Here’s why rainbows have a curved or arcing shape


Rainbow arcing over a city brightly lit by the sun with dark clouds behind.
View at EarthSky Community Photos. | Muafak Bisher in Jerusalem captured this image on March 22, 2023. Muafak wrote: “Colorful rainbow over my small village Majd ElKurum, taken a few seconds before the rain shower and sunrise.” Thank you, Muafak!

Light and raindrops work together to create a rainbow, but why is it curved? When light hits a spherical raindrop, the colors of the light refract toward our eyes in slightly different directions, which is what allows us to see the different colors. But the light also bounces, or reflects, off the raindrops. That sunlight most strongly reflects at a 42-degree angle. If we were hovering in the air, we could see that rainbow as a 42-degree circle. But because we’re usually on the ground, we see the rainbow as a curved arc that intersects with the ground. Want more details? Keep reading.

Rainbow basics

First, to see a rainbow, you need to put the sun at your back. Also, you’ll need the raindrops to be falling in front of you.

Second, when making a rainbow, sunlight emerges from many raindrops at once. A rainbow isn’t a flat two-dimensional image on the dome of sky. It’s more like a mosaic, composed of many separate bits … in three dimensions (more about the three-dimensional quality of rainbows below.) Your eyes see rainbows as flat for the same reason we see the sun and moon as flat disks. When we look in the sky, there are no visual cues to tell us otherwise.

Third, rainbows are more than half circles. They’re really whole circles. You’ll never see a circle rainbow from Earth’s surface because your horizon gets in the way. But, up high, people in airplanes sometimes do see them.

Last chance to get a moon phase calendar! Only a few left.

Physics of rainbows

When making a rainbow, sunlight shining into each individual raindrop refracts, or splits into its component colors. And the light also reflects, so that those various colors come bouncing back.

One key to rainbows is that the light leaves the collection of raindrops in front of you at an angle. In making a rainbow, the angle is between 40 and 42 degrees, depending on the color (wavelength) of the light. Physicsclassroom.com explained it this way:

The circle (or half-circle) results because there are a collection of suspended droplets in the atmosphere that are capable of concentrating the dispersed light at angles of deviation of 40-42 degrees relative to the original path of light from the sun.

These droplets actually form a circular arc, with each droplet within the arc dispersing light and reflecting it back towards the observer.

Angles of light coming toward an observer from a rainbow.
Rainbows are the base of a cone shape with our eyes at the point. Image via Wikipedia.

So why are rainbows curved?

To understand the curvature of rainbows, you’ll need to switch your mind to its three-dimensional-thinking mode. Cecil Adams of the newspaper column The Straight Dope explained it this way:

We’re used to thinking of rainbows as basically two-dimensional, but that’s an illusion caused by a lack of distance cues. The cloud of water droplets that produces the rainbow is obviously spread out in three dimensions.

The geometry of reflection, however, is such that all the droplets that reflect the rainbow’s light toward you lie in a cone with your eyes at the tip.

It takes an intuitive leap to see why this should be so, but let’s give it a crack. Water droplets reflect sunlight (or any light) at an angle of between 40 and 42 degrees, depending on the wavelength …

The sun is low and behind you. All the sunbeams head in, strike the cloud of water droplets ahead of you and bounce back at an angle of [approximately] 40 degrees.

Naturally the beams can bounce 40 degrees any which way — up, down, and sideways.

But the only ones you see are the ones that lie on a cone with a side-to-axis angle of 40 degrees and your eyes at the tip.

Rainbows, 1 bright and 1 faint, arcing over New York City.
Supernumerary rainbow over New York City on July 8, 2017, by Alexander Krivenyshev of WorldTimeZone.com.

Rainbows don’t exist

I also asked Les Cowley of the great website Atmospheric Optics. He’s a world-class expert in sky optics and EarthSky’s go-to guy for all daytime sky phenomena. Les told me:

The cone explanation is sound and also my preferred one at Atmospheric Optics.

Rainbows don’t exist! They are nowhere in space. You cannot touch them or drive around them. They are a collection of rays from glinting raindrops that happen to reach our eyes. Raindrops glint rainbow rays at an angle of 42 degrees from the point directly opposite the sun. All the drops glinting the rainbow are on the surface of a cone with its point at your eye. They can be near and far. Other drops not on the cone also glint sunlight into rainbow colours but their rays do not reach our eyes. We only see those on the cone. When you look down the cone you see a circle. So rainbows are circles!

To get technical, here is how rainbow rays form.

And this one (it took pain to write it) explains why we see rainbows and halos.

Phew! Thanks from EarthSky to all the smart and knowledgeable people who contributed to this explanation.

Beautiful rainbow photos

And now for some great pics …

Double rainbow, 1 faint and 1 bright, anti-crepuscular rays over a wide beach.
View at EarthSky Community Photos. | Alec Jones in coastal South Shields, in northeastern England, captured this image on February 20, 2019. Alec wrote: “A delightful rainbow that particularly caught my eye as it framed the anticrepuscular rays on the horizon.” Thank you, Alec.
Two rainbow arcs, 1 brighter, over a tumultuous surf.
View at EarthSky Community Photos. | Cecille Kennedy in Depoe Bay, Oregon, captured this rainbow on February 14, 2023. Cecille wrote: “A rainbow this morning after a powerful overnight storm. Some ice remains on the ground, and it was raining slightly when this beautiful surprise rainbow appeared.” Thank you, Cecille!
A rainbow with stormy clouds over badlands and a winding road.
Mike Taylor – based in Maine – calls this photo Innuendo. Used with permission.
Low rainbow over desert landscape and saguaro cactus.
Eliot Herman wrote to EarthSky: “This one is my favorite ground-hugging rainbow, right out my front door … A final last thunderstorm, and as the day was ending it cleared and the low-angle sun lit up this ground-hugging rainbow on the adjacent hillside.”

Bottom line: Rainbows have a curved shape because they’re made from light reflected after hitting spherical raindrops.

The post Here’s why rainbows have a curved or arcing shape first appeared on EarthSky.



from EarthSky https://ift.tt/lW4Yha7
Rainbow arcing over a city brightly lit by the sun with dark clouds behind.
View at EarthSky Community Photos. | Muafak Bisher in Jerusalem captured this image on March 22, 2023. Muafak wrote: “Colorful rainbow over my small village Majd ElKurum, taken a few seconds before the rain shower and sunrise.” Thank you, Muafak!

Light and raindrops work together to create a rainbow, but why is it curved? When light hits a spherical raindrop, the colors of the light refract toward our eyes in slightly different directions, which is what allows us to see the different colors. But the light also bounces, or reflects, off the raindrops. That sunlight most strongly reflects at a 42-degree angle. If we were hovering in the air, we could see that rainbow as a 42-degree circle. But because we’re usually on the ground, we see the rainbow as a curved arc that intersects with the ground. Want more details? Keep reading.

Rainbow basics

First, to see a rainbow, you need to put the sun at your back. Also, you’ll need the raindrops to be falling in front of you.

Second, when making a rainbow, sunlight emerges from many raindrops at once. A rainbow isn’t a flat two-dimensional image on the dome of sky. It’s more like a mosaic, composed of many separate bits … in three dimensions (more about the three-dimensional quality of rainbows below.) Your eyes see rainbows as flat for the same reason we see the sun and moon as flat disks. When we look in the sky, there are no visual cues to tell us otherwise.

Third, rainbows are more than half circles. They’re really whole circles. You’ll never see a circle rainbow from Earth’s surface because your horizon gets in the way. But, up high, people in airplanes sometimes do see them.

Last chance to get a moon phase calendar! Only a few left.

Physics of rainbows

When making a rainbow, sunlight shining into each individual raindrop refracts, or splits into its component colors. And the light also reflects, so that those various colors come bouncing back.

One key to rainbows is that the light leaves the collection of raindrops in front of you at an angle. In making a rainbow, the angle is between 40 and 42 degrees, depending on the color (wavelength) of the light. Physicsclassroom.com explained it this way:

The circle (or half-circle) results because there are a collection of suspended droplets in the atmosphere that are capable of concentrating the dispersed light at angles of deviation of 40-42 degrees relative to the original path of light from the sun.

These droplets actually form a circular arc, with each droplet within the arc dispersing light and reflecting it back towards the observer.

Angles of light coming toward an observer from a rainbow.
Rainbows are the base of a cone shape with our eyes at the point. Image via Wikipedia.

So why are rainbows curved?

To understand the curvature of rainbows, you’ll need to switch your mind to its three-dimensional-thinking mode. Cecil Adams of the newspaper column The Straight Dope explained it this way:

We’re used to thinking of rainbows as basically two-dimensional, but that’s an illusion caused by a lack of distance cues. The cloud of water droplets that produces the rainbow is obviously spread out in three dimensions.

The geometry of reflection, however, is such that all the droplets that reflect the rainbow’s light toward you lie in a cone with your eyes at the tip.

It takes an intuitive leap to see why this should be so, but let’s give it a crack. Water droplets reflect sunlight (or any light) at an angle of between 40 and 42 degrees, depending on the wavelength …

The sun is low and behind you. All the sunbeams head in, strike the cloud of water droplets ahead of you and bounce back at an angle of [approximately] 40 degrees.

Naturally the beams can bounce 40 degrees any which way — up, down, and sideways.

But the only ones you see are the ones that lie on a cone with a side-to-axis angle of 40 degrees and your eyes at the tip.

Rainbows, 1 bright and 1 faint, arcing over New York City.
Supernumerary rainbow over New York City on July 8, 2017, by Alexander Krivenyshev of WorldTimeZone.com.

Rainbows don’t exist

I also asked Les Cowley of the great website Atmospheric Optics. He’s a world-class expert in sky optics and EarthSky’s go-to guy for all daytime sky phenomena. Les told me:

The cone explanation is sound and also my preferred one at Atmospheric Optics.

Rainbows don’t exist! They are nowhere in space. You cannot touch them or drive around them. They are a collection of rays from glinting raindrops that happen to reach our eyes. Raindrops glint rainbow rays at an angle of 42 degrees from the point directly opposite the sun. All the drops glinting the rainbow are on the surface of a cone with its point at your eye. They can be near and far. Other drops not on the cone also glint sunlight into rainbow colours but their rays do not reach our eyes. We only see those on the cone. When you look down the cone you see a circle. So rainbows are circles!

To get technical, here is how rainbow rays form.

And this one (it took pain to write it) explains why we see rainbows and halos.

Phew! Thanks from EarthSky to all the smart and knowledgeable people who contributed to this explanation.

Beautiful rainbow photos

And now for some great pics …

Double rainbow, 1 faint and 1 bright, anti-crepuscular rays over a wide beach.
View at EarthSky Community Photos. | Alec Jones in coastal South Shields, in northeastern England, captured this image on February 20, 2019. Alec wrote: “A delightful rainbow that particularly caught my eye as it framed the anticrepuscular rays on the horizon.” Thank you, Alec.
Two rainbow arcs, 1 brighter, over a tumultuous surf.
View at EarthSky Community Photos. | Cecille Kennedy in Depoe Bay, Oregon, captured this rainbow on February 14, 2023. Cecille wrote: “A rainbow this morning after a powerful overnight storm. Some ice remains on the ground, and it was raining slightly when this beautiful surprise rainbow appeared.” Thank you, Cecille!
A rainbow with stormy clouds over badlands and a winding road.
Mike Taylor – based in Maine – calls this photo Innuendo. Used with permission.
Low rainbow over desert landscape and saguaro cactus.
Eliot Herman wrote to EarthSky: “This one is my favorite ground-hugging rainbow, right out my front door … A final last thunderstorm, and as the day was ending it cleared and the low-angle sun lit up this ground-hugging rainbow on the adjacent hillside.”

Bottom line: Rainbows have a curved shape because they’re made from light reflected after hitting spherical raindrops.

The post Here’s why rainbows have a curved or arcing shape first appeared on EarthSky.



from EarthSky https://ift.tt/lW4Yha7

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