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Scientists Luck Upon a New Way To Make a Rainbow (sciencemag.org)
sciencehabit shares a report from Science Magazine: Chemists have stumbled across a new way to separate reflected light into the colors of the rainbow -- a phenomenon known as iridescence. The surprisingly simple technique, which is something of a hybrid of previously known ones, could have applications both scientific and aesthetic. In iridescence, an object reflects different colors at different angles, separating white light into its constituent colors.
Now, [researchers] at Pennsylvania State University in State College report producing iridescence in a new way. They happened across the effect in early 2017, when they cooked up micron-size spherical droplets containing two types of oil in which the lighter oil formed a lentil-shaped upper layer the researchers hoped to use as a lens. But surprisingly, when illuminated from above, the edges of the lentils glowed with a color that depended on their size and the angle at which they were viewed, the team reports today in Nature. Clarity came only with the computer simulations performed [the researchers]. Their analysis showed the iridescence emerges through a new mechanism that blends certain elements of the previously known ones. [...] Engineers already use thin-films and refractive particles to create iridescence in video displays, paints, and decorative wall coverings. With its simplicity and adjustability, the new effect could open ways to color the world. The effect can be explained in a much simpler system: "water droplets that condense and hang from the underside of the lid of a petri dish. Light waves entering near one edge of a droplet can bounce two or more times off the dome of the droplet before emerging near the other edge -- much as light reflects off the back of a raindrop in a rainbow. However, the light waves entering at slightly different distances from the center of the droplet can bounce different numbers of times. And waves bouncing different numbers of times can interfere and reinforce each other, as in diffraction or thin-film interference. As a result, different colors emerge at different angles, which can be controlled by changing the size of the droplet."
Now, [researchers] at Pennsylvania State University in State College report producing iridescence in a new way. They happened across the effect in early 2017, when they cooked up micron-size spherical droplets containing two types of oil in which the lighter oil formed a lentil-shaped upper layer the researchers hoped to use as a lens. But surprisingly, when illuminated from above, the edges of the lentils glowed with a color that depended on their size and the angle at which they were viewed, the team reports today in Nature. Clarity came only with the computer simulations performed [the researchers]. Their analysis showed the iridescence emerges through a new mechanism that blends certain elements of the previously known ones. [...] Engineers already use thin-films and refractive particles to create iridescence in video displays, paints, and decorative wall coverings. With its simplicity and adjustability, the new effect could open ways to color the world. The effect can be explained in a much simpler system: "water droplets that condense and hang from the underside of the lid of a petri dish. Light waves entering near one edge of a droplet can bounce two or more times off the dome of the droplet before emerging near the other edge -- much as light reflects off the back of a raindrop in a rainbow. However, the light waves entering at slightly different distances from the center of the droplet can bounce different numbers of times. And waves bouncing different numbers of times can interfere and reinforce each other, as in diffraction or thin-film interference. As a result, different colors emerge at different angles, which can be controlled by changing the size of the droplet."
I am so disappointed that it doesn't involve having me lucky charms.
(Okay, it's pretty cool)
Why all the black bars and rectangles on that sciencemag site? :-(
Displays with wide color gamut, anyone?
In a paved parking lot, cars with leaky engines leave behind a few drops oil. After a light drizzle, especially after a long dry period, you would see small patches of oily wet paving with colors of the rainbow. Usually very muted because of the dark back ground. I used to tell my daughter that they were pieces of dead rainbow that had fallen from the sky. There was a time she believed it. As she grew up she started pretending to believe it to indulge me. Then came a day, "will you stop saying that? It is not creative or funny anymore!". That's the day ...
sed -e 's/Chuck Norris/Rajnikant/g' joke > fact
There are a whole lot of AC's this morning who didn't even read the TFS. Yes, even the summary clearly explains that this is not the common oil interference effect. Not all things that look sort of similar are exactly the same thing.
Starships were meant to fly, Hands up and touch the sky - Nicky Minaj
This will be developed commercially. Soon we will have the spectacle of equipment spraying oil into the air at weddings. Hopefully they can keep it separated from the butterfly releases so the butterflies don't drift into the airbourne oil.
Where's me gold?
More RGB lighting for your computer!
I love sky effects. There's lots of extra physics one can see in rainbows that most people never see. As described in the summary, this is a well known effect known as supe numary rainbows. They arise from multipathing in the dorplet as decribed. You see these all the time in thin clouds but you may not have noiced. Next time you see thin clouds look for oscilating purple and teal bands. Them's the supernumary bows.
And next time you see a double rainbow look at it again. First he second rainbow going the reverse direction. This tells you the bow is not just a second rainbow in a different place than the first, but it's different physics. Second look at the gap between the bows. It's not only always the same size, it's also subtly darker than the rest of the sky. What's there is an infrared rainbow. You just can't see it.
And on a cold day with some high very light clouds. Look off to the side of the sun. You might see bright spots in the sky on either side. THis tells you there are elingated hexagonal ice spikes in the air because it's cold up there.
My favorite effect of all that makes my kids really wonder is the effect called "jesus rays" but I'm not going to spoil it for you cause it's cool when the penny drops.
Some drink at the fountain of knowledge. Others just gargle.
They say it looks like effects we are familiar with. But the actual observations didn't match existing models. So they did some simulations and determined that this is actually a hybrid of a thin film interference effect and internal reflections.
Have gnu, will travel.