ATPL Meteorology - Class 11: Wind I.

ATPL class

10 Jun 202217:46

Summary

TLDRThis educational video delves into the science of wind, a crucial factor for pilots. It explains how wind forms due to pressure differences and temperature variations, with air moving from high to low pressure areas. The video introduces the pressure gradient force (PGF) and the geostrophic wind, influenced by Earth's rotation, which causes wind to veer right in the northern hemisphere and left in the southern hemisphere due to the Coriolis effect. It also discusses the impact of friction on wind speed and direction near the surface, and how these factors are essential for understanding wind limitations in aviation.

Takeaways

🌪️ Wind is primarily formed due to pressure differences, usually caused by temperature variations, with air moving from high to low pressure areas.
📊 The pressure gradient force (PGF) is the driving force behind air movement, with closer isobars indicating a stronger PGF and thus stronger winds.
🌀 Earth's rotation affects wind direction through the Coriolis effect, causing winds to veer right in the Northern Hemisphere and left in the Southern Hemisphere.
🔍 The geostrophic wind is the balance between the pressure gradient force and the Coriolis force, resulting in wind moving at a 90-degree angle to the isobars.
⚖️ The geostrophic force can be calculated using a formula involving Earth's rotational speed, air density, wind speed, and the sine of the latitude.
🌀 The gradient wind is the wind affected by the Coriolis force and the centripetal force due to curved isobars, which can be stronger or weaker than the geostrophic wind.
🏞️ Friction from the Earth's surface slows down wind speed and reduces the Coriolis effect, particularly in the friction layer or boundary layer near the ground.
🔄 In the Northern Hemisphere, as wind descends into the friction layer, it backs (wind direction becomes more clockwise), while in the Southern Hemisphere, it veers (wind direction becomes more counterclockwise).
📐 The degree of wind backing or veering can vary depending on surface conditions, with more pronounced effects over land and especially at night when the friction layer compresses.
✈️ For pilots, understanding wind behavior is crucial for safe takeoff and landing, as it can affect aircraft performance and the need to adhere to wind limitations.
🌍 The script provides a comprehensive meteorological overview of wind formation and behavior, essential for aviation and understanding weather patterns.

Q & A

What is the primary cause of wind formation?
-The primary cause of wind is a pressure difference, usually caused by differences in temperature, with air moving from high pressure towards lower pressure to correct this pressure differential.
What is the pressure gradient force (PGF) and how does it relate to wind strength?
-Pressure gradient force (PGF) is the force behind air movement that is caused by the pressure gradient between isobars. The closer the isobars are together, the more severe the gradient and the larger the PGF, resulting in stronger winds.
How does the Earth's rotation affect wind direction?
-The Earth's rotation affects wind direction through the Coriolis effect, causing winds to veer to the right in the Northern Hemisphere and to the left in the Southern Hemisphere, due to differences in linear speed at various latitudes.
What is the geostrophic wind and how is it formed?
-The geostrophic wind is a theoretical wind where the pressure gradient force and the Coriolis force are balanced. It blows parallel to the isobars and is the result of these two forces being equal and opposite.
How does the friction layer affect wind speed and direction?
-The friction layer, or the turbulent surface layer, slows down wind speed due to friction from geographic features and air turbulence. It also causes the wind to back (in the Northern Hemisphere) or veer (in the Southern Hemisphere) due to reduced Coriolis effect at lower speeds.
What is the difference between geostrophic wind and gradient wind?
-Geostrophic wind assumes straight isobars and equal balance between pressure gradient force and Coriolis force. Gradient wind considers the curved nature of isobars, introducing a centripetal force that can make the wind speed stronger or weaker than the geostrophic wind.
How does the wind direction change when descending into the friction layer?
-In the Northern Hemisphere, wind direction changes by backing, or moving in a clockwise direction, when descending into the friction layer. In the Southern Hemisphere, the wind direction veers, or moves counterclockwise.
What factors influence the degree of wind backing or veering?
-Factors influencing the degree of wind backing or veering include the surface type (sea or land), time of day (day or night), and the presence of geographic features that cause turbulence and friction.
Why is there a difference in wind behavior over land during the day compared to at night?
-At night, the friction layer compresses due to colder temperatures, leading to a more pronounced change in wind direction and strength as the friction increases suddenly near the surface compared to the gradual increase during the day.
How can pilots use the understanding of wind to ensure safe takeoff and landing?
-Pilots need to understand wind to ensure they do not exceed aircraft wind limitations during takeoff and landing. Knowledge of wind formation, types of winds, and how they are affected by various factors allows pilots to make informed decisions and adjustments for safe flight operations.