Sorry but your confusing thermal pressure (thermodynamic pressure) with the earths terrestrial natural (static pressure field)! As thermal pressure cannot exist out of a limited boundary surface integral! Thermal pressure generation is not ideally possible within unlimited open air atmospheric domain, basically ideally thermal pressure is non-existent in open unlimited spacial fields such as atmospheres! It’s (static pressure) your meaning to explain, as when a molecular air parcel is heated, yes it’s molecular kinetic vibrational energy field is increased, by which it naturally relative to conservative thermodynamic law expands reducing the number of air molecules per unit volume of space! Whereas this thermodynamic molecular expansion inversely reduces the (density) field & therefore this means that the (static pressure field) not a thermal pressure field has actually decreased & therefore now momentarily resides within a state of non-equilibrium, thus meaning that this parcel of heated & decreased pressurized air molecules becomes lighter than the surrounding static atmospheric pressure & it then begins to rise to a higher pressure altitude equal to its own static pressure field! However as it rises it cools adiabatically releasing it’s absorbed heat back into the localized atmospheric environment until it reaches its static pressure altitude of equilibrium! From there on ideally this parcel of energized air from below (lower altitudes of higher static pressure) will now advect upon a horizontal direction until it cools, causing the polar reverse to occur, by now decreasing its intermolecular kinetic energy field of kinetic vibrations thus decreasing its intermolecular forces of dispersion, thus inversely losing its ability to repel the air parcels intermolecular forces of attraction! Such meaning, that the air molecules attract closer together increasing the molecular parcel of air (density field) per unit volume, of which once again the same parcel of air molecules are now in polar reverse state of static pressure instability, now becoming more dense relative to its weight per unit volume, of which it shall fall back to lower altitudes of same increased density & static pressure! As (Static pressure) is the inverse component of the (dynamic pressure field) equating to the earths net total pressure field constant! Whereas thermal pressure fields can only generate within heated sealed boundaries such as containers etc, because thermal pressure fields are a product of heated kinetically energized air molecules trapped within confined spatial field limitations, whereas (thermal pressure) actually does the opposite to (static pressure) whence heat or kinetically energized, it actually increases due to intermolecular deflection off the limited enclosed boundary surface of its container.
Thank you ma'am. From India 🇮🇳
How does heating increase pressure you and cooling downing pressure you interpret it opposite
Hlo mam I m from India Kashmir
nice explanation
First u said heating increases pressure afterwards u said heating decreases pressure. Pls make it clear
Sorry but your confusing thermal pressure (thermodynamic pressure) with the earths terrestrial natural (static pressure field)! As thermal pressure cannot exist out of a limited boundary surface integral!
Thermal pressure generation is not ideally possible within unlimited open air atmospheric domain, basically ideally thermal pressure is non-existent in open unlimited spacial fields such as atmospheres!
It’s (static pressure) your meaning to explain, as when a molecular air parcel is heated, yes it’s molecular kinetic vibrational energy field is increased, by which it naturally relative to conservative thermodynamic law expands reducing the number of air molecules per unit volume of space!
Whereas this thermodynamic molecular expansion inversely reduces the (density) field & therefore this means that the (static pressure field) not a thermal pressure field has actually decreased & therefore now momentarily resides within a state of non-equilibrium, thus meaning that this parcel of heated & decreased pressurized air molecules becomes lighter than the surrounding static atmospheric pressure & it then begins to rise to a higher pressure altitude equal to its own static pressure field!
However as it rises it cools adiabatically releasing it’s absorbed heat back into the localized atmospheric environment until it reaches its static pressure altitude of equilibrium!
From there on ideally this parcel of energized air from below (lower altitudes of higher static pressure) will now advect upon a horizontal direction until it cools, causing the polar reverse to occur, by now decreasing its intermolecular kinetic energy field of kinetic vibrations thus decreasing its intermolecular forces of dispersion, thus inversely losing its ability to repel the air parcels intermolecular forces of attraction!
Such meaning, that the air molecules attract closer together increasing the molecular parcel of air (density field) per unit volume, of which once again the same parcel of air molecules are now in polar reverse state of static pressure instability, now becoming more dense relative to its weight per unit volume, of which it shall fall back to lower altitudes of same increased density & static pressure!
As (Static pressure) is the inverse component of the (dynamic pressure field) equating to the earths net total pressure field constant!
Whereas thermal pressure fields can only generate within heated sealed boundaries such as containers etc, because thermal pressure fields are a product of heated kinetically energized air molecules trapped within confined spatial field limitations, whereas (thermal pressure) actually does the opposite to (static pressure) whence heat or kinetically energized, it actually increases due to intermolecular deflection off the limited enclosed boundary surface of its container.
Hot air reduces presure not increase!