hhhh so it's not only me that i'm looking into different videos to understand it lol i feel better now ^____^

@@charlieteirney4252 glad to have helped! It’s a confusing subject no doubt.

I appreciate that! Not sure I have donations set up but it’s appreciated!

Thank for the comment and for watching!

Thanks for watching!

Haha awesome! Hopefully you did well

@@PartTimePilot 94 👍🏻

Can you tell me what part of the video you are referring to ?

@@PartTimePilot 03:53 air density decreases with increasing altitude, but a cooler air mass is more dense than warmer air mass. I think @parisvanrensburg7241 is referring to this.

@@PartTimePilot at 3:52

@@shahyarhaider8382oh wow. Good catch! I misspoke. Should be saying density is rising there. My bad!

Glad you found it helpful, thanks for watching!

No problem! Thank you for watching!

Anytime!

Anytime. Hope you found it useful!

Good question. The orange dashed line represents a trough. A trough is an elongated area of low pressure. A ridge on the other hand would be an elongated area of high pressure. If you were to see a 3-D topographical map of just pressure where low pressure has a low elevation and high pressure a high elevation then the trough would be like a really long valley between two hills or mountains. Low pressure systems are generally associated with poor weather for pilots because of the rising air (turbulence, cloud formation, etc.)

@@PartTimePilot I think that's why my flight instructor cancelled the flight the other day add the I also shared your video if you don't mind on a big group of student pilots on Facebook for the others to benefit add learn from this video thank you for all the efforts that you put to help us

@@MrSam-db1vw of course!

Thank you and thanks for watching!

Warm fronts have similar weather as temperature inversions as there is often a cap of warm air over colder air in a warm front just like in an inversion (actually called a frontal inversion). The weather you get also depends on where you are in relation to the front. As to why the air in the "warm layer" of the inversion does not continue to rise... that is a tricky one and one not easily described. I like to think of it as a hot air balloon. Hot air balloons rise in air because well they are hotter and less dense than the more dense and cooler air around it. Or in other words they have buoyancy. In a temperature inversion there is simply a point due to the changing lapse rate caused by various factors (radiation in radiation inversions, moving fronts in frontal inversions, etc.) where the balloon simply loses its buoyancy and there is a stable condition where nothing rises above a certain point "lid" of the inversion. The real answer gets into different lapse rates and the competing forces of the air wanting to rise naturally and things like radiation or fronts. This article goes into it if you want to read more about it: www.weather.gov/source/zhu/ZHU_Training_Page/Miscellaneous/inversion/inversion.html#:~:text=If%20the%20CAP%20is%20too,when%20they%20reach%20the%20CAP. Also, remember that eventually the air does rise and dissipate and temperature inversions are not permanent but when the forces that cause them are more than that rising force, they stick around.

You’re the best! Thanks for watching

@@PartTimePilot ur welcome i should be thanking u tho