~We give here some recent examples to be found amongst many others
The first thing in identifying the effects of invisible clear air moisture is to describe what happens when the High Arctic is cloudy:
Further examples abound: January 26 2018 had very low overcast conditions, pw was 2.10 mm, on the 24th same month 300 feet stratus near overcast skies had a pw column of 1.18 mm, on the 12th of January various altitude clouds were part of 1.48 mm pw. On Feb 12, 2018 0.85 mm with alto cumulus dominating overcast. When mid air winds are not so strong, spontaneous cloud formations can also be seen throughout winter, sometimes appearing and disappearing within a few hours, this is not an often quoted meteorological process, but it can be said that the cloud may revert to invisible or visible mode.
On many observed occasions, horizon heights defied logic, sometimes higher or lower than would be expected given nearly identical meteorological conditions from one day to the next. But First Melt 2018 might have exposed one secret player for all of us to consider. First Melt is a horizon event marking the return of sea horizon elevation to Astronomical Horizon. Implying
T*** = Ts, top of snow (ice) temperature is equal to surface air temperature:
First Melt is an event caused by top of sea ice temperature equal to surface air, for March 14 event to have happened, it was necessary for thin sea ice to be present, because thin sea ice has more potential heat to compensate for extreme cold air, very frozen air cooling top of sea ice tends to be cancelled by the heat of the ocean, but on this afternoon, the sun's short wave radiation stopped sea ice top from cooling, in fact was warming it along with the air at its interface.
With much thicker sea ice the equation of winter would be more often: T*** < Ts, causing strong inversions since thicker sea ice insulates the warming from -1.8 C sea water.
If it was only thin ice causing First Melt to be early, identical sun rays at equal or coming from higher point in the sky would continue giving a daily drop to Astronomical Horizon after local apparent noon for days to come, that was not so, next clear days had it slightly or much higher horizons:
The over all impact of clear air moisture , its contribution to long wave radiation deflections may be small to important, however it can be measured even while not observing refraction effects. Top of snow temperature layer minus surface temperatures may dramatically vary day to day without any clouds. While precluding windy days, there are several examples of unexplainable variations of refraction and snow temperatures during clear air conditions, only plausible with the presence of clouds.
Invisible clouds were first suspected by strange refraction observation variations eventually confirmed by correct top of snow and surface air observations. An overcast with low clouds day can have top of snow temperatures always very close or equal to surface air temperatures. When not cloudy, with dominant clear skies, top snow layer may be persistently equal to Ts as well, even during the presence of the sun going up and down. Refraction observations obtained similar horizon heights as with extensive cloud coverage or with clear skies, in both instances an indication of a long wave feedback system, sometimes with bounce back points easily conclusive, sometimes not. If all air moisture wasn't invisible I would write about their geometry. At any rate, we do have many examples of observed days with T***=Ts with very few clouds or none at all,
Jan 13 2018 a clear day in darkness, following a cloudy one, similar T*** and Ts on all readings , pw was 3.26 mm. Jan 17, 2.70 mm . Apparent clear air moisture preceding coming of a cyclone system was detected March 11 with a 2.51 mm pw. February 20, 1.79 mm.
Some observations were rather confusing to analyze: March 12 1.43 mm. Jan 15 in darkness 1.37 and March 15 with 1.18 mm ..... All these observations suggest not seen moisture likely affecting the climate in the longer term. wd March 21,2018
