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Heat and freshwater budegts, fluxes, and transports

Delve into the intricate processes of heat distribution, fluxes, and transport in the atmosphere and ocean. Explore data on polar radiation, heat imbalance corrections, and global heat transport dynamics.

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Heat and freshwater budegts, fluxes, and transports

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  1. Heat and freshwater budegts, fluxes, and transports Reading: DPO Chapter 5

  2. Polar shortwave radiation longwave shortwave radiation longwave 450Wm-2 250Wm-2 150Wm-2 150Wm-2 200Wm-2 50Wm-2 atmosphere atmosphere evaporation evaporation -100Wm-2 -50Wm-2 225Wm-2 -100Wm-2 -50Wm-2 ocean 75Wm-2 ocean Net heat flux (gain) 75Wm-2 Net heat flux (loss) -75Wm-2 Heat budgets, fluxes, transports Tropics

  3. This imbalance needs to be compensated by transporting heat poleward in atmosphere and ocean. Total (atmosphere + ocean) ≈ 6 PW (1 PW = 1015 J/s) (can be determined just from satellite radiation observations). Atmospheric measurements allow estimate of atmospheric part: 4PW, so total ocean “meridional” heat transport 2 PW (no ocean observations needed for this….)

  4. Heat flux at edge of atmosphere versus latitude

  5. Total (atmosphere+ocean) global heat transport versus latitude

  6. Total global atmospheric heat transport versus latitude

  7. top area A Qsurface side area S volume V u2 h1 side area S u1 Q2 h2 Q1 Simple heat budget example Heat content H= cp T ρ V [J] per volume h= cp T ρ [J/m3] Heat flux Q = heat/time/area W/m2 may be radiation like Qsurface, or water transporting heat like Q1 = u1 h1 Heat transport F = Q x area [W] ΔH/ Δt= ρ cp V ΔT/ Δt = Qsurface A + Q1 S – Q2 S (*) Surface heat flux divergence of ocean heat transport

  8. Can calculate ocean heat transports F from only surface flux data : Q2=-50W/m2 Q3=+50W/m2 Q1=-50W/m2 A1 A2 A3 F1=-Q1A1 F2=-Q1A1-Q2A2 F3=-Q1A1-Q2A2-Q3A3

  9. Or from oceanic measurements of currents v and temperature T everywhere… over a section across the ocean. Heat transport = H = cpTviAi = cpTvdAJ/sec=W CARE is necessary to balance the MASS first. If more water flows INTO a volume than OUT, then the heat/temperature equation like (*) earlier has a term like(uout-uin) T which can give an arbitrary (possibly HUGE) error depending on choice of temperature scale (e.g. Celsius vs. Kelvin)

  10. Heat and heat transportSurface heat flux (W/m2) into ocean DPO Figure 5.16

  11. Ocean heat balance, including radiation Qsfc= Qs + Qb+ Qh + Qe Total surface heat flux = Shortwave + Longwave + Latent + Sensible

  12. Ocean heat balance, including radiation Qsfc= Qs + Qb+ Qe + Qh Total surface heat flux = Shortwave + Longwave + Latent + Sensible This diagram shows a net global balance, not a local balance

  13. Ocean heat balance Qsfc= Qs + Qb + Qe + Qh in W/m2 Shortwave Qs: incoming solar radiation - always warms. Some solar radiation is reflected. The total amount that reaches the ocean surface is Qs = (1-)Qincoming where is the albedo (fraction that is reflected). Albedo is low for water, high for ice and snow. C monthly mean fractional cloud cover, θN is the noon solar elevation. (So-called “bulk formulas”)

  14. Ocean heat balance Qsfc= Qs + Qb + Qe + Qh in W/m2 Longwave Qb: outgoing (“back”) infrared thermal radiation (the ocean acts nearly like a black body) - always cools the ocean C monthly mean fractional cloud cover, T is air and water temperature,e water vapour pressure, k an empirical cloud cover coefficient,ε emittance of the sea surface, σSb Stefan-Boltzmann constant.

  15. Ocean heat balance Qsfc= Qs + Qb + Qe + Qh in W/m2 Latent Qe: heat loss due to evaporation - always cools. It takes energy to evaporate water. This energy comes from the surface water itself. (Same as principal of sprinkling yourself with water on a hot day - evaporation of the water removes heat from your skin) Ce transfer coefficient for latent heat, u wind speed at 10m height,qs is 98% of saturated specific humidity, qa is actual specific humidity, L is latent heat of evaporation.

  16. Ocean heat balance Qsfc= Qs + Qb + Qe + Qh in W/m2 Sensible Qh : heat exchange due to difference in temperature between air and water. Can heat or cool. Usually small except in major winter storms. Ch transfer coefficient for sensible heat, u wind speed at 10m height,T is surface water and air temperature, γ is adiabatic lapse rate of air and z the height where Ta is measured.

  17. Annual average heat flux components (W/m2) DPO Figure 5.15

  18. Heat flux components summed for latitude bands (W/m2) DPO Figure 5.17

  19. Heat transport Heat input per latitude band (PW) 1 PW = 1 “Petawatt” = 1015 W Heat transport (PW) (meridional integral of the above) DPO Figure 5.24

  20. Heat transport • Meridional heat transport across each latitude in PW • Calculate either from atmosphere (net heating/cooling) and diagnose for ocean • OR from velocity and temperature observations in the ocean. Must have net mass balance to compute this. DPO Figure 5.23

  21. Transport definitions • Transport: add up (integrate) velocity time property over the area they flow through (or any area - look at velocity “normal” to that area) • Volume transport = integral of velocity v m3/sec • Mass transport = integral of density x velocity v kg/sec • Heat transport = integral of heat x velocity cpTv J/sec=W • Salt transport = integral of salt x velocity Sv kg/sec • Freshwater transport = integral of Fwater x velocity (1-S)v kg/sec • Chemical tracers = integral of tracer concentration (which is in mol/kg) x velocity Cv moles/sec • Flux is just these quantities per unit area

  22. Transport definitions • Volume transport = V =  viAi = vdA m3/sec • Mass transport = M =  viAi = vdAkg/sec • Heat transport = H = cpTviAi = cpTvdAJ/sec=W • Salt transport = S = SviAi = SvdA kg/sec • Freshwater transport = F =  (1-S) viAi = (1 - S)vdA kg/sec • Chemical tracers = C = CviAi = CvdA moles/sec • Flux is just these quantities per unit area e.g. volume flux is V/A, mass flux is M/A, heat flux is H/A, salt flux is S/A, freshwater flux is F/A, C /A

  23. Conservation of volume, salt • volume conservation: Vo - Vi = (R + AP) – AE  F (total of freshwater inputs over basin) (2) Salt conservation: ViρiSi = VoρoSo or approximately ViSi = VoSo

  24. Combining these equations gives Vi = F So / ΔS Vo = F Si / ΔS or approximately (Vi≈ Vo V , Si≈ So S) V = F S / ΔS “Knudsen relations”. Useful for calculating transport/influx/outflux from F and S, or for estimating F from flow measurements…. Note what happens when ΔS becomes very small (“overmixed” case….)

  25. Mediterranean and Black Seas Evaporative basin Runoff/precipitation DPO Figure 5.3

  26. NCEP climatology Precipitation minus evaporation (cm/yr):what freshwater transports within the ocean are required to maintain a steady state salinity distribution in the ocean given this P-E? • Consider N. Pacific box, Bering Strait to north, complete east-west crossing between net P and net E areas, for example • Total freshwater transport by ocean out of this box must equal the P-E • FW transport across the long section must equal take up all the rest of the net P-E in the area to the north, after Bering Strait is subtracted

  27. Global ocean freshwater transport Wijffels (2001) • Continuous curves show different estimates of ocean FW transport based on observed P-E+R (atmosphere and rivers) • Diamonds with error bars are estimates of FW transports based on ocean velocities and salinities

  28. Freshwater transport divergences from velocity&salinity observations.Blue/positive means is net precipitation, red/negative net evaporation. Arrows/color show circulation and relative salinity being transported

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