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NATS 101 Lecture 12 Vertical Stability

NATS 101 Lecture 12 Vertical Stability. Ball speed leaving. Racket velocity before hit. Forehand:. Ball speed approaching. Ball speed leaving. Racket velocity before hit. Drop Shot:. Ball speed approaching. Tennis Basics. Piece of cake, right?. Boundary velocity. Molecule speed leaving.

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NATS 101 Lecture 12 Vertical Stability

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  1. NATS 101Lecture 12Vertical Stability

  2. Ball speed leaving Racket velocity before hit Forehand: Ball speed approaching Ball speed leaving Racket velocity before hit Drop Shot: Ball speed approaching Tennis Basics Piece of cake, right?

  3. Boundary velocity Molecule speed leaving Molecule speed approaching Molecule speed leaving Boundary velocity Molecule speed approaching Air Molecules Act Similarly Contracting Boundary: Expanding Boundary:

  4. Rising air parcel expands Expansion requires work against outside air Air molecules rebound from “walls” at a slower speed, resulting in a cooler temperature Assuming no transfer of heat across parcel walls (adiabatic expansion), cooling rate is 10oC/km Rising Air Cools-Sinking Air Warms no heat transfer 494 m/s 10oC 502 m/s 502 m/s 494 m/s 8 m/s 1 km Rising Expanding Sinking Contracting 20oC 502 m/s Ahrens, Fig 5.2

  5. Adiabatic Cooling-Warming Dew point decreases with height at a rate of2oC/km b/c DP varies less with Pressure than Temp. The rate is much less than cooling rate for air. Thus, unsaturated air can become saturated IF it rises far enough. 10C10C 20C 12C 30C14C Ahrens, Fig 5.2 Red=TemperatureBlue=Dew Point

  6. As a saturated parcel rises and expands, the release of latent heatmitigates the adiabatic cooling Cooling for saturated air varies with mixing ratio. We will use an average value of6oC/kmfor moisture lapse rate Note:sinking air always warms atdry lapse rate Rising, Saturated Air Cools Less no heat transfer 14oC 497 m/s 502 m/s latent heating 497 m/s 502 m/s 5 m/s 1 km Rising Expanding Sinking Contracting 20oC 502 m/s Ahrens, Fig 5.2

  7. Moist Flow over a Mountain +10C +2C DAR -6C -6C MAR saturated -6C -6C MAR unsaturated +10C +2C DAR unsaturated -10C-2C DAR +10C +2C DAR Ahrens, Fig 5.12 These concepts can be applied to understand Temp and DP changes for moist flow over a mountain

  8. Brain Burners Rising unsaturated air, and all sinking air Temp changes at Dry Adiabatic Rate (DAR) of 10oC/km Dew point changes at rate of 2oC/km Rising saturated air Temp cools atMoist Adiabatic Rate(MAR) of6oC/km Dew point decreases at rate of6oC/km

  9. Concept of Stability StableRock always returns to starting point UnstableRock never returns to starting point Conditionally UnstableRock never returns if rolled past top of initial hill Ahrens, Fig 5.1

  10. Archimedes’ Principle • Archimedes' principle is the law of buoyancy. It states that"any body partially or completely submerged in a fluid is buoyed up by a force equal to the weight of the fluid displaced by the body." • The weight of an object acts downward, and the buoyant force provided by the displaced fluid acts upward. If the density of an object is greater/less than the density of water, the object will sink/float. • Demo: Diet vs. Regular Soda. http://www.onr.navy.mil/focus/blowballast/sub/work2.htm

  11. Absolutely Stable: Top Rock Stable air strongly resists upward motion External force must be applied to an air parcel before it can rise Clouds that form in stable air spread out horizontally in layers, with flat bases-tops Ahrens, Fig 5.3

  12. Absolutely Unstable: Middle Rock Unstable air does not resist upward motion Clouds in unstable air stretch out vertically Absolute instability is limited to very thin layer next to ground on hot, sunny days Superadiabatic lapse rate Ahrens, Fig 5.5

  13. Conditionally Unstable: Lower Rock Ahrens, Fig 5.7

  14. Environmental Lapse Rate (ELR) ELR is the Temp change with height that is recorded by a weather balloon 6.5o C/km 6.0o C/km ELR is 6.5o C/km, on average, and thus is conditionally unstable! 10.0o C/km ELR is absolutely unstable in a thin layerjust above the ground on hot, sunny days Ahrens, Meteorology Today 5th Ed.

  15. Summary: Key Concepts I Rising unsaturated air, and all sinking air Temp changes at DAR of 10oC/km DP changes at rate of 2oC/km Saturation occurs with sufficient lifting Rising saturated air Latent Heating Mitigates Adia. Cooling Temp and DP cools at MAR of 6oC/km Note that MAR is always less than DAR

  16. Summary: Key Concepts II Vertical Stability Determined by ELR Absolutely Stable and Unstable Conditionally Unstable Temp Difference between ELR and Air Parcel, and Depth of Layer of Conditionally Instability Modulates Vertical Extent and Severity of Cumulus

  17. Assignment for Next Lecture • Topic - Precipitation Processes • Reading - Ahrens p121-134 • Problems - 5.14, 5.16, 5.17

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