ingridscience

Look at real crystals and match their shapes with drawings.

Under a dissecting microscope: put a few salt/sugar/epsom salt crystals in a small baggie. Place the baggie on black paper to show up the crystal shapes.
Using a magnifier: look at larger sugar or epsom salt crystals, or crystals in rocks.

Salt crystals are cubes. They are best seen under a microscope at 20X or 40X.
Sugar and epsom salt crystals are monoclinic prisms. The smaller crystals of purchased sugar (granulated) or epsom salts (from a pharmacy) best seen under a microscope at 20X or 40X to view the elongated shape with a pointed end. Grow larger sugar or epsom salt crystals and observe with a magnifier or the naked eye.
Amethyst (a kind of quartz) crystals are hexagonal pyramids. They are large enough to see with the naked eye.

The atoms in each of the crystals link in a certain pattern, so making a certain shape crystal.

Students pull apart a flower and look for these parts:
1. anther. the pollen is on the anther. the anther is part of the stamen (made up of the filament stalk supporting the anther)
2. stigma. pollen lands on the (often) wide, sticky stigma. the stigma is part of the pistil (made up of the stigma at the top, style (the stalk) and ovary (inside the flower).

Look at an apple, inside and out, to show these parts:
1. dried remains of the stigma and style at one end of the apple
2. ovary case inside, containing the seeds. the apple flesh is the swollen ovary.
See this link for the parts of the flower becoming the parts of the apple: https://www.researchgate.net/profile/Alexandra-Buergy/publication/35122…

Discuss the process of fertilization and maturation:
pollen from the anther of one flower is transferred to the stigma of another flower (by insects or wind)
DNA from the pollen grain travels down the style to the ovary, where it meets the egg, and fertilization happens
a seed grows in the ovary
the seed can make a whole new plant

Discuss fruit formation:
After fertilization, the ovary around the seeds swells to make the fruit. (see photo of new fruit forming)
This fruit is attractive to animals, that eat it and transport the seeds elsewhere to make new plants.

Before the lesson:
Gather images of the same flower taken in visible light and UV light, and print with permission, or use from a webpage.
Link suggestions:
1. http://www.naturfotograf.com/UV_flowers_list.html#top/ (permission needed for printing).
The following images have a "strong bulls eye pattern" or are described as "strong" in the description:
Arnica angustifolia (Arctic sunflower) http://www.naturfotograf.com/UV_ARNI_ANG.html
Bidens http://www.naturfotograf.com/UV_BIDENSZ.html
Oenothera biennis http://www.naturfotograf.com/UV_OENO_BIE.html#top
Potentilla reptans http://www.naturfotograf.com/UV_POTE_REP.html#top
Rudbeckia hirta http://www.naturfotograf.com/UV_RUDB_HIR.html#top
Sow thistle (looks like a branching dandelion), Sonchus arvensis http://www.naturfotograf.com/UV_SONC_ARV.html#top
Tripleurospermum maritimum http://www.naturfotograf.com/UV_TRIP_MAR.html
2. https://twitter.com/EntomoDaily/status/1651972037013913601
3. https://www.researchgate.net/figure/Floral-images-in-visible-and-UV-lig…
4. https://www.sciencephoto.com/search?q=ultraviolet%20light%20flower&medi…

If prints of the flowers are available, make a transparency copy of the UV patterns.

Students are asked to pair the images, first by shape only (as the colours are different).
Tell them that the pairs are the same flower photographed in two different ways. One of each pair is photographed in visible light, the same as how we see the flower. The second is taken with a camera that can see ultra violet light. We cannot see ultraviolet, but a bee can.
Ask students to lay the UV pattern over the visible pattern - this is what a bee sees - both the visible and the UV patterns together. Students should take apart and rematch the pairs, to explore what we see and what a bee sees.
Discussion: The UV pattern circles or highlights the centre of the flower, where the pollen and nectar are, so the bee is guided by the UV pattern to the nectar and pollen. UV patterns are also called 'nectar guides'.

Other colours seen by animals which humans cannot see:
Snakes can see well in infra red, which is heat, to help them catch (warm) prey.
Reptiles, amphibians, birds and insects can all see more colours than humans.

Bees collect pollen, to feed growing bees in the hive.
Pollen can be different colours, to attract bees.
Once students know that the pollen is on the anthers of a flower, give them magnifiers to find it, look at it closely, and find out what colour it is.
(Tulips have black pollen. Orange lilies purchased in florists have red-brown pollen. Fireweed has green pollen.)
Give them pipe cleaners to gently touch the anthers to pick up pollen.

Crush the plants on the worksheet, to show what colour dyes they contain. The colour may change depending on the chemistry of the paper, and some colours will fade with time as light changes their chemistry.

Crushing to extract the juice from a plant is one of the methods used in plant preparation. Other Indigenous methods for preparing medicinal plants (from J Ethnobiol Ethnomed. 2012; 8:7):

Optional art project to make a card:
Lay pieces of fern on a piece of the cloth in a design you like.
Tape the ferns to the cloth. Make sure they are completely covered with tape.
Use the hammer, or a rock, to pound the ferns onto the cloth. Smash the ferns completely, so their colour transfers to the cloth.
Peel the tape and ferns off the cloth.
Open the card and put a few drops of glue around the edge of the window.
Lay your cloth fern design over the window, so that it is held in place by the glue.
A beautiful card made form a natural dye!

Green leaf chemistry:
The green colour in the fern leaves is called chlorophyll. In living plants, chlorophyll traps the sun's energy for plants to grow.
Indigenous groups have been making dyes from plants for thousands of years. The leaves, petals, bark and seeds of plants have all been used to make different dye colours.

Try to pair up each fresh with dried herb, or dried herb with herb essence, or fresh herb with herb essence.

Herbs may smell strong to discourage animals from eating them.

You can smell the herbs and spices because some of the molecules leaving the herb or spice go up your nose and interact with molecules in your nose. We smell them when their unique shapes fit like jigsaw pieces into the inside of our nose, and stimulate a nerve signal to our brain, which we perceive as smell.

Pair up fresh herb with smell of dried
Students smell the real herbs, by brushing their hands against them then smelling their hands.
Match with bags of dried herbs, whose identity is hidden (see photos).
The pairs of fresh herbs/dried herbs/essences probably didn't have exactly the same smells as they all release slightly different mixtures of smell molecules.
However there is often a main molecule responsible for each distinctive herb smell, so we cue into this odour molecule to match the smells.

Each of the smells has many molecules making it up, but sometimes a predominant molecule that is responsible for the smell:
Oregano has the molecule carvacrol in its smell. Anise seeds have the molecule anethole in their smell. Cloves have eugenol in their smell. Mint has L-carvone in its smell. Garlic has allyl- disulphide in its smell. Rosemary has eucalyptol in its smell.

Optional: show molecule models of the predominant smell molecules in mint and marjoram smells (see photo):
See if students can spot the difference between the molecules responsible for mint and marjoram smells.
Although the chemical shapes are similar, they smell very different.

Most smells are complex mixtures of many molecules so smells often mean something quite different to each of us.

Pair up plant part with smell of essence
Squeeze and sniff the smelly bottles (containing essences). Look at the plant pieces inside the glass jars. Match them up.
Students can also try and match each smelly bottle and jar of plant pieces with a picture of the plants they come from.

For younger students, duplicate the smelly bottles, and ask them to match up the ones that smell the same - use fruity smells too.
For very young students make into a game, where each table is a team. All tables are given the same-smelling tube at one time. The students at a table work together to try and guess what the smell is, and write it down. When the time is up, they hold up their written answer.

Optional for older students: which part of the plant dos each plant piece come from? (Leaves, flowers, seeds, bark or trunk?)
Coffee beans are seeds.
Cedar wood is the trunk.
Lemons are the fruit.
Lavender is the flower.
Oregano is the leaves.
Cinammon is the bark.
Garlic is the bulb (underground leaves).

Two tubes contain tomato, two tubes contain banana and two tubes contain strawberry.
Smell the tubes and find the pairs.

For each pair, one tube contains ripe fruit and one contains unripe fruit.
Can you smell which is ripe and which is unripe?

Check your smells by pulling the sleeve down off the tube.

What's going on?
As a fruit ripens it makes new chemicals that change its smell.
Ripe smells attract animals, which eat the fruit and spread the seeds.
Fruits also change colour as they ripen, also to attract animals.
What colour is your favourite fruit before and after it ripens?

Each player picks up a bingo board (see attachment).
Each player chooses 4 of the bingo picture cards (see attachment), making sure that different players choose a different set of picture cards.
Glue each of the bingo picture cards to its own square of the bingo board.
Take your bingo boards into the garden/park. Find the things on your bingo card. First to find them all calls BINGO!

Smell and look at the cut flowers. Use the clues below to find out which insects would be attracted to each flower.

Bee: I like yellow, white, blue and purple flowers. I like flowers that smell sweet.
Butterfly: I like all coloured flowers - and unlike most other insects, I can see red. I like flowers that smell sweet.
Fly: I usually pollinate white, green, yellow or brown flowers. I like flowers that might smell funky to you - they have a strong smell that is not all sweet.

Or go outside on a sunny day when flowers are out and observe what insects land on them. Record what you find: what insect lands on what flower, the colour and smell of the flower.

What’s going on?
Each flower is adapted to attract one or more kinds of insects to it. When the insects collect nectar to eat, they move pollen from one flower to another. The pollen fertilizes the fowers.

Smell the fragrant leaves, flower petals and fruit peels. Choose two or three that you like best. Pick out one leaf, petal or piece of peel from each of your chosen plants. Tear the leaves/petals/peel into small pieces and put them in the mortar.
Add one spoonful of water. Grind with the pestle - push down while you grind in a circle. Grind until the plants are completely mashed up.
Suck up the perfume with a dropper. Put the perfume in a small tube to take home. Think up a fancy name for your perfume. (Your perfume will smell nice for just a day or two, so use it soon!)

What’s going on?
You used water to extract the fragrant chemicals from the plants. Professional perfume makers also extract fragrant chemicals from plants using water, or other solvents. Then they mix different fragrances to design new perfumes.