When you see 'heat rising', what are you actually seeing?
Like the title says: when you see "heat rising" (the wavy/blurry area above a heat source), what are you actually seeing?
Bonus question: How does that cast a shadow? I noticed when I was opening my air fryer, I could see the shadow of the heat rising but, looking at the hot basket itself, couldn't see it.
You are seeing changes in the refractive index of air as a result of heat lowering the density of the air. As air comes in contact with the hot surface, it becomes heated and rises through otherwise cool air - The rising air causes eddies and vortexes that lead to light bending in weird ways as it passes through.
The shadows are much like the shadows on the bottom of a pool when there are waves on the surface. Incoming wavefront of light are distorted from planar and sent in different directions, some directions get less total light, some get more.
You took me straight back to a D- in intro to optics and modern physics where my classmates were trying to solve problems based on concepts, where I was trying to solve the problem of not understanding the concepts.
Warmer air has a different density to colder air, so the light refracts/bends, like through a prism.
The shadows occur as the light happens to have been focused away from those points.
Hot air is less dense than cold air, and the speed of light through a fluid will change with the fluid's density. Heat shimmers are a swirling mass of air at different temperatures.
In a not super scientific explanation, hot air rises and is less dense than cold air, this changes how light passes through it compared to the rest of the air. Shadows are essentially less light dense areas, so by changing how light passes through it you naturally get less dense regions behind the distortion making it darker than the other areas, aka a shadow. Air, being transparent though, there is less distortion than an opaque object, such as yourself, which has greater ability to distort (or rather, prevent) light in that area. (Your shadow)
You’ve gotten some good answers explaining that heat changes the density, and therefore the index of refraction of air.
Fun fact: Schlieren Imaging allows one to photograph shockwaves by relying on the same effect. As a shockwave travels through air, it creates a region of high density, which can be imaged with this technique.