Saturday, May 12, 2007

Matchstick boats

Build matchstick boats that will zip across a water surface - powered only by soap.

You will need:
  • A matchstick
  • A bowl or tray of clean water, which isn't soapy
  • A knife
  • A drop of washing-up liquid
What to do:

First, use the knife to make a split in the wooden end of the matchstick, making it into a Y shape.
Fill the bowl with water (just a cm or so is fine).
Gently float the matchstick on the water.
Place a tiny drop of washing-up liquid into the split on the matchstick.
The matchstick zips away from the washing-up liquid as soon as you drop the washing-up liquid on the water.

What’s going on?

Water molecules have an attractive force between them, so if you imagine that you're a water molecule right in the centre of a tank of water, you'd be pulled in every direction by all the water molecules around you - and all these forces would cancel out so you wouldn't move. But if you’re a water molecule at the surface then you won’t be pulled from the top at all because there is just air above you. So, you end up with a more dense film of molecules on top of the water. The result of this is surface tension – the molecules are more attracted to each other then to the air above. Water molecules are also attracted to other substances, so a matchstick, for example, will be pulled by the water wherever it is touching it.
Washing-up liquid is a surfactant, which is something that breaks down surface tension. So by adding washing up liquid, one side of the matchstick has the attraction between the water molecules broken, whereas on the other side of the matchstick, they're still attracting each other and the matchstick.
What the matchstick feels is a pulling force from all the molecules on the clean water side, but on the other side there is virtually no surface tension. So rather than being repelled by the washing-up liquid, it's actually being pulled from the other side, across the bowl of water. Clever eh?

Cheesy Waves

Microwaves in a microwave oven are the kind of waves that don't travel anywhere but just stay in one place. These are called standing waves. You can make standing waves with a skipping rope or by banging a drum. In this experiment you can see standing waves by melting cheese in a microwave oven. Plus of course afterwards there is the added bonus of eating it!

You will need:

  • A microwave oven

  • Some slices of processed cheese

  • A (microwaveable) plastic tray

What to do:

Remove the turntable from the microwave.
Lay strips of cheese on the tray and put it into the oven.
Either give it a quick blast (about 10 sec) on high power or try leaving it in there for 1 min on a low setting like defrost. (This is better if your microwave timer doesn't have seconds on it).
Take the tray out of the oven and look to see where the cheese has melted. The places where the cheese has melted show where the microwaves inside the oven are biggest (where the waves have maximum amplitude).

What's going on?

In some parts of the oven, the waves have a high amplitude and the cheese gets hot and melts. In other parts, the amplitude is small, or zero, and the cheese doesn't melt.
This is why you need a turntable in a microwave oven. If the food isn't turned round it doesn't get cooked evenly all over.
(I did this experiment in the microwave in the staff room and saw parts where the cheese didn't melt!)

Wednesday, April 25, 2007

'Kryptonite' discovered in mine

Kryptonite is no longer just the stuff of fiction feared by caped superheroes.
A new mineral matching its unique chemistry - as described in the film Superman Returns - has been identified in a mine in Serbia.
According to movie and comic-book storylines, kryptonite is supposed to sap Superman's powers whenever he is exposed to its large green crystals.
The real mineral is white and harmless, says Dr Chris Stanley, a mineralogist at London's Natural History Museum.
"I'm afraid it's not green and it doesn't glow either - although it will react to ultraviolet light by fluorescing a pinkish-orange," he told BBC News.
Rock heist
Researchers from mining group Rio Tinto discovered the unusual mineral and enlisted the help of Dr Stanley when they could not match it with anything known previously to science.
Once the London expert had unravelled the mineral's chemical make-up, he was shocked to discover this formula was already referenced in literature - albeit fictional literature.
"Towards the end of my research I searched the web using the mineral's chemical formula - sodium lithium boron silicate hydroxide - and was amazed to discover that same scientific name, written on a case of rock containing kryptonite stolen by Lex Luther from a museum in the film Superman Returns.
"The new mineral does not contain fluorine (which it does in the film) and is white rather than green but, in all other respects, the chemistry matches that for the rock containing kryptonite."
The mineral is relatively hard but is very small grained. Each individual crystal is less than five microns (millionths of a metre) across.
Elementary clash
Identifying its atomic structure required sophisticated analytical facilities at Canada's National Research Council and the assistance and expertise of its researchers, Dr Pamela Whitfield and Dr Yvon Le Page.
"'Knowing a material's crystal structure means scientists can calculate other physical properties of the material, such as its elasticity or thermochemical properties," explained Dr Le Page.
"Being able to analyse all the properties of a mineral, both chemical and physical, brings us closer to confirming that it is indeed unique."
Finding out that the chemical composition of a material was an exact match to an invented formula for the fictitious kryptonite "was the coincidence of a lifetime," he added.
The mineral cannot be called kryptonite under international nomenclature rules because it has nothing to do with krypton - a real element in the Periodic Table that takes the form of a gas.
Power possibilities
Instead, it will be formally named Jadarite when it is described in the European Journal of Mineralogy later this year.
Jadar is the name of the place where the Serbian mine is located.
Dr Stanley said that if deposits occurred in sufficient quantity it could have some commercial value.
It contains boron and lithium - two valuable elements with many applications, he explained.
"Borosilicate glasses are used to encapsulate processed radioactive waste, and lithium is used in batteries and in the pharmaceutical industries."

Monday, April 23, 2007

Rope around the Earth

You have a piece of rope that just fits around the Earth. If you put 1 metre high sticks right around the equator and lay the rope on top, how much longer does the rope need to be to make ends meet? Answer below as a comment.

Tuesday, April 17, 2007

The World's most perfect sphere?

Engineers don't often indulge in poetic flourish when discussing the things they build. So when words like "beautiful" and "elegant" and "artful" frequently cross the lips of scientists and engineers as they talk about the design of Gravity Probe B (GP-B), one might suspect that this spacecraft is truly something special.Using the most perfect spheres humans have ever created.
Gravity Probe B just might turn Einstein's theories upside-down.

The probe, which launched April 20th on a mission to test an unproven aspect of Einstein's theory of relativity, is by all accounts a marvel of human ingenuity and know-how. Only recently has it even become technologically possible to build Gravity Probe B, despite the fact that the idea for the experiment has been around since the 1950s.

"If experimental science is an art, then I would look at GP-B as a Renaissance masterpiece," says Jeff Kolodziejczak, NASA's Project Scientist for GP-B at the Marshall Space Flight Center. The beauty of GP-B's design lies in part in its ability to create, in the messy real world, a pocket of near-perfection. The goal of the experiment demands it. Researchers hope to detect a bending of spacetime around Earth so subtle that even a minute interference from some outside force or a tiny internal imperfection in the spacecraft itself would mask the effect they're hunting for.

Einstein's theory of General Relativity predicts that Earth, by rotating, twists space and time around with it, forming a mild vortex in the fabric of spacetime around our planet. Researchers call this "frame dragging." Most physicists believe the spacetime vortex is real, but no experiment to date has been sensitive enough to detect it unequivocally.
Enter Gravity Probe B.

The idea behind the experiment is simple: Put a spinning gyroscope into orbit around the Earth, with the spin axis pointed toward some distant star as a fixed reference point. Free from external forces, the gyroscope's axis should continue pointing at the star--forever. But if the region of space through which the gyroscope orbits is slightly twisted, as Einstein's theory predicts, the direction of the gyroscope's axis would drift ever-so-slightly over time. By noting this change in direction relative to the star, the subtle frame-dragging effect can be measured.
Left: A spinning spherical gyroscope in Earth orbit should wobble due to frame dragging.
It sounds like a straightforward experiment; the trick is in actually building it. The gyroscope's axis won't drift much, only 0.042 arcseconds over a year, according to calculations. (An arcsecond is only 1/3600th of a degree.) To measure this angle reasonably well, GP-B must have a precision of 0.0005 arcseconds."Every aspect of the experiment has to be nearly perfect," Kolodziejczak says. Meeting this challenge has taken almost 40 years of effort from many bright scientists and engineers, primarily at Stanford University, NASA's Marshall Space Flight Center, and Lockheed-Martin.

The Gravity Probe B team had to create the roundest gyroscopes ever made, and set them orbiting Earth inside a force-free pocket. No form of atmospheric drag or magnetic forces could be allowed to penetrate the gyro-chambers. That's tricky because Earth's far-flung magnetic field envelops GP-B and, even at an altitude of 400 miles, Earth's outermost atmosphere exerts drag on the spacecraft. Furthermore, it would be necessary to measure the tilt of the gyroscope's spin axis ... without ever touching the gyroscope itself.
The gyroscopes in GP-B are the most perfect spheres ever made by humans. (The experiment actually carries four gyroscopes for redundancy.) These ping pong-sized balls of fused quartz and silicon are 1.5 inches across and never vary from a perfect sphere by more than 40 atomic layers. That means that if these gyroscopes were the size of the Earth, the elevation of the entire surface would vary by no more than 12 feet! If these gyroscopes weren't so spherical, their spin axes would wobble even without the effects of frame-dragging, thus ruining the experiment.

Being in orbit allows the spheres to float within their housings as if weightless, but without other controls, the spinning spheres would still tend to drift and bump into the walls of their containers. The reason is that the spacecraft is being slowed slightly by aerodynamic drag, while the free-floating spheres within the spacecraft's belly are not.
The GP-B team solved this problem by developing a drag-free satellite.
Inside the spacecraft instruments monitor the distance between one of the gyroscopes and its chamber walls with extraordinary precision -- to within less than a nanometer (a millionth of a millimeter). The spacecraft's thrusters respond to any changes in that separation. In effect, the spacecraft chases the gyroscope and flies along the same "drag free" orbital path that it does.
The spheres must also be protected from Earth's magnetic field. Why? Because a faint magnetic signal from the gyroscopes themselves will ultimately be used to detect the all-important change in angle of their spin axes. The intrusion of Earth's magnetic field would swamp that signal.

But how do you block a planet's magnetic field?

"We used superconducting bags," says Kolodziejczak. The gyroscope assembly is placed inside lead bags, which in turn are placed inside a large cryogenic container called a "dewar" holding 400 gallons of liquid helium. The helium cools the lead bags to 1.7 degrees above absolute zero (1.7 K, or about -271 °C). At this temperature the lead becomes a superconductor, thus blocking out Earth's magnetic field. The ambient magnetic field within these bags is reduced to less than 3 micro-gauss, which is about the same as in deep interstellar space.

Gravity Probe B's big dewar holds hundreds of gallons of liquid helium.

The extreme cold also helps create an ultra-low pressure vacuum in the gyroscope chamber; after pumping out most of the gas, the molecules of gas that remain are very cold and thus hardly moving, which means they exert almost zero pressure. In this pristine, high-vacuum environment, the spherical gyroscope could spin at its operating speed of 10,000 rpm for 1,000 years without slowing by more than 1 percent.
Finally, it's necessary to measure the gyroscopes' spin without nudging the gyroscopes in the slightest.

Once again, superconductivity comes to the rescue. A superconducting sphere, when spun, will produce a weak magnetic field that is precisely aligned with the axis of rotation. The gyroscopes are therefore coated with a metallic layer of niobium of near-perfect uniformity. At the cryogenic temperature in the core of GP-B, niobium becomes a superconductor and it produces a magnetic field when the spheres are spun. By monitoring the magnetic field, engineers can monitor the spin of the gyroscopes--no touching required!

To do this, the GP-B scientists use a remarkable device called a SQUID--short for "Superconducting QUantum Interference Device." Attached to a loop of superconducting wire closely encircling each gyroscope, a SQUID functions as an ultra-sensitive magnetic field detector. SQUIDs can detect a change in this field of only 50 billionths of a micro-gauss (5 x 10-14 gauss), which equates to a change of the gyroscope's angle of 0.0001 arcseconds.
A telescope onboard the spacecraft constantly watches a distant star named IM Pegasus. This serves as an external reference point for measuring the tilt of the gyroscopes. IM Pegasus isn't truly a fixed point, though. It will drift ever-so-slightly during the 2 year lifetime of the GP-B mission. Fortunately, astronomers know very precisely how far it will drift, so that motion can be accounted for.

Telescopes. Gyroscopes. Superconducting lead bags and SQUIDs. These are odd materials for art. Among engineers and physicists, though, there's no doubt: Gravity Probe B is a masterpiece.

Two Candle Riddle

A candle flame consumes oxygen and produces water vapour and carbon dioxide. Carbon dioxide is heavier than air. But cover two candles with a jar and the taller one goes out first … why?

Thursday, April 12, 2007

The Rock in a Boat in a Pool problem

Post your answer and explanation as a comment below.

This problem is famous for stumping Robert Oppenheimer, one of the most famous physicists of the 20th Century and two of his physicist pals George Gamow and Felix Bloch so don't be afraid to try! You can demonstrate and prove the answer with some plastic containers and a rock! Oppenheimer directed the Manhattan Project which led to the development of the first atomic bomb. After seeing the first ever explosion of an atomic bomb in the New Mexico desert, he said ‘we knew the world would not be the same’. He later opposed the development of an even more powerful hydrogen bomb.

Saturday, March 31, 2007

Science to save your life!

Picture the scene – you're laid out on a raft, the sun is beating down, your mouth feels like the bottom of a birdcage. "Water! Water!" you gasp through parched lips. The seawater surrounding you mocks back "Hah! Try drinking this matey and you'll know about it!"
But wait! What's this? You managed to grab a large bowl, clingfilm, sticky tape, a glass and a small rock before the ship sank (!). Thank goodness for that! Now all you need is to make a solar still…

You will need:

  • large bowl

  • short glass or cup

  • plastic wrap

  • small rock

  • pitcher of water

  • salt

  • long spoon for stirring

What to do:

First make saltwater by adding salt to fresh water. Stir the water until the salt dissolves. Now pour about two inches of saltwater in a large bowl. Take an empty glass and put it in the bowl. The top of the glass should be shorter than the top of the bowl, but higher than the saltwater. Put clingfilm over the top of the bowl. You may need to use tape to make sure the seal is tight. The last step is to put something heavy right in the centre of the clingfilm, over the empty glass. That will weigh the plastic down and help you collect the water. Now you've made a solar still. It's called a still because it distills, or purifies, water. Leave your still outside in the sun. Leave it alone for a few hours, or even a whole day. The longer you leave it out, the more water you'll collect. When you're ready to check your still, take the plastic wrap off and look at the water that's collected in the cup. Do you think it's salty or fresh? Taste it – it's fresh! (make sure all the items are cleaned thotoughly before you try this experiment though!)

What's going on?

Rays from the sun heat up the salty water in the bowl. When the water gets warm, it evaporates and becomes a gas. When the gas rises and hits the clingfilm, it turns back into water droplets. Eventually, gravity makes the water droplets roll down the clingfilm towards the rock. Then the water droplets slide off the clingfilm into the glass. The salt doesn't evaporate, so it gets left behind in the bowl. Water evaporates in the same way from lakes, rivers, and oceans. The water heats up, turns into a gas, and then condenses to fall back down as rain. Now, can you distill fresh water from other liquids like cola or orange juice?

Did you know?

This can also be done with urine if you're in the desert and water is hard to come by. If you do not have a pot, you can just dig a hole in the ground, do your business in the hole, place a glass/container in the middle and cover with something (plastic bag works). The natural heat of the sand will evaporate the clean water into the glass. You never know, it may save your life!

Egg Engraving

This is like engraving in reverse i.e. your name will stand out in relief from the shell rather than be etched into it.

You will need:

  • Hard boiled egg
  • Wax crayon
  • White vinegar
  • Large glass or bowl (big enough to hold the egg)

What to do:

Ask an adult to hard boil an egg for you. Print your initials or your first name, large and fairly thick, on the shell of a hard boiled egg with the wax crayon. Now put the egg in a glass large enough to hold it and add enough fresh white vinegar to cover it. Tiny bubbles should form on the egg which show that the acid in the vinegar is reacting with the shell. The shell under the waxy letters is protected from this acid action. In an hour or two, when the bubbling stops, replace the now neutralized vinegar with a fresh supply. After another two hours wash off the egg under running water. Rub your fingers over the letters and they should stand out in relief. You can even try to GENTLY remove the wax coating with a soft brush and scouring powder under running water.

What's going on?

An average eggshell is 2.35mm thick. It's made of 3.5% protein, 1.5% water, and 95% calcium carbonate mineral. It is this mineral that reacts with the acetic acid in vinegar. The wax protects the shell from coming into contact with the vinegar. If half of the shell has dissolved during the four hours, then it has only about a 1.25mm thickness left. So be careful!

Tuesday, March 27, 2007

How good are your vectors?



Warning: do not play this game if you are easily offended

Friday, March 23, 2007

Energy for the Future lecture

















Mr Anders Ihle from ECC Care Thailand came to present an Environmental Technologies for the Future lecture as part of the Science and Technology Week. Click on the image above to watch the talk, or download the podcast below to listen to it. His powerpoint is also available on a link below. Thanks to Mr Ihle for his highly entertaining and informative lecture. If you have any questions for him you can email him at andersihle@yahoo.com

Right click here, "save target as" to download the podcast (98MB *.mp3)

Rick click here, "save target as" to download the powerpoint used in the lecture (14MB *.ppt)

Tuesday, March 20, 2007

The Winner, the Thief and Science Week

Congratulations to Roy in 8A for he was the first to solve the finger print jigsaw last week - he must have sent it at lunchtime on the first day to beat the rest - do you know who's fingerprint it was? Roy, come to the Science office and collect your prize from Mr Taylor. The thief was named today as Dr Macgregor - once again thanks for all the emails accusing me and the furtive looks on the corridor because you thought it was me all week long. Dr M spent two days in jail over the weekend after analysis of video footage revealed this photo of her in lab 2. As punishment she has to do community service as a Chemistry teacher here at Bangkok Patana school for the rest of the year - she is appealing against the severity of the sentence. Don't forget to thank your Science teacher and especially the Science technicians (Khun A, Khun Gun, and Khun Pornpen) for all the exciting activities that were prepared for you last week. If you have any photos from Science Week that you would like to share then please email me.

Einstein's box snares photon

In 1927, Albert Einstein conceived of a box in which light was trapped and a single light particle, or photon, was released in a theoretical experiment to measure the relationship between mass and energy.

Eighty years on, French physicists say they have created Einstein's box: a device just 2.7 centimetres big that snares a photon, enabling it to be monitored from birth to death.

They publish their work today in the journal Nature.

Photons are arguably the ultimate existential particle in physics. By switching on a light bulb, you release a million billion of them every second.

But as soon as you see a photon, it dies, as its contact with the retina expends the energy that made it exist.

"Photons are easy to detect. You do it yourself, every second for instance when you are looking at a computer screen," says co-author Professor Jean-Michel Raimond of France's National Centre for Scientific Research (CNRS).

"But you do this only once. It's post-mortem analysis. We, though, can now analyse it in real time, while the photon is still alive."

The box is a cavity with walls made from ultra-reflective, superconducting mirrors able to trap a photon for about a seventh of a second.

That may not seem much but it is worth considering that, in the same time, a free photon would travel about a tenth of the distance from the Earth to the Moon.

A new way to count photons

The conventional way of counting photons is by a light detector that works by absorbing the energy by impacting particles. But the collision destroys the photons, so what is needed is a 'transparent' counter.

The French team says it has found the answer in a stream of rubidium atoms, which cross the box in which the photon is trapped.

Photons have an electrical field that slightly changes the energy levels of the atom, but in this case, not enough to let the atom absorb energy from the field.

When an atom crosses the photon's electrical field, this causes a tiny delay in the electrons that orbit the atom's nucleus.

The delay is measurable, using the technique of modern atomic clocks, which use electrons' orbit as a 'pendulum' to provide a precise time.

Quantum 'masterpiece'

In a commentary also published by Nature, Professor Ferdinand Schmidt-Kaler, a quantum physicist at Germany's University of Ulm, describes the achievement as an "experimental masterwork".

He says it has major implications for quantum computing, a field that proponents claim will make one of today's supercomputers look like an abacus.

Instead of using the binary digits 0 and 1 to hold information, quantum computing is based on a principle of quantum mechanics, changes of state, called superposition, that occur at the atomic level.

Quantum information, or a qubit, can be a 0 or 1 or simultaneously as both 0 and 1, amounting to a potential boost in data storage, but only useful so long as it can be controlled and accessed.

Photons, atoms and ions have been used as qubit carriers in this area of research.

The experiment demonstrates that "a stream of atomic qubits can be fully controlled by the qubit state of a trapped photon", says Schmidt-Kaler.

Related Stories

Friday, March 16, 2007

Friday, March 9, 2007

Science week: Finger print challenge

The year 7's will become CSI's trying to find out which science teacher stole the delicious ice cream as part of the Science Week. Can you solve this jigsaw fingerprint of one of the Scientists? Which member of the Science Department do you think it is? Click on the image to start solving the jigsaw. Post your guess as a comment below. First completed jigsaw as a screen print emailed to brta@patana.ac.th will win a prize!

National Science and Engineering Week 9-18th March

Thursday, March 8, 2007

National Science and Engineering Week 9-18th March

Only two more days to go - have you signed up or any cool lunchtime experiments next week? See the notice board on the Physics side stairs 2nd floor for more details.

Vote for you favourite experiment here

Tuesday, March 6, 2007

National Science and Engineering Week 9-18th March

Here is the next experiment for you to watch...........

Vote for you favourite experiment here

Monday, March 5, 2007

Can you make these Water Spikes?

Here’s something to do for National Science and Engineering Week 2007! Now before we start I have a confession. I tried this out and it didn’t work. Distilled water yes, freezer at minus 11.5 degrees C hmmmm, maybe (didn’t measure it at the time). So I am throwing down the gauntlet to anyone who wants to give it a go. Send me a photo of your ice spike with your face and first name on a piece of paper next to it. Just so that I have proof y’understand – yes those Google Images are soooo useful at times aren’t they? All those entering will be put in a draw for a pack of AQA GCSE Sciences Flashcards courtesy of Hodder Murray (www.hoddereducation.co.uk) and a 100 baht snack card.

You will need:

Distilled water (you can get this from a petrol station)
Ice cube tray
Freezer

What to do:

Fill the ice cube tray with distilled water.
Place in a freezer whose air temperature is at least -11.5 degrees C.
Leave for an hour and a half.
You should see a short spike of ice protruding from each cube.

What’s going on?

The short explanation is this: as the ice freezes fast under supercooled conditions, the surface can get covered except for a small hole. Water expands when it freezes. As freezing continues, the expanding ice under the surface forces the remaining water up through the hole and it freezes around the edge forming a hollow spike. Eventually, the whole thing freezes and the spike is left.
But you may find fuller explanations in the following websites:

You, too, can grow ice-cube spikes in your own freezer!

Ice Spikes

Got Spikes on Your Ice Cubes?

See video

Diagram of how spikes are formed

The draw will take place at 5pm on Wednesday 21st March.

Saturday, March 3, 2007

Eclipse set to be 'best in years'

Skywatchers eagerly awaiting Saturday's total lunar eclipse say that the spectacle could be the "best in years". The eclipse begins at 2018 GMT, with the Moon totally immersed in the shadow of the Earth between 2244 and 2358 GMT. During "totality", only light that has been filtered through the Earth's atmosphere reaches the Moon's surface, making it appear a reddish colour.
The eclipse will be visible from the whole of Europe, Africa, South America, and eastern parts of the US and Canada. "They are beautiful events," said Robert Massey, spokesman for the UK's Royal Astronomical Society. "They have a really romantic feel to them as you look up because the Moon, which is normally pearly white, takes on this reddish colour." He added that it was totally safe to observe and no protective filters were needed because the Moon would actually be less bright than during a normal full moon.

Saturday, February 24, 2007

National Science and Engineering Week 9-18th March

Another one for you to vote for:

Vote for you favourite experiment here

National Science and Engineering Week 9-18th March

The last one for this week - remember to check for me next week!

Vote for you favourite experiment here

National Science and Engineering Week 9-18th March

Have you been watching these experiments? Which one is your favourite so far? You can vote for them online (see link under the video). Here is the 3rd of 8 (see Feb archives for previous experiments).

Vote for you favourite experiment here

National Science and Engineering Week 9-18th March


Vote for you favourite experiment here

National Science and Engineering Week 9-18th March


Vote for you favourite experiment here

Tuesday, February 20, 2007

A-maze-ing onions


You will need:

An onion (ideally already sprouting)
A shoe box
Another spare cardboard box
Strong scissors
Sticky tape

What to do:

First build a maze for your onion!
Use your spare cardboard box to cut rectangles about the same size as the smaller side of the shoe box. These will be the dividers inside your maze. You need at least two but you could make more if you like.
For each divider, cut a ‘window’ in the cardboard about 3 cm square. It will make the maze more interesting if they are in different positions on each divider.
Cut an ‘exit’ door for the onion shoot at one end of the shoe box.
Put the onion at the other end of the shoe box..
Fit the dividers into the box, spacing them out between the onion and the exit. Try to put them in so the onion will have to change direction to get through each hole.
Try to find a sunny place to leave it (so the sun can shine on the exit) but where it won’t be disturbed.
Leave for about 3 weeks and then check to see how it’s getting on.

What’s going on?

The sprouts on your onion should have started to find their way out of the maze. They are growing towards the light coming through the exit. Biologists call this phototropism. You might have noticed this already with indoor plants. They grow towards the light, and can get very lopsided unless you turn their pots round occasionally.

So how does the onion ‘know’ where the light is, and how does it grow towards it? The tips of plant shoots contain a growth hormone called an auxin, which makes the shoot grow faster. But light destroys the auxin, so it only works on the side that doesn’t have any light. The side without any light grows longer and the shoot ends up bending towards the light.

You might have also noticed that plants without much light grow long and spindly. This is because there is lots of auxin in the plant and it grows fast – but the plant won’t be very healthy because it needs light to make food for itself by photosynthesis.

More ideas

Try seeing if a sprouting potato can find its way through the maze. Have a race between the potato and the onion to see which shoots grow quicker.

You could grow plants from identical seeds, one in the dark and one in the light to compare them. Look especially at the colour of the leaves. Think of ways to test whether the auxin is only in the tips of the shoots or all along the shoots.

Friday, February 16, 2007

Lion vs Leopard vs Hyena


Who will win a tug-of-war between these three?

Secret writing

There are many ways of writing secretly. A good spy should know at least three but we'll give you FOUR!

You will need:

Candle or white wax crayon
Paper
Water-based paint
Cotton buds
Lemon juice
Bicarbonate of soda
Red cabbage water (see instructions)
Pencil
Paintbrush

What to do:

Method 1: Candle or white wax crayon
Write your message on a piece of paper using the candle or crayon.
Now paint over the message with water based paint. See the message now? Aha!

Method 2: Lemon juice
Write your message on a piece of paper using a cotton bud dipped in lemon juice. Now either iron over the message (ask an adult to do this) or place it near a light bulb (ask an adult to do this). We don't want anyone getting burnt! See the message now? Oooh yes! And it's gone brown!

Method 3: Pencil and wet paper
Wet some paper, just a bit, and place another sheet of paper on top. Use the pencil to write your message quite gently. Take the topmost paper off. Wait for the wet paper to dry.
Now wet the paper again. Well would you believe it? There's the message.

Method 4: Bicarbonate of soda and red cabbage water
Dissolve two teaspoons of bicarbonate of soda in four tablespoons of warm water.
Write your message on the paper using a cotton bud dipped in the solution.
Let it dry.
Pour hot water over some shredded red cabbage leaves. Leave for 15 mins and then strain. You should have a dark purple solution.
Paint the red cabbage water over your message. Well I never!
Try it again but this time use lemon juice instead of bicarbonate of soda.

What's going on?

Method 1: Candle or wax crayon
Wax is oil based and oil and water do not mix. The paint will not stick to the wax message so the paint soaks into the paper and leaves the waxy areas paint-free. Your message will show up white against a coloured background.

Method 2: Lemon juice
The lemon juice is very nearly clear so does not show up on the paper when it is dry. When you heat the paper, the lemon juice starts to burn. Like all organic material (i.e. anything that was once living), the lemon juice contains carbon. When it burns, some of the carbon is released in the same way a candle releases soot. The brown writing is just the carbon that has come out of the charred lemon juice.

Method 3: Pencil and wet paper
The pressure from your pencil will mash up the fibres on the lower, damp sheet of paper. Mashed up fibres reflect the light differently to normal, unmashed fibres.
But when the paper dries, the fibres look the same, so your message disappears - until you wet the paper again.

Method 4: Bicarbonate of soda and red cabbage water
Red cabbage water is a dark purple colour. It is a natural indicator which means it changes colour in the presence of acids or alkalis. With acids it turns red or pink and with alkalis it turns blue or green. Bicarbonate of soda is alkaline and when the red cabbage water is painted on it turns blue and shows up against the purple background. If you use lemon juice instead the message will appear red against a purple background.

Saturday, February 10, 2007

Thursday, February 8, 2007

Saturday, February 3, 2007

Animation vs Animator


Ok so it's not related to Science, but I enjoyed this so much I thought I'd share it with you. Enjoy!

Tuesday, January 30, 2007

Bees cooking hornets.........


Watch this amazing clip of bees 'cooking' an invading hornet by vibrating their bodies!!!

Tuesday, January 23, 2007

Do you know your elementary particles?



There was a time in the last century when the only subatomic particles we knew were the proton, neutron, and electron. But in the past 40 years or so physicists working at particle accelerators—or "atom smashers" in the lay lingo—have ferreted out a menagerie of so-called fundamental particles, everything from the charm and strange quarks to the gluon and tau neutrino. In this gallery, view visual representations of the most important fundamental particle discoveries—discoveries that have deepened physicists' understanding of the building blocks of nature as well as led to their appreciation of key aspects of string theory, such as supersymmetry. Read more...... and click here to see a larger version of the animation above.

A Theory of Everything?



Starting at an everyday scale, travel by powers of 100 down into the infinitesimally itsy-bitsy world of strings. In this excerpt from his book The Elegant Universe, Brian Greene explains why string theory might hold the key to unifying the four forces of nature.

How can you lift an icecube with a matchstick?

You will need:
An ice cube
A matchstick
Salt
What to do:
Sprinkle some salt on top of the icecube.
Place the matchstick lengthwise on top of the icecube with part of the stick extending.
Wait a few seconds.
Now try lifting the matchstick up.
The matchstick is frozen to the ice. So the icecube can be lifted using a matchstick.
What's going on?
The matchstick becomes attached to the ice cube because the salt lowers the freezing point of water and melts the ice. The top of the ice cube quickly re-freezes which traps the matchstick. Simple eh? Plus a great trick that you can do whilst waiting for your food to arrive next time you're out for dinner.


See more experiments like this on the practical of the week link.

How can you lift an icecube with a matchstick?

You will need:

An ice cube
A matchstick
Salt

What to do:

Sprinkle some salt on top of the icecube.
Place the matchstick lengthwise on top of the icecube with part of the stick extending.
Wait a few seconds.
Now try lifting the matchstick up.
The matchstick is frozen to the ice. So the icecube can be lifted using a matchstick.

What's going on?

The matchstick becomes attached to the ice cube because the salt lowers the freezing point of water and melts the ice. The top of the ice cube quickly re-freezes which traps the matchstick. Simple eh? Plus a great trick that you can do whilst waiting for your food to arrive next time you're out for dinner.

Colourful Coins...

You will need:

Saucer
Paper towel
Vinegar
A few pennies (or other foreign coins with a copper coating)

What to do:

Fold the paper towel in half a couple of times and put into the saucer. Pour on enough vinegar to cover the paper towel.
Place the coins on the wet paper towel and leave for a few hours.
What has happened to the coins? Pick them up and compare the sides exposed to the air with the sides next to the paper towel.
Wash the coins and your hands carefully when you have finished the experiment.

What’s going on?

The coins go a blue-green colour because the vinegar (aka acetic acid) reacts with the copper to make copper acetate.

Copper acetate has been used since Egyptian times as a green pigment called verdigris. It is the most common green pigment found in medieval manuscripts, probably because it is so easy to make. The scribes or artists simply had to place some copper strips in vinegar and then scrape off the green powder when it had formed.

You may see less verdigris on the bottoms of the coins. This could be for two reasons. One is because the reaction needs an oxidising agent. In this situation the oxidising agent is oxygen from the air. The bottoms of the coins are right next to the wet paper towel and don’t have as much oxygen around them, so more of the copper will stay as it is.


And more?

Most copper coins go dull after a while as the copper becomes oxidised by the oxygen in air. Leave dull copper coins soaking in tomato ketchup. The oxidised copper reacts and the product goes into the tomato ketchup solution, so you are left with unreacted shiny copper.

You may get a surprise when you see the real colour of the copper coins! To be certain this colour did not come from the tomato ketchup, try using brown sauce instead – do the coins go the same colour as they did in the ketchup?

Note:

Copper acetate can be an irritant and is harmful if inhaled or swallowed, so make sure you wash your hands (and the coins) very well.

Also, technically it is illegal to ‘deface coins of the realm’ – and that’s why we suggested using foreign coins. (We don’t want anyone arrested for trying out our experiments.)

Monday, January 22, 2007

Can a human skydiver fall faster than a peregrine falcon?


What is the terminal velocity of a human and a peregrine falcon? Which is greatest? Watch this amazing 5 min clip to see which animal wins the incredible race!

Friday, January 19, 2007

Wednesday, January 17, 2007

Protection for 'weirdest' species

A conservation programme for some of the world's most bizarre and unusual creatures has been launched by the Zoological Society of London (ZSL). Read on.......

Monday, January 15, 2007

Anti-cancer chicken eggs produced

Chickens that can lay eggs containing cancer-fighting proteins have been created by scientists in Scotland. Read on........

Thursday, January 11, 2007

Improve your motor skills.................



Easy at first, just try the later levels! Press 'S' to turn off the sound.