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ATM OCN 100 - Summer 2002 LECTURE 18

ATM OCN 100 - Summer 2002 LECTURE 18. THE THEORY OF WINDS: PART II - FUNDAMENTAL FORCES A. INTRODUCTION How do winds originate? What factors influence the winds?. B. EXPLANATIONS of ATMOSPHERIC MOTION. Practical Problems Historical Concepts Forces of Motion & Newton's Laws.

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ATM OCN 100 - Summer 2002 LECTURE 18

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  1. ATM OCN 100 - Summer 2002LECTURE 18 THE THEORY OF WINDS: PART II - FUNDAMENTAL FORCES A. INTRODUCTION • How do winds originate? • What factors influence the winds?

  2. B. EXPLANATIONS of ATMOSPHERIC MOTION • Practical Problems • Historical Concepts • Forces of Motion & Newton's Laws

  3. NEWTON’S EQUATIONS of MOTION • 1st Law(Conservation of Inertia)Object at rest will remain at rest or object moving at constant velocity will continue until acted upon by a net force. • 2nd LawForce = mass x acceleration. • 3rd LawFor every action, an equal & opposite reaction exists.

  4. B. EXPLANATIONS of ATMOSPHERIC MOTION (con’t.) • Implications of Newtonian Laws • Vectors, Forces and Units • Velocity -- a vector (speed & direction) • Speed or magnitude of velocity-- a scalar[mph or meters per second, etc.] • Acceleration or rate of change of a velocity vector -- a vector[ft/sec/sec or meter/sec2] • Force -- a vector-- What causes a mass to accelerate.[pounds, or Newtons]

  5. C. DESCRIBING ATMOSPHERIC MOTION • Reasons for Atmospheric Motions: • Buoyancy Effects or Dynamic Effects

  6. C. DESCRIBING ATMOSPHERIC MOTION • Complications involved with Atmospheric Motion: • Spherical planet; • Rotating planet & non-inertial frame of reference.

  7. An example of an equation of motionNASA

  8. DESCRIBING ATMOSPHERIC MOTION(con’t.) • Three-Dimensional Equation of Motion for the Atmosphere • A vector equation; • Entails specification of all forces per unit mass (i.e., equivalent to acceleration); • All forces do not act alone; • Vector sum of individual forces equals net force.

  9. Numerical Weather Prediction

  10. Numerical Weather Prediction

  11. Numerical Weather Prediction

  12. FORCES ASSOCIATED WITH ATMOSPHERIC MOTION • Following forces influence motion of air parcels: • Pressure Gradient Force • Gravitational Force or Gravity • Coriolis Effect or "Force" • Frictional Force or Friction • Centripetal Forceor more specifically --

  13. PRESSURE GRADIENT FORCE • Generated by differences in pressure within a fluid element; • Responsible for initiation ofall air motion;

  14. Low Pressure High Pressure Explaining Differences in Air Pressure

  15. PRESSURE GRADIENT FORCE(con’t.) • A 3-dimensional vector that has: • Magnitudeof pressure gradient force vector depends: • directly upon difference in pressure over a given distance (i.e., slope or grade equals “pressure gradient”). • Directionof pressure gradient force vector is: • fromHigh pressure to Low pressure, • along steepest direction of pressure gradient.

  16. PRESSURE GRADIENT FORCE(con’t.)

  17. GRAVITATIONAL FORCE or GRAVITY • Produced by mutual physical attraction between massive bodies; • Gravity refers to acceleration; • Acts continuously, regardless of motion; • A vector quantity that has: • Direction – toward center of earth. • Magnitude ~ 9.8 m/s2 (32 ft/s2)

  18. CORIOLIS EFFECT or FORCE • Produced by earth’s rotation; • A “fictitious force” used to explain apparent deflection of moving object on a rotating frame of reference;

  19. CORIOLIS EFFECT or FORCE • Produced by earth’s rotation; • A “fictitious force” used to explain apparent deflection of moving object on a rotating frame of reference;

  20. CORIOLIS EFFECT or FORCE(con’t.)Speed is dependent upon latitude:

  21. An example of the Coriolis EffectFig. 9.5 Moran & Morgan (1997) Time 1 Time 2

  22. CORIOLIS EFFECT or FORCE(con’t.)

  23. Coriolis Effects upon the WindFig. 9.6 Moran & Morgan (1997)

  24. CORIOLIS EFFECT or FORCE(con’t.) • Produced by earth’s rotation; • A “fictitious force” used to explain apparent deflection of moving object on a rotating frame of reference; • Acts only after motion is initiated; • Can only modify direction of motion; • A 3-dimensional vector, but consider only horizontal component described by:

  25. CORIOLIS EFFECT or FORCE(con’t.) • Magnitudeof horizontal Coriolis force vector depends upon: • Rotation rate of earth (Direct relationship); • Speed of object;(Direct relationship) • Latitude (specifically, sine of latitude).

  26. CORIOLIS EFFECT or FORCE(con’t.) • Directionof horizontal component of Coriolis force vector: • Causes a deflection of moving object to rightof direction of motion in Northern Hemisphere;but • Deflects moving object to leftof intended motion in Southern Hemisphere.

  27. FRICTIONAL FORCE or FRICTION • Produced by “viscosity” (interactions of moving fluid elements with one another or with a boundary surface) due to: • random molecular motions; • large random turbulent motions of fluid associated with either: • thermal turbulence • mechanical turbulence

  28. An example of Turbulent ViscosityFig. 9.5 Moran & Morgan (1997)

  29. FRICTIONAL FORCE(con’t.) • Acts only after motion is initiated; • Acts to retard motion; • Magnitude of friction force vector depends upon: • Speed of motion of fluid; • Type of surface, e.g., “surface roughness”; • Temperature structure of fluid. • Directionof friction force vector is • opposite motion vector.

  30. Relative Surface RoughnessSource: Stull, 1995

  31. Centripetal ForceFig. 9.3 Moran & Morgan (1997)

  32. CENTRIPETAL FORCE • Produces curved motion; • Opposite the “centrifugal force”; • Acts only after motion is initiated;In reality, a net force Used to describe imbalance of other forces in curved motion;

  33. CENTRIPETAL FORCEVECTOR(con’t.) • Centripetal force vector is described by: • Magnitude of centripetal force vector depends upon: • Speed of instantaneous motion(a direct relationship); • Radius of curvature(an inverse relationship). • Direction of centripetal force vector is • inward toward center of curvature.

  34. SUMMARIZING • A 3-D Equation of Motion for Atmosphere (in word form): Net force = Pressure gradient force + gravitation force + Coriolis force + friction. • Notes: • The above is a vector equation! • Since a unit mass is used, force is equivalent to an acceleration.

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