation • Expand this equation 0u 0 Remember, ρ0 does not depend on x or y u v w w d 0 0 x y z 0 dz u v 1 d 0 w x y 0 dz Scale Analysis of the Continuity Equation • The vertical motion on large (synoptic) scales is closely related to the divergence of the horizontal wind u v 1 d 0 w x y 0 dz 1 d 0 w uh 0 dz Scale Analysis of the Horizontal Momentum Equations Du uvtan( ) uw 1 p 2Ωv sin( ) 2Ωw cos( ) 2 (u ) Dt a a x Dv u 2 tan( ) vw 1 p 2Ωu sin( ) Dt a a y 2 ( v ) U·U/L U·U/a U·W/ a ΔP/ρL Uf Wf νU/H2 10-4 10-5 10-8 10-3 10-3 10-6 10-12 Largest Terms Geostrophic Balance 1 p 2Ωv sin( ) fv x 1 p 2Ωu sin( ) fu y • There is no D( )/Dt term (no acceleration) • No change in direction of the wind (no rotation) • No change in speed of the wind along the direction of the flow (no divergence) What are the scales of the terms? For “large-scale” mid-latitude Du uvtan( ) uw 1 p 2Ωv sin( ) 2Ωw cos( ) 2 (u ) Dt a a x Dv u 2 tan( ) vw 1 p 2Ωu sin( ) Dt a a y 2 ( v ) U·U/L U·U/a U·W/ a ΔP/ρL Uf Wf νU/H2 10-4 10-5 10-8 10-3 10-3 10-6 10-12 Prediction (Prognosis) Ageostrophic Analysis (Diagnosis) Geostrophic • Remember the definition of geostrophic wind 1 p vg f x 1 p ug f y • Our prediction equation for large scale midlatitudes Du 1 Dt Dv 1 Dt p fv f v vg fvag x p fu f u ug fuag y Ageostrophic Wind and Vertical Motion • Remember the scaled continuity equation 1 d 0 w uh 0 dz • Vertical motion related to divergence, but geostrophic wind is nondivergent. • Divergence of ageostrophic wind leads to vertical motion on large scales. Closing Our System of Equations • We have formed equations to predict changes in motion (conservation of momentum) and density (conservation of mass) • We need one more equation to describe either the time rate of change of pressure or temperature (they are linked through the ideal gas law) • Conservation of energy is the basic principle Conservation of Energy: The thermodynamic equation • First law of thermodynamics: • Change in internal energy is equal to the difference between the heat added to the system and the work done by the system. • Internal energy is due to the kinetic energy of the molecules (temperature) • Total thermodynamic energy is the internal energy plus the energy due to the parcel moving Thermodynamic Equation For a Moving Parcel DT D cv Dt p Dt J • J represents sources or sinks of energy. – – – – radiation latent heat release (condensation/evaporation, etc) thermal conductivity frictional heating. • cv = 717 J K-1 kg-1, cvT = a measure of internal energy – specific heat of dry air at constant volume – amount of energy needed to raise one kg air one degree Kelvin if the volume stays constant. Thermodynamic Equation DT D cv p J Dt Dt • Involves specific heat at constant volume 1 D • Remember the material derivative u form of the continuity equation Dt • Following the motion, divergence leads to a change in volume • Reformulate the energy equation in terms of specific heat at constant pressure Another form of the Thermodynamic Equation DT D cv p J Dt Dt DT Dp cp J Dt Dt • Short derivation • Take the material derivative of the equation of state • Use the chain rule and the fact that R=cp-cv • Substitute in from the thermodynamic energy equation in Holton • Leads to a prognostic equation for the material change in temperature at constant pressure p RT D DT ( p ) R Dt Dt D Dp DT p R Dt Dt Dt D Dp DT DT p cp cv Dt Dt Dt Dt Substitute in from the thermodynamic energy equation (Holton, pp. 47-49) D Dp DT D p cp p J Dt Dt Dt Dt DT Dp cp J Dt Dt (Ideal gas law) (Material derivative) (Chain Rule) (Use R=cp-cv) D DT p J cv Dt Dt (Cancel terms) Thermodynamic equation DT Dp cp J Dt Dt • Prognostic equation that describes the change in temperature with time • In combination with the ideal gas law (equation of state) the set of predictive equations is complete Atmospheric Predictive Equations Du uvtan( ) uw 1 p 2Ωv sin( ) 2Ωw cos( ) 2 (u ) Dt a a x Dv u 2 tan( ) vw 1 p 2Ωu sin( ) 2 ( v ) Dt a a y Dw u 2 v 2 1 p g 2Ωu cos( ) 2 ( w) Dt a z D u Dt DT D 1 cv p J Dt Dt p RT and 1 Motions in a Dry (Cloud-Free) Atmosphere • For most large-scale motions, the amount of latent heating in clouds and precipitation is relatively small • In absence of sources and sinks of energy in a parcel, entropy is conserved following the motion • Why is this important? – Large scale vertical motion – Atmospheric stability (convection) Motions in a Dry (Cloud-Free) Atmosphere • Goal: find a variable that – Is conserved following the motion if there are no sources and sinks of energy (J) – Describes the change in temperature as a parcel rises or sinks in the atmosphere • Adiabatic process: “A reversible thermodynamic process in which no heat is exchanged with the surroundings” • Situations in which J=0 referred to as – Dry adiabatic – Isentropic • Why is this useful? Synoptic Motions Forced Ascent/Descent Cooling Warming Derivation of Potential Temperature c p DT Rd Dp J T Dt p Dt T D (ln T ) D (ln p ) J cp Rd 0 Dt Dt T c p D (ln T ) Rd D (ln p ) (No sources or sinks of energy) (Adiabatic process) p T c p D (ln T ) Rd D (ln p ) T0 p0 c p (ln T0 ln T ) Rd (ln p0 ln p ) T0 Rd p0 ln ln T cp p p T0 T 0 p (Energy Equation divided by temperature) Rd cp (Integrate between two levels) (Use the properties of the natural logarithm) (Take exponential of both sides) Definition of the Potential Temperature Rd cp p0 T p Note: p0 is defined to be a constant reference level p0 = 1000 hPa Interpretation: the potential temperature is the temperature a parcel has when it is moved from a (higher or lower )pressure level down to the surface. p0 T p Rd cp • The temperature at the top of the continental divide is -10 degrees celsius (about 263 K) • The pressure is 600 hPa, R=287 J/kg/K, cp=1004 J/kg/K • Compute 304 K 1. potential temperature at the continental divide 2. The temperature the air would have if it sinks to the plains (pressure level of 850 hPa) with no change in potential temperature T 290 K 17 oC 64 o F Dry Adiabatic Lapse Rate Change in Temperature with Height • For a dry adiabatic, hydrostatic atmosphere the potential temperature does not vary in the vertical direction: 0 z • In a dry adiabatic, hydrostatic atmosphere the temperature T must decrease with height. How quickly does the temperature decrease? ln ln T p0 p Rd cp ln T Rd ln p0 c p p Rd p0 ln ln T ln z z z c p p 1 1 T Rd ln p0 ln p z T z c p z T T Rd T ln p z z c p z 1 p g ln p z p z p T T g Rd T z z c p p T T g z z c p (logarithm of potential temperature) (take the vertical derivative) (Definition of d lnx and derivative of a constant) (Multiply through by T) (Hydrostatic balance) (Equation of State) Dry adiabatic lapse rate The adiabatic change in temperature with height is T T g z z c p For dry adiabatic, hydrostatic atmosphere T g d z c p d: dry adiabatic lapse rate (approx. 9.8 K/km) Atmospheric Static Stability and Potential Temperature • Static: considering an atmosphere at rest (no u, v, w) • Consider what will happen if an air parcel is forced to rise (or sink) • Stable: parcel returns to 0 the initial position z • Neutral: parcel only rises/sinks if forcing continues, otherwise 0 z remains at current level • Unstable: parcel accelerates 0 away from its current position z Static Stability p Rd T p parcel penv parcel Rd Tparcel env Rd Tenv parcelTparcel envTenv • Displace an air parcel up or down • Assume the pressure adjusts instantaneously; the parcel immediately assumes the pressure of the altitude to which it is displaced. • Temperature changes according to the adiabatic lapse rate Static Stability • Adiabatic: parcel potential temperature constant with height • For instability, the temperature of the atmosphere has to decrease at greater than 9.8 K/km • This is extremely rare… • Convection (deep and shallow) is common • How to reconcile lack of instability with presence of convection? 0 z 0 z 0 z Static Stability and Moisture • The atmosphere is not dry—motion is not dry adiabatic • If air reaches saturation (and the conditions are right for cloud formation), vapor will condense to liquid or solid and release energy (J≠0) • Average lapse rate in the troposphere: -6.5 oC/km • Moist (saturated) adiabatic lapse rate: -5 oC/km Consider the Upper Atmosphere Atmosphere in Balance • Hydrostatic balance (no vertical acceleration) • Geostrophic balance (no rotation or divergence) • Adiabatic lapse rate (no clouds or precipitation) • What we are really interested in is the difference from balance. • This balance is like a strong spring, always pulling back. • It is easy to know the approximate state. Difficult to know and predict the actual state. Next time • Ricky will be lecturing Friday, Monday, and Wednesday • We have essentially completed chapters 1-2 in Holton • We have derived a set of governing equations for the atmosphere • Chapter 3 will introduce simple applications of these equations • First exam covers chapters 1-3—three weeks from today!