Why is the sky blue?

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Why is the sky blue?  It’s a question that only leads to more questions.

Use this resource with Year 5 students learning about the behaviour of light, including reflection and refraction. The accompanying interactive student activity is great for introducing the topic or it could be used to review and consolidate learning. This resource includes an experiment that can also be used with Year 9 students studying wave and particle models.

Word Count / Video Length: 874 / 05:16 mins

Credit: Tobias Titz / Getty Images

This is actually a question that Roger Rassool, an associate professor in particle physics at the University of Melbourne, answered way back in 2013. This was his answer then:

Why is the sky blue? It is a question that, in true Sumner Miller fashion, leads to many more: What is light? What is the sky made of? How do we perceive colour?

To answer those questions we first turn to Isaac Newton who once said, “If I have seen further than others, it is by standing on the shoulders of giants.” Like everyone else in the 17th century, Newton marvelled at seeing a beam of sunlight enter a polished glass prism and emerge as a rainbow of colours. Some thought the prism itself contained the rainbow and the light beam was pushing it out. Newton had another suspicion. He directed the spreading rainbow of rays on to a second prism. What emerged at the far end was a restored beam of white light. Newton showed the prism was not concealing a rainbow; it was splitting light into its component colours.

So Newton takes us the first step of the way by showing that sunlight is made up of the colours of the rainbow.

For the next step, we turn to another Englishman, polymath Thomas Young. Not only did he solve several of the mysteries of physics, he also cracked Egyptian hieroglyphics using the ancient Rosetta Stone that bore the same inscription in three languages. Young’s contribution to our understanding of light was to replace Newton’s 100-year-old idea that light is made up of particles. Instead, based on his studies of sound, he proposed that light was a wave and in 1803 proved it to his colleagues at the Royal Society of London, beginning with the words, “The experiments I am about to relate … may be repeated with great ease, whenever the sun shines, and without any other apparatus than is at hand to everyone.”

At hand, perhaps, but “great ease” might be a stretch. According to rumour, one experiment involved punching two small holes in the roof of a church and allowing sunlight to form a pattern on the floor below. You might expect he would have seen two bright dots, but no. He saw a pattern of bright and dark bands. There was no explanation for that pattern unless the light travelling through the slits behaved like waves. Imagine throwing two pebbles into a stream. When the spreading ripples meet, sometimes they cancel each other out and sometimes they add together. If light were a wave, these cancellations and additions would produce a pattern of alternating light and dark bands, which was exactly what Young saw in various versions of his now famous “double slit experiment”.

This was when he climbed on to Newton’s shoulders to take his findings further. Newton had shown that light was made of different colours; Young had shown that it was a wave. So perhaps the different colours were in fact light with different wavelengths. Bingo! Young takes us a second step on the way.

In 1859 Irish scientist John Tyndall used this information to make the next step, becoming the first to explain why the sky is blue. He shone a beam of white light through a fluid speckled with floating particles. When he peered from the side the fluid glowed blue. This became known as the “Tyndall effect”. Tyndall realised this meant the blue light was bouncing or “scattering” off the particles in the fluid more than any other colour. Since blue light has a short wavelength, he inferred that shorter wavelengths are scattered more than longer ones.

Tyndall’s experiment takes us the final step of the way, showing that blue light scatters more than other colours.

So what if we put all of this together? As sunlight passes through the atmosphere it scatters, bouncing off the molecules of nitrogen and oxygen. The shorter wavelengths at the blue end of the spectrum are 10 times more likely to scatter than red light, the longest wavelength. To an observer on Earth, it is like a storm of bouncing blue light waves bombarding the eyeballs; in comparison the drizzle of red wavelengths hardly register, so the sky looks blue. Why not violet which, as the shortest wavelength, scatters the most? The answer lies with our eyes. The scattered light in fact does contain violet light as well as blue. But the eye’s receptors for coloured light, the cones, are not as sensitive to violet and when it is combined with blue, they register the latter.

But hang on, why do sunsets appear red? When the sun is low on the horizon, light has to travel much further through the lower atmosphere, encountering bigger particles such as smoke and pollution that make blue light scatter all the more. By the time this light reaches your eyes, most of the blue light waves have scattered away. This leaves predominately red light waves to create that beautiful reddish glow.

So the next time you gaze up at a beautiful blue sky, remember the giants who explained why it is so.

This article is republished from Cosmos. Read the original article here.

This film was submitted to the SCINEMA 2021 International Science Film Festival and was selected to feature in our Australian, Experimental and School categories. It also achieved the Special Jury Award at the festival. The filmmaker has kindly allowed us to continue to show the film beyond the festival.

Video Length: 05:16 mins

Watch our SCINEMA films here. 

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Year: 5, 9

Topics:

Physical Sciences – Energy

Additional – Careers, Technology.

Concepts (South Australia):

Physical Sciences – Energy

SCINEMA International Science Film Festival is the largest science film festival in the Southern Hemisphere!

In 2021, people hosted at home and community screenings to an audience of over 125,000. Although the 2021 festival is over, we have permission to continue to use the films and their associated educational resources with your students.

Each resource is mapped to the Australian National Curriculum and contains hands-on activities for your students. Designed to engage and inspire, these resources demonstrate STEM careers and skills to your students, encouraging them to be curious thinkers, problem-solvers and contributing citizens within society.

Years:

5 & 9
Learning Connections

Student Skill Summary

Australian Curriculum Connections - Version 8.4

Sub StrandYear LevelKey IdeaConcept - ACConcept - SAContent TopicContent CodeContent Descriptor
Physical Sciences9Matter and energy | Form and functionForms and Transfers of EnergyEnergyEnergy Movement and WavesACSSU182Energy transfer through different mediums can be explained using wave and particle models