SIO 217B Atmospheric and Climate Sciences II Winter 2012 Homework #5 Due March 13 at the beginning of class 1. A simple model for the annual mean Hadley circulation is that air parcels rise to the upper troposphere at the equator and then move to higher latitudes in both hemispheres. a) Assuming that air parcels conserve angular momemtum in the absolute reference frame, derive an expression for zonal wind in the rotating reference frame as a function of latitude. For simplicity assume that parcels at the equator are at rest with respect to the rotating Earth. b) Using the above expression, calculate values of zonal wind at 0°, 10°N, 20°N, 30°N, 40°N, and 50°N. c) Assuming surface wind is zero and upper-level wind is at 200 hPa, calculate the layer mean temperature gradient in thermal wind balance with momentum-conserving wind. Express your answer in terms of temperature change per 1000 km at 0°, 10°N, 20°N, 30°N, 40°N, and 50°N. 2. Momentum-conserving flow cannot extend far into higher latitudes because the vertical wind shear and the meridional temperature gradient eventually become so large that baroclinic instability occurs. The waves generated by baroclinic instability then become the primary process for transporting momentum, and the mean flow no longer conserves angular momentum. One theory for determining the latitude at which the Hadley circulation ends is the latitude at which baroclinic instability first occurs. a) The two-layer model indicates that the onset of baroclinic instability for the most unstable wave occurs when 2 λ2 UT / β = 1. Change this equation into a form where f0 = a function of β, ∂T/∂y, σ, and δp. Hint: R T / δp ≈ f0 (ψ1 – ψ3) / δp b) All else the same, if the stratification of the troposphere increases, will the latitude of the onset of baroclinic instability shift poleward, equatorward, or stay the same? c) All else the same, if the depth of the troposphere (represented by δp) increases, will the latitude of the onset of baroclinic instability shift poleward, equatorward, or stay the same? d) All else the same, if the meridional temperature gradient in the troposphere increases, will the latitude of the onset of baroclinic instability shift poleward, equatorward, or stay the same? 3. During Ice Ages, there is less CO2 in the atmosphere and greater surface albedo at higher latitudes from more snow and ice cover. a) Do you think the equator-to-pole temperature gradient is larger or smaller during Ice Ages than during interglacial times? Why? b) Colder temperature during Ice Ages implies less water vapor in the atmosphere available for condensation in the upper troposphere. Do you think that tropospheric stratification is larger or smaller during Ice Ages than during interglacial times? Why? c) Less CO2 during Ice Ages means less radiative cooling in the stratosphere to offset solar absorption by ozone. Less CO2 and water vapor also mean less greenhouse warming in the troposphere. Less water vapor available for condensation means less buoyancy for rising parcels. Do you think the tropopause, defined as the elevation of the coldest temperature, is higher or lower during Ice Ages than during interglacial times? 4. Do the following in context of your answers to the previous questions. a) The plot below schematically indicates positions of the vertical and meridional components of the annual mean Hadley circulation during interglacial times. Draw arrows schematically indicating the positions during Ice Ages, if different from interglacial times. surface SP 60°S EQ 30°S 30°N 60°N NP b) Qualitatively draw how annual mean zonal mean average tropospheric temperature varies with latitude during interglacial times. Qualitatively draw how temperature varies with latitude during Ice Ages to qualitatively show differences between the interglacial and Ice Age conditions. warmer T colder SP 60°S 30°S EQ 30°N 60°N NP c) Qualitatively draw how annual mean zonal mean upper tropospheric zonal wind varies with latitude during interglacial times. Qualitatively draw how zonal wind varies with latitude during Ice Ages to qualitatively show differences between interglacial and Ice Age conditions. Make sure changes in your plot are consistent with zero global average momentum flux into the atmosphere. westerly u = 0 easterly SP 60°S 30°S EQ 30°N 60°N NP