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Download 02-12-2014 Forces and Wind
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MIDTERM 1: TOTAL POINTS = 45 AVERAGE = 33.5 HIGH SCORE = 44 APPROXIMATE GRADES 38.5 – 45.0 = A 30.0 – 38.0 = B 21.0 – 29.0 = C < 21.0 NP Newton’s Laws of Motion 1) 2) Object at rest remains at rest; Object in motion remains in motion; As long as no NET force exerted on object. F = m • a Force = mass x acceleration F, a are vectors (magnitude and direction) Direction of Motion so, F is the NET force F1 FNET F2 Forces to consider: 1) Pressure Gradient Force 2) Coriolis Force 3) Centripetal Force 4) Friction Force Force is a VECTOR!! It has a magnitude AND a direction Pressure Gradient Force (PGF) pressure change in pressure = gradient distance PGF is directed from HIGH pressure to LOW pressure at right angles to isobars. isobars PGF H L 1008 mb 1004 mb Clicker Question Set Frequency to "AD" At which location is the pressure gradient force (PGF) largest? (A) A (B) B A B (C) Same PGF at A and B isobars (4mb interval) Clicker Question Set Frequency to "AD" At which location is the pressure gradient force (PGF) largest? (A) A (B) B A B (C) Same PGF at A and B At "A", the distance between isobars is smallest, so pressure isobars (4mb interval) gradient is largest PGF ~ ∆P / distance Set Frequency to "AD" Clicker Question N HIGH San Diego LOW isobars What would be the wind direction? (A) to the north (B) to the east (C) to the west (D) to the south W E S Set Frequency to "AD" Clicker Question N HIGH San Diego LOW isobars What would be the wind direction? (A) to the north (B) to the east (C) to the west (D) to the south W E S MIT Coriolis Movie Coriolis Force: An "apparent" force we add to compensate for viewing motion on a rotating reference frame http://www.classzone.com/books/earth_science/terc/content/visualizations/es1904/es1904page01.cfm?chapter_no=visualization http://www.fccj.info/gly1001/animations/Chapter18/Coriolis Coriolis Force important when length-scale is large (100-1000’s of km) Coriolis Force (CF) - Deflect objects to right in Northern Hemisphere - Deflect objects to left in Southern Hemisphere - Zero at equator - Maximum at poles - Proportional to speed of object - Acts at right angles to direction of motion If interested: CF = 2 m Ω V sin(φ) m = mass of object Ω = rotation rate of Earth V = Velocity of object φ = latitude What to know for this class Geostrophy: Balance between Pressure Gradient force and Coriolis force Consider straight isobars and ignore friction for now. Low Pressure High Pressure Low Pressure Initially, no motion, so only force to start with is the PGF High Pressure Low Pressure PGF Initially, no motion, so only force to start with is the PGF High Pressure At point 0 V0 = 0 Low Pressure Air begins to move in direction of PGF. PGF V1 At point 1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure Air begins to move in direction of PGF. - PGF remains the same, but... PGF V1 At point 1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure Air begins to move in direction of PGF. - PGF remains the same, but... - Now there is a Coriolis Force PGF V1 At point 1 CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V1 At point 1 NET CF1 V1 > 0 Air begins to move in direction of PGF. - PGF remains the same, but... - Now there is a Coriolis Force - Net force is combo of CF and PGF PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V1 At point 1 NET CF1 V1 > 0 Air begins to move in direction of PGF. - PGF remains the same, but... - Now there is a Coriolis Force - Net force is combo of CF and PGF - Velocity increases and changes direction PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V2 Air moves in direction of NET force At point 2 V 2 > V1 PGF V1 At point 1 NET CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V2 At point 2 V 2 > V1 CF2 PGF V1 At point 1 Air moves in direction of NET force - Coriolis perpendicular and proportional to velocity NET CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V2 NET At point 2 V 2 > V1 CF2 PGF V1 At point 1 Air moves in direction of NET force - Coriolis perpendicular and proportional to velocity - NET force adjusts and bends more NET CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V3 PGF V2 NET At point 2 V 2 > V1 CF2 PGF V1 At point 1 As NET force bends, so does the velocity NET CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V3 PGF V2 NET At point 2 V 2 > V1 CF2 PGF V1 At point 1 CF3 As NET force bends, so does the velocity - Coriolis Force keeps changing direction as velocity change NET CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF V3 PGF NET V2 NET At point 2 V 2 > V1 CF2 PGF V1 At point 1 CF3 NET As NET force bends, so does the velocity - Coriolis Force keeps changing direction as velocity change - and NET force also adjusts CF1 V1 > 0 PGF High Pressure At point 0 V0 = 0 Low Pressure PGF PGF PGF V3 PGF NET V2 NET At point 2 At point 1 CF3 CF2 NET CF1 V1 > 0 Finally, Coriolis force is equal and opposite of the PGF - Now, no net force - Velocity remains constant - Velocity is parallel to the isobars PGF High Pressure At point 0 CF V 2 > V1 PGF V1 V V0 = 0 GEOSTROPHIC WIND - Straight isobars; no friction - Balance between Pressure Gradient Force and Coriolis Force LOW PGF WIND isobars Coriolis Force HIGH GRADIENT WIND isobars WIND LOW PGF V2/R HIGH Coriolis Force PGF = CF + V2/R (Flow around Low Pressure)
