Hydrologic cycle . The numbers attached to the stages express each value as the volume - PowerPoint Presentation

1. Hydrologic cycle. The numbers attached to the stages express each value as the volume of water divided by Earth surface area. Thus the values shown represent the depth of water (centimeters per year) associated with each mass transfer. All can be directly compared to the global average precipitation rate, which is about 100 cm/year. Fig 12.2

2. Distribution of water in the hydrosphere. The middle and lower bars show the percentage distribution of the 2.8 percent of total hydrospheric water that is fresh. Of that freshwater component, only about one-tenth is easily available to humans. Water in the HydrosphereMost of the water is salt water in the oceanMost of the fresh water is locked up in ice sheets and glaciersMost of the liquid fresh water is in the groundFig 12.3

3. Total water withdrawals (millions gallons per day) for the United States in 2005.Water Usage in the United States, 2005Which states use the most water?

4. Condensation near the ground forms fog, a cloud in contact with the ground.As the ground and surface air cools to the dewpoint, water vapor condenses into a radiation fog (cooling by longwave radiation overnight) here in East Africa.

5. Schematic diagram of the different cloud types – stratus, cumulus, and cirrus, arranged by their typical altitude.Cloud Types

6. Precipitation ProcessesThe Ice-Crystal Process-requires the coexistence of ice and super-cooled water droplets in the cloud. Ice grows at the expense of water droplets that evaporate water molecules which adhere to the ice until they are large enough to fall as snow. If the air is warm enough, the snow melts and rain occurs.The Coalescence Process-requires different sizes of water droplets within warm clouds. Larger droplets grow by falling faster and sweeping up smaller droplets by coalescing until they are large enough to fall as rain.Source: http://collider.com/singin-in-the-rain-60th-anniversary-blu-ray-review/191992/

7. Four major forms of precipitation. (A) A rainstorm douses the Ponderosa Pine Forest near Flagstaff, Arizona. (B) Falling snow accumulates in south-central Alaska. (C) Freezing rain forms an icy coating on pine needles on a golf course in Wawona, near Yosemite National Park, California. (D) Golf-ball-sized hailstones litter the countryside following a storm in northern Texas.Besides rain and snow, there is: Sleet-melting ice that refreezes before reaching groundFreezing rain-melting ice that freezes on contact with a frozen surfaceHail-ice particles that grow within clouds that have strong updraftsGraupel-soft, partially melted hailSource: http://climate.met.psu.edu/features/Hail/PEMA_hail.phpTypes of Precipitation

8. Four Forms of PrecipitationABCDA-rainstorm B-snowC-freezing rainD-hail

9. Range of water balance conditions found at the surface of Earth. (A) Baghdad, Iraq, experiences a constant deficit because potential evapotranspiration normally exceeds precipitation. (B) At Tokyo, Japan, the situation is reversed, and a constant water surplus is recorded. (C) At Faro, Portugal, the intermediate situation occurs, with a combination of surplus and deficit at different times of the year.Water Balance for Different Climates

10. Water Balance Averages by LatitudeAverage annual latitudinal distribution of precipitation, evapotranspiration, and runoff in cm per year. The arrows show the direction of the water vapor flux by the atmospheric circulation.

11. Global distribution of annual evaporation and evapotranspiration in centimeters, with land elevations adjusted to sea level. Red isolines show the pattern over land; blue isolines over the oceans. Global Distribution of Annual Evaporation, EvapotranspirationFig 12.10?

12. Global Distribution of Annual PrecipitationGlobal distribution of annual precipitation in millimeters/day.Source: http://www-das.uwyo.edu/~geerts/cwx/notes/chap10/global_precip.html

13. Air MassesAn air mass is a large body of air with relatively homogeneous character of temperature and humidity.Classification by latitude, moisture mT, mP, cA, cP, cTMovement and transitions-character of air masses can change as moves over different land surfaces, or crosses mountains, ie mP can become cP after crossing the Rockies, cP can become mT when moving over warm water.Source: https://www.meted.ucar.edu/sign_in.php?go_back_to=http%253A%252F%252Fwww.meted.ucar.edu%252Ffire%252Fs290%252Funit7%252Fprint_3.htm

14. Source regions and common paths of the principal air masses that affect the continental United States. North American Air Masses & Sources

15. Lifting Mechanisms That Produce PrecipitationConvergence-when similar air masses converge, they are forced to rise, forming cloudsConvection-surface heating causes warm air parcel to rise and form cloudsOrographic-mountains and large obstacles force air to rise, forming cloudsFrontal-when warm and cold air masses meet, cold air lifts warmer air forming cloudsSource: http://keithrogershome.com/Chap7CldsPcpnFog.html

16. Lifting by ConvergenceAlong the ITCZ warm trades meet and rise. Precipitation along the ITCZ shifts with season, into the summer hemisphere.Average daily rainfall rates (mm/day) for January and July based upon measurements from the Tropical Rainfall Measuring Mission (TRMM) satellite for the years 1998-2007.

17. Vertical cross-section through a warm front (top) and cold front (bottom). The vertical scale is greatly exaggerated. Warm fronts typically have a 1:200 vertical-to-horizontal ratio; the ratio for cold fronts is approximately 1:70.Frontal Precipitation

18. Convectional PrecipitationConvection often leads to isolated showers from building cumulus clouds. Occasionally, these clouds grow large enough to form thunderstorms. Each thunderstorm cloud, cumulonimbus, has a life cycle of 3 stages.The three stages of the life cycle of an air mass thunderstorm: cumulus, mature, and dissipating. Updrafts dominate the developing stage, both updrafts and downdrafts are found during the mature stage, while only downdrafts are found during the dissipating stage. The approximate width at each stage of the thunderstorm is shown at the bottom.

19. Cumulonimbus grows near the Canadian Rockies in an afternoon thunderstorm. Source: http://www.physicalgeography.net/fundamentals/7t.html

20. Severe ThunderstormsConceptual model of a severe thunderstorm producing sizeable hailstones. The red dashed lines represent the warm updrafts, the blue lines show the cold downdrafts, and the green lines represent the movement of hailstones. The thunderstorm is moving from left to right.

21. Orographic precipitation on the upper windward slope of the Cascade Mountains in west-central Oregon. Note the significant temperature and moisture differences between the windward and leeward sides of this major mountain barrier. (Vertical scale is greatly exaggerated.)Orographic PrecipitationFig 13.7

22. Oregon’s precipitation pattern, with the distribution of isohyets exhibiting the results of the orographic effect as westerly winds off the Pacific are forced across the north-south-trending Cascade Mountains. The transect across the Cascades between Eugene and Bend, diagrammed in Fig. 12.10, is marked by a red line. Fig 13.8

23. The trough axis marks where the trades are converging with rising motion behind the westward moving wave, and where divergence and sinking motion occur ahead of the wave axis. Heaviest precipitation occur in the convergence zone, while mostly sunny conditions precede the axis.Easterly WavesEasterly waves are disturbances within the trades that can produce heavy rainfall and potentially can form into tropical storms and hurricanes.Source: http://www.geography.hunter.cuny.edu/~tbw/wc.notes/11.hurricanes/easterly_wave_atl.htm

24. Tropical Storms and HurricanesTropical cyclones can form over land or water, however hurricanes always develop over warm oceans. As cyclones increase their energy, their winds increase. Storms are defined by wind speed:Tropical Depression-winds below 40 mphTropical Storm-winds 40 to 74 mphHurricane-winds exceed 74 mphHurricanes may form ifThey occur over warm water-80F or 28CThere is an initial disturbance (ITCZ, convergence, mid-latitude cycloneThere is sufficient Coriolis force. Most hurricanes form in 8-15 degrees latitudeThere are weak upper air winds. Strong flow destroys formation.Hurricanes can form over all tropical oceans where these conditions are met.

25. The eye of Hurricane Mitch is still over water, but this 1998 storm is poised to strike Central America and will become the costliest natural disaster in the modern history of the western hemisphere. Honduras will be hit hardest, with nearly 10,000 deaths When it is over, nearly one-quarter of the country’s 6.4 million people will be homeless, and most of the agricultural economy will be ruined. Fig 14.2

26. Cross-sectional view of a hurricane showing its mechanics and component parts. Fig 14.3

27. Storm tracks of weak and severe tropical cyclones from 150 years through 2006. Weaker systems, shown in blue and yellow, occur near the Equator, during their early stages of development, and over land and in the middle latitudes as they lose energy and weaken. The steering of these systems by the easterly trade winds within the tropics, and the westerlies as they move into the middle latitudes is apparent. Category 4 and 5 hurricanes are most common in the western North Pacific Ocean.Historic Tropical Storm and Hurricane Tracks

28. 500-mb map for North America in November. The lines show the height of the 500-mb level in meters above the surface (ex. 92 equals 5920 m). There is a ridge along the W. coast with troughs over central and E. coast US. Dashed lines are temperatures in Celsius.Rossby Waves in the Upper Atmosphere Westerlies

29. Relationship between the Polar jet stream and surface pressure patterns. (A) Position of the jet stream 9000 m (30,000 ft) above North America. (B) Associated air movement around points X and Y in vertical cross section. (C) Resulting surface pressure conditions. Polar Jet Stream and Surface Weather

30. Life Cycle of a Mid-latitude CycloneSource: http://www.geography.hunter.cuny.edu/~tbw/wc.notes/9.weather.patterns/mid_cyclone_stages.htm