@j_bertolotti I know very little also! This is one interesting reference: https://t.co/Ns9JpioTmV
RT @TSUJINO_SATOKI: 渦位で見る傾圧渦の藤原効果 https://t.co/FBFzx1z61D 基本は上層の渦位アノマリが地表低気圧の回転を決めている.
RT @TSUJINO_SATOKI: 渦位で見る傾圧渦の藤原効果 https://t.co/FBFzx1z61D 基本は上層の渦位アノマリが地表低気圧の回転を決めている.
渦位で見る傾圧渦の藤原効果 https://t.co/FBFzx1z61D 基本は上層の渦位アノマリが地表低気圧の回転を決めている.
RT @ScottDuncanWX: The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. W…
RT @ScottDuncanWX: The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. W…
RT @ScottDuncanWX: The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. W…
RT @ScottDuncanWX: The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. W…
RT @ScottDuncanWX: The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. W…
RT @ScottDuncanWX: The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. W…
The complexity of this synoptic setup though... The relative vorticity is a great map to follow key weather features. We could be looking at examples of 'contact binary systems'. Where cyclones dance around each other, similar to the Fujiwhara effect --&g