22: Atmospheric Optics

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Light can be considered as photon particles or electromagnetic waves, either of which travel along paths called rays. To first order, light rays are straight lines within a uniform transparent medium such as air or water, but can reflect (bounce back) or refract (bend) at an interface between two media. Gradual refraction (curved ray paths) can also occur within a single medium containing a smooth variation of optical properties.

The beauty of nature and the utility of physics come together in the explanation of rainbows, halos, and myriad other atmospheric optical phenomena.

22.1: Ray Geometry
This page covers the behavior of monochromatic light at media interfaces, focusing on reflection, refraction, and absorption, governed by Snell’s Law and the concept of refractive index. It includes tables of refractive indices and emphasizes component angles in optical calculations. Principles of light refraction, critical angles, and Huygens' Principle are discussed, with calculations provided for refracted angles and critical angles, exemplified by red light transitioning from ice to air.
22.2: Liquid-Drop Optics
This page explores the optical phenomena of rainbows, explaining their visibility related to the sun and the differences between primary and secondary rainbows based on viewing angles and raindrop size. It delves into the geometric optics of rainbow formation, including reflection and refraction.
22.3: Ice Crystal Optics
This page provides an overview of optical phenomena related to ice crystals in the atmosphere, such as halos, sun dogs, and various arcs formed through the refraction and reflection of sunlight. Key features include the formation of 22° and 46° halos, circumzenithal and circumhorizonal arcs, and the influence of crystal orientation on light behavior.
22.4: Scattering
This page covers light scattering in the atmosphere, focusing on optical thickness, polarization, and various scattering types. It explains how Rayleigh scattering by small molecules creates a blue sky, while larger aerosol particles, such as sulfuric-acid droplets, affect atmospheric color and visibility, creating red sunsets and blue moons.
22.5: Diffraction and Interference
This page explores optical phenomena such as corona, iridescence, and glory, which result from light diffraction and interference in cloud droplets. It explains how constructive interference forms bright rings around light sources and distinguishes between corona (from uniform droplet sizes) and halos (from ice crystals). The page also covers supernumerary bows, faint arcs near rainbows created by similar-sized raindrops leading to constructive interference.
22.6: Mirages
This page explores the correlation between air density and refractive index, emphasizing how temperature and pressure variations influence light paths, resulting in optical effects like mirages. It presents equations for calculating light ray curvature in various atmospheric conditions and categorizes different mirages, such as inferior and superior.
22.7: Review
This page explores atmospheric optical phenomena including halos, sun dogs, rainbows, and aureoles, examining the processes of reflection, refraction, and scattering. It serves as a conclusion to the textbook, emphasizing the interconnectedness of atmospheric concepts while encouraging further exploration in meteorology. It also reflects on Isaac Newton's historical misinterpretation of the blue sky, underscoring the fallibility of great scientists and the need for innovative thinking in science.
22.8: Homework Exercises
This page covers the study of atmospheric optical phenomena, such as halos, sun dogs, and rainbows. It guides readers in exploring these phenomena through images and descriptions, while emphasizing practical exercises in calculating angles of incidence, refraction, and reflectivity using Snell's law. Various exercises involve analyzing viewing angles for colors and calculating the impact of environmental factors on optics.

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