From parallax scrolling, particle - producing explosions, and even subtleties like an upsurge of water when a detonation
happens near the surface demonstrate an adept attention to detail.
When this water condenses this latert heat is given up so if
this happens near the surface then local air temperatures will increase slightly.
Comment: «So, how does any excessive heat build - up
happen near the surface?
So, how does any excessive heat build - up
happen near the surface?
Not exact matches
The ability of a band to shape the temperature profile of the whole atmosphere should tend to be maximum at intermediate optical thicknesses (for a given band width), because at small optical thicknesses, the amounts of emission and absorption within any layer will be small relative to what
happens in other bands, while at large optical thicknesses, the net fluxes will tend to go to zero (except
near TOA and, absent convection, the
surface) and will be insensitive to changes in the temperature profile (except
near TOA), thus allowing other bands greater control over the temperature profile (depending on wavelength — greater influence for bands with larger bandwidths at wavelengths closer to the peak wavelength — which will depend on temperature and thus vary with height.
An apparent lag in temperature seen in the Greenland ice cores might be an artifact of the proximity of the large Laurentide Ice Sheet, which would have limited the
near surface air temperature to the freezing point, as
happens over summer sea - ice now.
Assuming that the flow rates from the deep geology are uninfluenced by what is
happening in the
near -
surface, this leaves something like 9 Tg per year currently being held back by the permafrost seal.
Now consider what
happens to any given stationary parcel of air
near the
surface that the tropical Hadley cell sucks towards the equator.
«The effect only
happens when fast - rising air would form a thunderstorm anyway, and when the air
near the
surface is moist,» Bell adds.»
What
happens is that the
near black body 15 micron CO2 IR annihilates the
near black body
surface IR so there is no IR to be absorbed by atmospheric CO2.
AlecM's analysis (which someone thought worth repeating): «What
happens is that the
near black body 15 micron CO2 IR annihilates the
near black body
surface IR so there is no IR to be absorbed by atmospheric CO2.»
Looking up into the sky, it is clear that SOMETHING is emitting close to a BB radiation curve @ ~ 265 K (the atmospheric temperature
near the
surface), but only above ~ 14 um or below ~ 8 um (which
happens to be where H2o & CO2 emit well).
«If we expect to see the problem minimized at any time in the
near future,» he told the E-Commerce Times, «enterprises are going to need to find a better way to cover all of their attack
surfaces, and fix key issues ahead of the next breach
happening.»
Now with this camera bump, the Moto G5 Plus does wobble a bit when you are tapping the screen with it sitting on a table or another flat
surface, but that mostly only
happens near the top of the display.