DOCSLIB.ORG

VARIATIONSUS CLIVAR VARIATIONS CUS CLIVAR Lim Ity a Bil Te V Cta Ariability & Predi

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
VARIATIONSUS CLIVAR VARIATIONS CUS CLIVAR Lim Ity a Bil Te V Cta Ariability & Predi VARIATIONSUS CLIVAR VARIATIONS CUS CLIVAR lim ity a bil te V cta ariability & Predi Summer 2014 • Vol. 12, No. 3 Predictability of Arctic climate Arctic–lower latitude coupling: What is the variability forcing and what is the response? Guest Editor: John E. Walsh Judah Cohen Atmospheric and University of Alaska, Fairbanks Environmental Research ecent Arctic changes are expected to, and may already be, impacting middle latitudes This issue of Variations is and the rest of the globe. For the first time, the US National Climate Assessment (Melillo dedicated to the predictability of R et al. 2014) has called attention to a possible role of the Arctic in variations of the jet stream Arctic climate, its interaction with (now referred to as the “polar vortex”) over the contiguous United States (http://nca2014. the climate of lower latitudes, and globalchange.gov/report/our-changing-climate/melting-ice). As evidence of the increased how climate change may impact public awareness of this topic, Hamilton and Lemcke-Stampone (2013) have recently reported such interactions. The dramatic results showing that a clear majority (60%) of surveyed members of the public now accepts retreat of perennial Arctic sea ice that there is a connection between Arctic warming and mid-latitude weather. Yet the Arctic’s has become the poster child of connection with middle latitudes represents a challenge to scientific diagnosis because the climate change. Such a large and forcings and responses of the two regions are intertwined. Hence a key question about Arctic− visible change to the Arctic system lower latitude coupling is: What is the forcing and what is the response to Arctic warming? has been a wake up call to the climate community that climate Drivers of the amplified warming in the Arctic change may not necessarily be slow and steady nor its impacts There is indisputable evidence that the Arctic has warmed over the past several decades at only of consequence in the far off more than double the global rate of warming. There are at least four factors that contribute to future. The newly revealed open the polar amplification: waters of the Arctic ocean and the • A temperature feedback by which a warming surface leads to a more radiative loss to less discussed collapse of warm space in the warmer lower latitudes than in the colder polar regions; season spring snow cover are • The albedo-temperature feedback associated with a reduction of sea ice and snow; known to have profound impacts • Increased atmospheric humidity and the associated increase of downwelling longwave on the energy balance of the radiation; and Arctic at the surface and in the • Increased poleward transports by the ocean and atmosphere. lower troposphere. And just as While these drivers are not independent (e.g., the loss of sea ice can be driven by warming heating anomalies in the tropics associated with increased humidity or poleward transports), the following sequential summary can influence weather around enables a more structured presentation. the globe, it is plausible that large heating anomalies in the IN THIS ISSUE Arctic can have ripple effects at Arctic lower-latitude coupling: What is the forcing and what is the response? ........................................ 1 lower latitudes, especially across The influence of tropical convection on Arctic climate variability ............................................................. 6 the industrialized countries Implicatioins of rapid Arctic change for weather patterns in northern mid-latitudes............................... 10 and population centers of the Recent evidence for skill in model forecasts of Northern Hemisphere winter climate ........................... 14 Northern Hemisphere. Can high latitude boundary forcings improve predictability on seasonal and decadal time scales? ..... 18 (Cont. pg. 2) Arctic sea ice predictability .................................................................................................................... 24 USUS CLIVAR CLIVAR VARIATIONS VARIATIONS • •Summer Spring 2014 2014 • • Vol. Vol. 12, 12, No. No. 2 3 1 US CLIVAR VARIATIONS Latitudinal dependence of efficiency of re-radiation of energy Though the entire globe is warming, the rate of warming in Pithian and Mauritsen (2014) have recently shown that polar amplification is a prominent the Arctic is two to three times feature of global climate warming even without changes in snow and ice. In the absence of faster than the rest of globe. Why a decrease of surface albedo, the Arctic still warms more than lower latitudes because the the Arctic is warming quickly is cold shallow near-surface layer, often characterized by temperature inversions, is relatively not obvious. Walsh discusses the inefficient at re-radiating the additional energy. This inefficiency can be explained by the causes and implications of Arctic smaller increase of emitted blackbody radiation per unit warming at lower temperatures. amplification of warming. Though Pithian and Mauritsen find that this “Planck feedback” is stronger than even the albedo the snow and ice albedo feedback feedback in shaping the latitudinal pattern of externally forced warming. is thought by most as responsible The albedo-temperature feedback for Arctic amplification, it is hard to reconcile the timing and pattern The warming since 1980, shown in Figure 1 as a function of calendar month and latitude, of warming simply with an albedo is strongest over the Arctic Ocean (70-90ºN) during the period September-December. This feedback. Feldstein and Lee argue period coincides with the greatest loss of sea ice. The reduction of the reflective sea ice cover that much of the Arctic warming during the season of strong solar radiation enables the upper ocean to absorb heat for release can be explained by tropical back to the atmosphere during the autumn and early winter (Perovich and Richter-Menge variability. One direct cause of 2009), when cooling would be most rapid in the presence of sea ice. The signature of this release Arctic amplification is a weaker of stored heat by the high-latitude ocean is unmistakeable in Figure 1, which also shows a meridional temperature gradient. secondary maximum of warming in the northern high latitudes during spring. This maximum Francis and Overland discuss is consistent with the earlier disappearance of snow over northern land areas. Snow cover on how changes in the meridional land has decreased over the past several decades (Shi et al. 2013), especially in spring (Derksen temperature gradient may be and Brown 2012). As with the loss of sea ice over the ocean, the loss of springtime snow cover influencing mid-latitude weather. enables the less reflective land surface to absorb greater amounts of incoming solar radiation, And given the possible growing thereby contributing to warmer spring conditions in the northern high latitudes. Because land influence of Arctic variability on has a smaller heat capacity than the ocean, there is less seasonal lag in the warming relative to our weather, Riddle and Scaife and the loss of terrestrial snow cover compared to the loss of sea ice. Peings et al. discuss new sources of predictability on seasonal to decadal timescales. Finally, given large sea ice melt and increased sea ice variability, societal interest in sea ice predictability has grown, and Bitz and Stroeve summarize the prospects for long range forecasts. US CLIVAR VARIATIONS Editors: Mike Patterson and Kristan Uhlenbrock 1201 New York Ave NW, Suite 400 USWashington, CLIVAR Project DC 20005 Office Figure 1. Change of temperature (°C) over 1980-2013 as a function of calendar month and latitude. 202-787-1682 www.usclivar.org Values are differences between end point and starting point of linear trend lines. Source: NASA © 2014 US CLIVAR Goddard Institute for Space Studies, http://data.giss.nasa.gov/gistemp/. USUS CLIVARCLIVAR VARIATIONSVARIATIONS • Summer• Summer 2014 2014 • Vol. • 12,Vol. No. 12, 3 No. 3 2 US CLIVAR VARIATIONS Increased atmospheric humidity and associated reanalyses as well as rawinsonde data to document humidity downwelling radiation changes poleward of 60°N. While the increases varied by season and location, all sources showed increases of precipitable water Water vapor is a strong greenhouse gas. Increases in humidity in the surface-500 hPa layer over the period 1979-2010. Cohen can therefore be expected to result in additional trapping of et al. (2013) show that the recent increase is especially large in the infrared radiation emitted by the Earth. The corresponding September-October. increase in downwelling radiation will then enhance the warming of the surface. Even before the recent decline of sea ice, Francis and While the water vapor feedback appears to have emerged as a Hunter (2006) showed that variability of downwelling radiation contributor to Arctic amplification, changes in cloudiness are also was associated with sea ice variations on interannual timescales. considered to be candidates for feedbacks to climate change in Since a loss of sea ice leads to increased atmospheric moisture, high latitudes. However, Screen and Simmonds (2010) concluded which then increases the downwelling radiation and warming of that changes in cloudiness have played a much smaller role than the surface, the Arctic is a prime candidate for a manifestation of changes in sea ice and atmospheric water vapor in the recent the so-called “water vapor feedback” and amplification of surface Arctic warming, and this conclusion is supported by the more warming.
Load more

Recommended publications
  • Winds in the Lower Cloud Level on the Nightside of Venus from VIRTIS-M (Venus Express) 1.74 Μm Images
    atmosphere Article Winds in the Lower Cloud Level on the Nightside of Venus from VIRTIS-M (Venus Express) 1.74 µm Images Dmitry A. Gorinov * , Ludmila V. Zasova, Igor V. Khatuntsev, Marina V. Patsaeva and Alexander V. Turin Space Research Institute, Russian Academy of Sciences, 117997 Moscow, Russia; [email protected] (L.V.Z.); [email protected] (I.V.K.); [email protected] (M.V.P.); [email protected] (A.V.T.) * Correspondence: [email protected] Abstract: The horizontal wind velocity vectors at the lower cloud layer were retrieved by tracking the displacement of cloud features using the 1.74 µm images of the full Visible and InfraRed Thermal Imaging Spectrometer (VIRTIS-M) dataset. This layer was found to be in a superrotation mode with a westward mean speed of 60–63 m s−1 in the latitude range of 0–60◦ S, with a 1–5 m s−1 westward deceleration across the nightside. Meridional motion is significantly weaker, at 0–2 m s−1; it is equatorward at latitudes higher than 20◦ S, and changes its direction to poleward in the equatorial region with a simultaneous increase of wind speed. It was assumed that higher levels of the atmosphere are traced in the equatorial region and a fragment of the poleward branch of the direct lower cloud Hadley cell is observed. The fragment of the equatorward branch reveals itself in the middle latitudes. A diurnal variation of the meridional wind speed was found, as east of 21 h local time, the direction changes from equatorward to poleward in latitudes lower than 20◦ S.
    [Show full text]
  • Global Climate Influencer – Arctic Oscillation
    ARCTIC OSCILLATION GLOBAL CLIMATE INFLUENCER by James Rohman | February 2014 Figure 1. A satellite image of the jet stream. Figure 2. How the jet stream/Arctic Oscillation might affect weather distribution in the Northern Hemisphere. Arctic Oscillation Introduction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
    [Show full text]
  • Globe Lesson 10 - Latitude Zones - Grade 6+ Geographers Divide the Earth Into Latitude Zones
    Globe Lesson 10 - Latitude Zones - Grade 6+ Geographers divide the Earth into latitude zones. There are three latitude zones: - Low latitude zones - Middle latitude zones - High latitude zones There are 90 degrees of latitude. Each zone of latitude is 30 degrees wide. The Equator is 0 degrees. 0 to 30 are low numbers, 30-60 are middle numbers, and 60 to 90 are high numbers. This chart shows the arrangement of the zones in the Northern Hemisphere. Write in high, middle, and low latitude zones in the proper order in the Southern Hemisphere. Remember that the Equator is latitude 0 and the South Pole is latitude 90. Find the 180th meridian on your globe. On this line you will find the numbers of the printed parallels. Find 30 and 60 degrees north latitude. Draw a line of dashes around your globe on these lines. Find 30 and 60 degrees south latitude. Draw a line of dashes on these lines. These parallels divide the latitude zones. Label the zones Low, Middle and High in both the Northern and Southern Hemisphere on your globe. Finding Latitude Zones 4. In the following exercise identify the latitude with the proper latitude zone. "L" stands for low latitudes. "M" stands for middle latitudes. "H" stands for high latitudes. ______ 35°N ______ 23°N ______ 86°N ______ 15°N ______ 5°N ______ 66°N ______ 45°N ______ 28°N 5. In the following exercise, identify each city with the latitude zone where you find it. "L" stands for low latitudes. "M" stands for middle latitudes.
    [Show full text]
  • Monthly Weather Review June1960
    DEPARTMENT OF COMMERCE WEATHER BUREAU FREDERICK H. MUELLER, Secretary F. W.REICHELDERFER, Chief MONTHLYWEATHER REVIEW JAMESE. CASKEY, JR., Editor Volume 88 JUNE 1960 Closed August 15, 1960 Number 6 Issued September 15, 1960 THE SEASONAL VARIATION OF THE STRENGTH OF THE SOUTHERN CIRCUMPOLAR VORTEX W. SCHWERDTFEGER Department of Meteorology, Naval Hydrographic Service, Argentina [Manuscript received May 24, 1960; revised June 20, 19601 ABSTRACT The annual marchof the strengthof the southerncircumpolar. vortexis shown to be composed of a simple annual variation(with the maximumoccurring in late winter)which dominates in thestratosphere, and a semiannual variation with the maximum at the equinoxes, which is the dominating part in the troposphere. This behavior of the circumpolarvortex is considered to be the consequence of the seasonal variation of radiation conditions and of the different efficiency of meridional turbulent exchange in the troposphere and stratosphere. It is suggested that the semiannual variation of the tropospheric vortex is an essential feature of a planetary circulation. The annual march of pressure with opposite phase values at polar and middle latitudes, can be understood as a consequence of the formation and decay of the great circumpolar vortex. 1. INTRODUCTION part of the period which can now be considered. The Some aerological data of the Southern Hemisphere and South Pole station has been taken as representative of the particularly those from the South Pole (Amundsen-Scott inner part of the SCPV, in spiteof the fact that inseveral Station) obtained during theIGY and its extension through months the center of the vortex cannot be found exactly 1959, make it possible for the first time to arrive at an es- over the Pole.
    [Show full text]
  • Weather and Climate Science 4-H-1024-W
    4-H-1024-W LEVEL 2 WEATHER AND CLIMATE SCIENCE 4-H-1024-W CONTENTS Air Pressure Carbon Footprints Cloud Formation Cloud Types Cold Fronts Earth’s Rotation Global Winds The Greenhouse Effect Humidity Hurricanes Making Weather Instruments Mini-Tornado Out of the Dust Seasons Using Weather Instruments to Collect Data NGSS indicates the Next Generation Science Standards for each activity. See www. nextgenscience.org/next-generation-science- standards for more information. Reference in this publication to any specific commercial product, process, or service, or the use of any trade, firm, or corporation name See Purdue Extension’s Education Store, is for general informational purposes only and does not constitute an www.edustore.purdue.edu, for additional endorsement, recommendation, or certification of any kind by Purdue Extension. Persons using such products assume responsibility for their resources on many of the topics covered in the use in accordance with current directions of the manufacturer. 4-H manuals. PURDUE EXTENSION 4-H-1024-W GLOBAL WINDS How do the sun’s energy and earth’s rotation combine to create global wind patterns? While we may experience winds blowing GLOBAL WINDS INFORMATION from any direction on any given day, the Air that moves across the surface of earth is called weather systems in the Midwest usually wind. The sun heats the earth’s surface, which warms travel from west to east. People in Indiana can look the air above it. Areas near the equator receive the at Illinois weather to get an idea of what to expect most direct sunlight and warming. The North and the next day.
    [Show full text]
  • Shifting Westerlies to Shift After the Last Glacial Period? J
    PERSPECTIVES CLIMATE CHANGE What caused atmospheric westerly winds Shifting Westerlies to shift after the last glacial period? J. R. Toggweiler he westerlies are the prevailing ica-rich deep water must be drawn to the sur- winds in the middle latitudes of face. As mentioned above, silica-rich deep Earth’s atmosphere, blowing water tends to be high in CO . It is also T 2 from west to east between the high- warmer than the near-freezing surface pressure areas of the subtropics and waters around Antarctica. the low-pressure areas over the poles. A shift of the westerlies that draws They have strengthened and shifted more warm, silica-rich deep water to poleward over the past 50 years, pos- the surface is thus a simple way to sibly in response to warming from explain the CO2 steps, the silica pulses, rising concentrations of atmospheric and the fact that Antarctica warmed carbon dioxide (CO2) (1–4). Some- along with higher CO2 during the two thing similar appears to have happened steps. Anderson et al.’s two silica pulses 17,000 years ago at the end of the last ice occur right along with the two CO2 steps, age: Earth warmed, atmospheric CO2 in- which implies that the westerlies shifted creased, and the Southern Hemisphere wester- early as the level of CO2 in the atmosphere lies seem to have shifted toward Antarctica began to rise. Had the westerlies shifted in (5, 6). Data reported by Anderson et al. on response to higher CO , one would expect to Southward movement. At the end of the last ice 2 page 1443 of this issue (7) suggest that the see more upwelling and more silica accumula- on October 23, 2009 age, the ITCZ and the Southern Hemisphere wester- shift 17,000 years ago occurred before the lies winds moved southward in response to a flatter tion after the second CO2 step when the level of warming and that it caused the CO2 increase.
    [Show full text]
  • Chapter 7 – Atmospheric Circulations (Pp
    Chapter 7 - Title Chapter 7 – Atmospheric Circulations (pp. 165-195) Contents • scales of motion and turbulence • local winds • the General Circulation of the atmosphere • ocean currents Wind Examples Fig. 7.1: Scales of atmospheric motion. Microscale → mesoscale → synoptic scale. Scales of Motion • Microscale – e.g. chimney – Short lived ‘eddies’, chaotic motion – Timescale: minutes • Mesoscale – e.g. local winds, thunderstorms – Timescale mins/hr/days • Synoptic scale – e.g. weather maps – Timescale: days to weeks • Planetary scale – Entire earth Scales of Motion Table 7.1: Scales of atmospheric motion Turbulence • Eddies : internal friction generated as laminar (smooth, steady) flow becomes irregular and turbulent • Most weather disturbances involve turbulence • 3 kinds: – Mechanical turbulence – you, buildings, etc. – Thermal turbulence – due to warm air rising and cold air sinking caused by surface heating – Clear Air Turbulence (CAT) - due to wind shear, i.e. change in wind speed and/or direction Mechanical Turbulence • Mechanical turbulence – due to flow over or around objects (mountains, buildings, etc.) Mechanical Turbulence: Wave Clouds • Flow over a mountain, generating: – Wave clouds – Rotors, bad for planes and gliders! Fig. 7.2: Mechanical turbulence - Air flowing past a mountain range creates eddies hazardous to flying. Thermal Turbulence • Thermal turbulence - essentially rising thermals of air generated by surface heating • Thermal turbulence is maximum during max surface heating - mid afternoon Questions 1. A pilot enters the weather service office and wants to know what time of the day she can expect to encounter the least turbulent winds at 760 m above central Kansas. If you were the weather forecaster, what would you tell her? 2.
    [Show full text]
  • Summer Westerly Jet in Northern Hemisphere During the Mid-Holocene: a Multi-Model Study
    atmosphere Article Summer Westerly Jet in Northern Hemisphere during the Mid-Holocene: A Multi-Model Study Chuchu Xu 1, Mi Yan 1,2,3,*, Liang Ning 1,2,3,4 and Jian Liu 1,2,5 1 Key Laboratory for Virtual Geographic Environment, Ministry of Education, State Key Laboratory Cultivation Base of Geographical Environment Evolution of Jiangsu Province, Jiangsu Center for Collaborative Innovation in Geographical Information Resource Development and Application, School of Geography, Nanjing Normal University, Nanjing 210023, China; [email protected] (C.X.); [email protected] (L.N.); [email protected] (J.L.) 2 Open Studio for the Simulation of Ocean-Climate-Isotope, Qingdao National Laboratory for Marine Science and Technology, Qingdao 266237, China 3 State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi’an 710061, China 4 Climate System Research Center, Department of Geosciences, University of Massachusetts, Amherst, MA 01003, USA 5 Jiangsu Provincial Key Laboratory for Numerical Simulation of Large Scale Complex Systems, School of Mathematical Science, Nanjing Normal University, Nanjing 210023, China * Correspondence: [email protected]; Tel.: +86-1860-252-4134 Received: 17 August 2020; Accepted: 25 October 2020; Published: 3 November 2020 Abstract: The upper-level jet stream, a narrow band of maximum wind speed in the mid-latitude westerlies, exerts a considerable influence on the global climate by modulating the transport and distribution of momentum, heat and moisture. In this study by using four high-resolution models in the Paleoclimate Modelling Intercomparison Project phase 3, the changes of position and intensity of the northern hemisphere westerly jet at 200 hPa in summer during the mid-Holocene (MH), as well as the related mechanisms, are investigated.
    [Show full text]
  • Interactions of Middle Latitude Troughs and Tropical Disturbances on 4-6 Week Time Scales
    The 87th AMS Annual Meeting, AMS Forum: Climate Variations and Change Manifested by Changes in Weather, 15-18 January 2007, San Antonio, TX 3.3 INTERACTIONS OF MIDDLE LATITUDE TROUGHS AND TROPICAL DISTURBANCES ON 4-6 WEEK TIME SCALES John Molinari* and David Vollaro Department of Earth and Atmospheric Sciences The University at Albany/SUNY Albany, New York 1. INTRODUCTION: 3. EVOLUTION OF LOWPASS-FILTERED CLOUDINESS: A number of studies have examined the impact of upper tropospheric troughs reaching the Figure 1 shows a sequence of maps of subtropics and tropics during Northern Hemisphere lowpass-filtered OLR once every 4 days. Figure 1a winter. Webster and Holton (1982) noted that such indicates the lowpass representation of the quasi- propagation most likely occurs in the presence of stationary frontal zone on 10 July, extending upper tropospheric westerlies (the "westerly duct"), northeastward from 30ºN, 150ºE. Over the next 8 and is generally prevented by the presence of upper days (Figs. 1b,c), the convection extended tropospheric easterlies. Kiladis (1998) examined equatorward along 150ºE and a separate convective troughs moving equatorward in the eastern Pacific. maximum began to develop near 20ºN. Thereafter Only the upper tropospheric component of the trough the separate convective maximum broke away from reached the subtropics, effectively narrowing the its midlatitude origins (Fig 1d), intensified and grew vertical scale of the trough. Plots of "e vectors" in area (Figure 1e), and moved westward along 20ºN (Hoskins and Ambrizzi 1993) showed that wave (Figures 1e-1h). Throughout the time the convective activity at 200 hPa penetrated to within 10 degrees of maximum moved westward, it was accompanied by a the equator in the upper troposphere.
    [Show full text]
  • Working with Maps, Globes, and Other
    CK_4_TH_HG_P087_242.QXD 10/6/05 9:01 AM Page 93 At a Glance The most important ideas for you are: ◗ Students can use scales on maps and globes to measure distance. ◗ Students can use longitude and latitude coordinates to locate places on maps and globes. ◗ The Prime Meridian is located at 0º longitude, and the International Date Line, which generally corresponds to 180º longitude, marks the change in days from east to west. ◗ Relief maps are special-purpose maps that indicate elevations and depressions in land height. ◗ Major mountain ranges by continent include the Andes (South America), Rockies and Appalachians (North America), Himalayas and Urals (Asia), Atlas (Africa), and Alps (Europe). ◗ High mountains of the world by continent are Everest (Asia), McKinley (North America), Aconcagua (South America), Mont Blanc (Europe), and Kilimanjaro (Africa). What Teachers Need to Know Teaching Idea Background Review map-reading skills and The study of geography embraces many topics throughout the Core concepts from previous grades Knowledge Sequence, including topics in history and science. Geographic as needed. knowledge includes a spatial sense of the world, an awareness of the physical processes to which people culturally adapt, a sense of the interactions between humans and their environment, an understanding of the relations between place and culture, and an awareness of the characteristics of specific regions and cultures. Many geographic topics are listed throughout the World History Cross-curricular and Geography Sequence in connection with historical topics. Teaching Idea Throughout this section, students should connect the “abstract” concepts Compare the distance using map to something more concrete, such as a country of interest or a topic of histor- scale (usually measured in a straight ical study in this grade.
    [Show full text]
  • The General Circulation of the Atmosphere
    Chapter 8 The general circulation of the atmosphere In this chapter we return to our discussion of the large-scale circulation of the atmosphere and make use of the dynamical ideas developed in the previous two chapters to enquire into its cause. We begin by reviewing the demands on the atmospheric circulation imposed by global energy and angular mo- mentum budgets as depicted in Fig.8.1.Theatmospheremusttransport energy from equator to pole to maintain the observed pole-equator tempera- ture gradient. In addition, because there are westerly winds at the surface in middle latitudes and easterly winds in the tropics (see, e.g., Fig.7.28) angu- larmomentummustbetransportedfromthe tropics to higher latitudes. We discuss how this transfer is achieved by the Hadley circulation in the trop- ics and weather systems in middle latitudes. We will discover that weather systems arise from a hydrodynamic instability of the thermal wind shear associated with the pole-equator temperature gradient. Produced through a mechanism known as baroclinic instability, the underlying dynamics are illustrated through laboratory experiment and discussed from the perspec- tive of the available potential energy ‘stored’ by the horizontal temperature gradients. 8.1 Understanding the observed circulation The simplest observed global characteristic of the atmosphere is that the tropics are much warmer than the poles. As discussed in Chapter 5, this 249 250CHAPTER 8. THE GENERAL CIRCULATION OF THE ATMOSPHERE Figure 8.1: Latitudinal transport of (left) heat and (right) angular momentum implied by the observed state of the atmosphere. In the energy budget there is a net radiative gain in the tropics and a net loss at high latitudes; in order to balance the energy budget at each latitude, a poleward heat flux is implied.
    [Show full text]
  • 1 Introduction
    1 Introduction In this chapter we revisit one of the “classical”topics of atmospheric dynamics: the maintenance of the zonal ‡ow relative to the rotating Earth. The literature on this topic, discussed at length in the monograph of Lorenz (1967), dates back over 300 years and includes work of Edmund Halley (of Halley’scomet), George Hadley (of the Hadley cell), and William Ferrell (of the Ferrell cell). Most of the early work on this topic was restricted to consideration of the role of mean meridional circulations in the transport of angular momentum within the atmosphere, a line of inquiry that proved inconclusive because mean meridional circulations are not the only component of the atmospheric circulation that plays a role in the transport. It was not until the mid-20th century that the role of synoptic and planetary- scale eddies in the transport of atmospheric angular momentum was fully appreciated, and upper air data became available for making quantitative estimates of the eddy transports. The …rst estimates of the poleward eddy ‡uxes of westerly momentum were made using the formalism [uv] = [u][v] + [uv] + u0v0 which is derived in Appendix 1. Estimates of time-averaged terms u, v, and 1 u0v0 derived from time series of station data and subsequently zonally averaged [( )]. In these estimates, u0v0 was interpreted as the transient eddy term, under the assumption that the term [u]0 [v]0 is negligibly small. This formalism was popular before the days of gridded datasets because it was much less labor intensive than the other decompositions, in which the laborious zonal averaging must performed multiple times before the time averaging.
    [Show full text]