Since I didn’t plan of getting pictures during Totality, I decided to focus on things I could attempt to capture with a lot less effort. The first of these is the temperature change during Totality. Since we were going to be in a shadow, it was logical to assume there would be some change. The […]
Since I didn’t plan of getting pictures during Totality, I decided to focus on things I could attempt to capture with a lot less effort.
The first of these is the temperature change during Totality. Since we were going to be in a shadow, it was logical to assume there would be some change. The real question was how much was the temperature going to change?
It was a HOT and muggy day in Tennessee, during the eclipse. The temperature was about 95 degrees and 60%-80% humidity. I used a digital thermometer in direct sunlight and it registered 121 degrees just before the eclipse began! As the eclipse transpired, the temperature dropped to 81 degrees! That’s a 40 degree difference! It was a lovely respite from the heat.
The second thing I tried to capture were the shadowbands that can appear during Totality. Shadows bands are hard to explain, so I’ll let this NASA burb tell you more.
What are “shadow bands?”
These are among the most ephemeral phenomena that observers see during the few minutes before and after a total solar eclipse. They appear as a multitude of faint rapidly moving bands that can be seen by placing a white sheet of paper several feet square on the ground. They look like ripples of sunshine at the bottom of a swimming pool, and their visibility varies from eclipse to eclipse. 19th century observers interpreted them as interference fringes caused by some kind of diffraction phenomenon. The Sun, however, is hardly a “point source” and the patterns are more random than you might expect from diffraction effects.
The simplest explanation is that they arise from atmospheric turbulence. When light rays pass through eddies in the atmosphere, they are refracted. Unresolved distant sources simply “twinkle,” but for nearby large objects, the incoming light can be split into interfering bundles that recombine on the ground to give mottled patterns of light and dark bands, or portions of bands. Near totality, the image of the Sun is only a thin crescent a few arc seconds wide, which is about the same size as the atmospheric eddies as seen from the ground. Bands are produced because the Sun’s image is longer in one direction than another. The bands move, not at the rate you would expect for the eclipse, but at a speed determined by the motion of the atmospheric eddies.
Since we would be look at the sun, I set up and old camera to record shadows bands. They are extremely faint and I almost wish I would have used a better quality video. Oh well, next time. They are difficult to see, and when I converted the video, they became even fainter.