Five Science 'Facts' You Learned At School That Are Plain Wrong

Illustration for article titled Five Science Facts You Learned At School That Are Plain Wrong

Let's start with a quiz…

  1. How many senses do you have?
  2. Which of the following are magnetic: a tomato, you, paperclips?
  3. What are the primary colours of pigments and paints?
  4. What region of the tongue is responsible for sensing bitter tastes?
  5. What are the states of matter?

If you answered five; paperclips; red, yellow and blue; the back of the tongue; and gas, liquid and solid, then you would have got full marks in any school exam. But you would have been wrong.

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The Sixth Sense And More

Illustration for article titled Five Science Facts You Learned At School That Are Plain Wrong
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Taste, touch, sight, hearing and smell don't even begin to cover the ways we sense the world. We sense movement via accelerometers, which are located in the vestibular system within our ears. The movement of fluid through tiny canals deep in our ears allow us to sense movement and give use our sense of balance. Make yourself dizzy and its this sense that you are confusing. [Image by Thomas.haslwanter via Wikimedia Commons]

When we hold our breath we sense our blood becoming acidic as carbon dioxide dissolves in it forming carbonic acid. Not to mention senses for temperature, pain and time plus a myriad of others that allow us to respond to the need what is going on within us and the environment around.

Magnetic Repulsion

It is not just paperclips that are magnetic. Both tomatoes and humans interact with magnetic fields, too.

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Paperclip and other objects that contain iron, cobalt and nickel are ferromagnets, which means that they can be attracted to magnetic fields. While the water in you and the tomato – or more accurately the nuclei in the hydrogen in the water in you and the tomato – is repelled by magnetic fields. This interaction is called diamagnetism.

But the forces involved are incredibly weak. So normally you don't notice them. That is unless you have been in a magnetic resonance imaging (MRI) machine. In there, a massive magnet manipulates nuclei of various atoms inside you in such a way that results in detailed images of your inner workings.

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Though you don't need to go to a hospital to see diamagnetic interactions. Just use a couple of cherry tomatoes, a strong magnet, a wooden kebab stick and a pin:

And the types of magnetism don't stop there, but that's for another time.

You're Painting With The Wrong Color

Illustration for article titled Five Science Facts You Learned At School That Are Plain Wrong
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You were taught that primary colours are those that can't be made by mixing other coloured pigments together, and that all other colours can by produced by blending these primary colours. Red and blue fail on both counts. You can make red by mixing yellow with magenta. While a blend of magenta with cyan yields blue. Meanwhile a massive range of hues are inaccessible if you start with just red, blue and yellow. [Image Credit: MARKELLOS via Wikimedia Commons]

Colour theorists had this all worked out by the end of the 19th century but for some reason it hasn't made it to school curriculums. The proof is in your colour printer cartridges. They come in cyan, yellow and magenta, which are the true primary colours.

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Illustration for article titled Five Science Facts You Learned At School That Are Plain Wrong

A Bitter Taste In Your Mouth

Remember those tongue maps that crop up in biology text books? They clearly show how the taste buds for bitter sit at the back of the tongue, with sweet, sour and sweet having their own discrete regions. [Image Credit: MesserWoland via Wikimedia Commons]

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These tongue maps first appeared in 1942 after Edwin Boring of Harvard University misinterpreted a German study from 1901. Despite Boring's mistake the maps soon started to appear in schools texts. Then in 1974 the topic was revisited and the whole idea was roundly discredited. Nevertheless over 40 years later tongue taste maps still persist in biology text books.

Look At The State Of Your Screen

We all learnt solids keep a constant shape because the molecules in them are ordered. These can melt to liquids which keep a constant volume and can be poured. Liquids evaporate to form gases that expand to take up the volume available to them. There we have the three states of matter, end of story.

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Expect of course there is more. Liquid crystals have molecules that are ordered like a solid but are fluid like a liquid. These properties are vital for your cells, shampoo and of course liquid crystal (LCD) flat screen devices.

But why stop at four states. There is plasma, the state of matter for most things in the sun, or Bose-Einstein condensates, superfluids and dozens more.

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Time To Rewrite Textbooks?

There are many more than the five "facts" that need to be fixed in school textbooks. I am not suggesting that we should start teaching 6-year-olds about matter that only appears in Nobel Prize-winning physics labs or filling the curriculum with detail on dozens of senses. But maybe we should stop telling kids fibs.

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Perhaps a biology lesson should start with: "We have many senses, here are the five we are going to learn about." Or a sentence dropped in here and there that mentions the existence of more than three states of matter. As for the tongue map, just rip that page out of the book.

Mark Lorch does not work for, consult to, own shares in or receive funding from any company or organisation that would benefit from this article, and has no relevant affiliations.

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This article was originally published on The Conversation. Read the original article.

Top image via Shutterstock.

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DISCUSSION

I call "FAIL" on the colors. What colors are the primaries depends on your medium and how the colors combine.

In they eyes, it's red, green, and blue that our cone cells concentrate their sensitivity around, making those the primary sensed colors. These are also the primary colors for emittive color mixing. Look at your monitor with a magnifying glass (or, lacking that, take a close look next time you sneeze or spit on it) to see for yourself. You start with black and add red, green, and/or blue in whatever proportions to make your color.

For printing, you're combining pigments to filter out parts of the light scattered from the white substrate (e.g. paper) they are printed on. In this medium you start with white and subtract red, green, and blue to make your color, doing so with the primary colors in this medium: cyan, magenta, and yellow. Cyan subtracts red, magenta subtracts green, and yellow subtracts blue. (In CMYK K stands for "blacK", because b was already taken for blue in the larger context of color space designations, and is mostly there to save ink and make the blacks more balanced.) The inks are transparent to the colors they don't filter.

For paints, you're not so much accumulating filtration of colors as averaging what's scattered since they generally include a white base to cover over whatever you're painting. I'm unclear on the math involved (somebody feel free to jump in with that), but bottom line is the primaries in this medium are, in fact, red, yellow, and blue.