Tag Archives: poster

Happy Mid-Autumn Festival! New infographic: Chemistry of MOON CAKES

Chemistry of MOON CAKES infographic jameskennedymonash
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Mid-Autumn Festival (中秋节) is a traditional Chinese festival celebrated on the 15th day of the 8th lunar month each year (a full moon night in September). It started as an agricultural tradition (like harvest festival in western cultures) around 1000 BC in the Zhou Dynasty, and was formally acknowledged as a festival during the Northern Song Dynasty (between 960 and 1279 AD).

Today, Mid-Autumn Festival is celebrated with moon cakes, family reunions and three days off work. Moon cakes are circular to represent the full moon that always occurs on the Mid-Autumn Festival. Watch the video below to learn about the story behind the festival:

Moon cakes consist of crust, filling and an egg wash. The crust is made from flour, the polysaccharides in which bind together at oven temperatures to form a strong, intricate network (also including proteins) that allows the moon cake to keep its all-important circular shape.

The crust also contains invert sugar syrup, which is chemically similar to both honey and golden syrup. Invert sugar syrup is made by hydrolysing sucrose into its constituent monomers, glucose and fructose. The result is a sweeter-tasting, gooey liquid that doesn’t crystallise during cooking. This gives the moon cake a smooth mouthfeel.

Peanut oil (a blend of mostly monounsaturated triglycerides) is added to the crust for two reasons. First, it is a non-volatile liquid at room temperature, which prevents the moon cake from drying out. Second, the peanut oil molecules disrupt the protein matrix in the crust and give it an even smoother texture (not a doughy texture).

Maillard reactions are caramelisation reactions involving the removal of two hydrogen atoms from a sugar aldehyde or ketone. The resulting compounds are yellow/brown in colour because they contain carbon-carbon double bonds (C=C), which absorb violet and UV light (λmax ≈ 190 nm). The moon cake is usually also given an egg wash, which provides extra protein necessary for Maillard reactions to occur. More egg wash will provide a deeper brown colour to the dough.

Alkaline water (枧水) is a common ingredient in Guangdong-style cuisine. Chemically, it’s a ~0.020 molar solution of potassium carbonate and can be considered as the ‘opposite of vinegar’. It raises the pH in the moon cake, which accelerates the Maillard reaction, which is favoured by alkaline conditions. Alkaline water thus makes the crust more brown!

Finally, the fillings can be very diverse. Lotus seed with salted duck egg yolks is a common filling, but “five kernels”, red bean and green tea (with beans) are also quite popular. Lotus seed filling, for example, is made by soaking dried lotus seeds in alkaline water, pulverising and adding sugar. The resulting paste is then cooked with more oil and sugar before being used to fill a moon cake. ●

How do headphones work? New infographic: Chemistry of BEATS®

Chemistry of BEATS® Headphones jameskennedymonash.wordpress.com
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If you’ve ever tried Beats® headphones, you’ll have felt the rich, powerful baselines they give you without overwhelming the rest of the music. Beats® and its music streaming service, BeatsMusic, have become so popular so fast that they now recently acquired by Apple for a whopping $3 billion, making co-founder Dr Dre the most financially successful hip-hop artist of all time. By far.

Here’s how this best-selling product works. Each headphone contains a neodymium magnet (the strongest known permanent magnet). When an electrical signal from your iPod (or similar) passes through the gold-plated audio cable to the voice coil, electromagnetic induction gives the voice coil a variable magnetic field. The exact strength and timing of the variable magnetic field represent perfectly the music being played. The voice coil’s magnetic field then interacts with the magnetic field of the headphone’s neodymium magnet via magnetic attraction (or repulsion), which moves the diaphragm, which sits between the magnet and the ear. When the diaphragm moves, it creates differences in air pressure (sound waves) that are detected by the diaphragm in your ear.

Excellent sound quality requires an air-tight seal between the headphone’s diaphragm and the diaphragm in your ear. Overstuffed leather guarantees this air-tight fit. Leather requires over 20 treatment processes before it’s ready to use in manufacturing. One of those processes is dying using polyazo dyes. When used in lower concentrations, these dyes are brightly-coloured; when mixed together and used in very high concentrations, they give an overall ‘black’ appearance to the leather.

The Beats® headphone frame is made from strong anodised aluminium. Aluminium, a strong yet lightweight metal perfect for making wearable tech, is anodised to increase its ability to resist wear-and-tear. The aluminium headphone frame is dipped into an electrolytic solution with a ~20-volt direct current flowing through it. Bubbles of hydrogen form at the cathode, and bubbles of oxygen form on the surface of the headphone. This oxygen gas buildup quickly oxidises not only the surface of the headphone, but deep into pores in the surface, which give the frame very high resistance to corrosion. ●

Why are jeans blue? New Infographic: Chemistry of LEVI’S®

Chemistry of LEVI'S® chemistry infographic jameskennedymonash.wordpress.com
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Today’s graphic explores the chemistry of Levi’s® famous blue jeans. It’ll show you why they’re blue, and how the dye is made; why the blue colour survives so well in the wash; and what’s special about the denim cotton weave that makes your Levi’s® jeans so strong.

Indican is a colourless, water-soluble compound extracted from leaves of the Indigofera species. Indican is a dextrose molecule conjugated to an indoxyl group by a glycosidic ether (C–O–C) bond.

The indican is hydrolysed at high pH, which separates the dextrose from the indoxyl group. The resulting indoxyl compound is whisked to aerate it, which causes the indoxyl molecules to oxidise and dimerise into indigotin, which is the famous blue dye used in Levi’s® jeans.

However, the indigotin blue dye isn’t soluble in water, and must be changed chemically before the jeans are dyed. Indigotin is subjected to high pH again, which reduces the indigotin, forming leuco-indigotin (also known as indigo white dye), which is, despite the name, pale yellow in colour.

Jeans are steeped in this water-soluble “indigo white dye”, which is still pale yellow at this stage! However, as soon as the jeans are removed from the vat of dye, the leuco-indigotin oxidises back into indigotin, which is blue in colour. The oxidised form (indigo blue) is insoluble in water, which helps the colour stick to the jeans despite being washed hundreds of times.

Denim is a traditional way of weaving cotton into a thick, sturdy material. Cotton is predominantly cellulose, a strong polymer of beta-D-glucose monomer units. Several thousand glucose monomers are present in each polymer chain. Polar hydroxyl groups form hydrogen bonds with hydroxyl groups on adjacent chains to form strong microfibrils, which the cotton plant then meshes into a strong poly- saccharide matrix. This matrix, and the denim weave, give high strength and durability to your Levi’s® jeans. ●

Why is Coffee so Irresistable? The Chemistry of STARBUCKS®

Many people are openly addicted to coffee. In northern Europe, home of the world’s greatest coffee drinkers, annual coffee bean consumption hovers around 9 kg per capita, which equates to 400 mg of caffeine per person per day (this is a highly addictive, highly stimulating dose). In North America, coffee bean consumption is much lower at 4.2 kg per capita per year, which equates to 185 mg of caffeine per person per day. However, this is still a highly addictive dose.

Chemistry of STARBUCKS jameskennedymonash
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Caffeine (around 225 mg in the beverage shown above) causes short, sharp increases in your blood pressure. It makes you feel alert, but jittery in large doses. Caffeine stimulates nerves by counteracting adenosine, which is a nerve activity suppressant. The brain develops a tolerance to caffeine intake after a few weeks, which can cause some people to take increasingly large doses—sometimes exceeding the ~300 mg per day limit recommended by many doctors. That said, smaller doses are believed to provide some protection against Parkinson’s Disease in the long term.

Milk, a butterfat emulsion, gives the coffee its light colour and pleasant mouthfeel. Vanilla syrup adds an interesting flavour and aroma, and consists of glucose syrup and vanillin, an artificial flavour compound modelled on the main aroma compound in real vanilla beans.

The most amazing aspect of the product shown is the polypropylene cup. Starbucks® sells these reusable cups for just $1 in its United States stores, which is part of an attempt to serve 5% of all its beverages in reusable containers by 2015. In addition to giving you a 10-cent discount for bringing your own cup, and selling these reusable cups ridiculously cheaply, Starbucks® makes these cups from a fully recyclable plastic that’s completely inert at boiling-hot temperatures (100°C). This ensures that absolutely nothing from the cup leeches into your piping hot drink before you drink it. ●

How are Lego® bricks made? The Chemistry of LEGO®

I saw a Greenpeace advertisement recently that lambasted LEGO® for its ongoing toy deals with Shell Corporation. The advertisement was dark, sarcastic, and tasteless.

The video, made to highlight the Danish company’s $130-million relationship with Shell, has reappeared on YouTube after being withdrawn last week following copyright complaints from the toy-maker.

The video made me feel sorry for LEGO®. It also reminded me that LEGO® is made from oil-based products (even though they’re trying to find a sustainable alternative), and it inspired me to make this infographic: the Chemistry of everyone’s favourite building block.

Chemistry of LEGO jameskennedymonash
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LEGO® is made from ABS (acrylonitrile butadiene styrene), a thermoplastic polymer comprised of three monomers. The first monomer, acrylonitrile, gives the bricks strength. The second, 1,3-butadiene, gives them resilience (i.e. stops them from snapping so easily) and the third, styrene, gives them a shiny, hard surface. These three ingredients are mixed with colorants then polymerised (hardened) with the help of an initiator called potassium peroxydisulphate. LEGO® buys pre-made ABS granules and injects them into brick shapes on a massive scale.

LEGO® make 20 billion bricks each year (that’s 35,000 bricks a minute) and according to the Guinness Book of World Records, they produce more plastic tyres than anyone else. Personally, I think that’s a remarkable feat. It’s engineering genius.

In a statement, LEGO® said: “We firmly believe that this matter must be handled between Shell and Greenpeace. We are saddened when the LEGO brand is used as a tool in any dispute between organisations. We will continue to… deliver creative and inspiring LEGO play experiences to children all over the world.”

Why is Gold Yellow? The Chemistry of GOLD

Chemistry of GOLD jameskennedymonash v2
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Why is Gold yellow? Special relativity causes length contractions and time dilations in objects that travel at speeds approaching the speed of light. The valence electrons of large atoms such as gold have such high energies that their speeds actually approach the speed of light—and the relativistic effects on those electrons can become quite large.

Special relativity changes the energy levels of the 5d orbital in a gold atom so that the energy difference between 5d and 6s orbitals equals the energy of a ‘blue’ photon. Gold thus absorbs blue light when electrons are elevated from the 5d to the 6s orbitals, while other metals do not. These special relativistic changes to the energy levels of atomic orbitals are slightly different for each element.

Relativistic contractions on gold’s valence electrons (the 6s subshell) pull the 6s electron very close to the nucleus. Being closer to the nucleus makes the 6s electron less accessible to any potential reactants. Special relativity is not only the reason for gold’s yellow colour but also for its very low reactivity! ●

All-Natural Banana Has Gone Viral: 2M views

banana collage 2 million jameskennedymonash

This post is a shameless list of newspapers and famous blogs that published articles about the All-Natural Banana, which has now exceeded 2 million views on the internet.

It’s also spawned a successful clothing line and a poster print business. In other words, for what started as a simple teaching aid, “Ingredients” is getting pretty big. 🙂

Here’s the list:

I’m now sending multiple print shipments every day, most of them international.

It now exists in 7 languages. More on that soon.

It has over 120,000 ‘likes’ on Facebook (but I don’t use Facebook)

And it’s been shared widely across social media like Twitter. In other words, it’s gone viral.

Exciting changes to the T-Shirt Store will be announced tomorrow. 🙂 James

If Beetroots had Ingredients Labels…

It’s Australia Day and beetroot burgers are in ‘season’.

Chemically, beetroots are remarkably simple.

ingredients of an AUSTRALIAN BEETROOTThe colour in beetroots comes from just two E-numbers (which are each groups of about 10 compounds); and the flavour comes almost entirely from geosimin. So simple.

Happy Australia Day!

Ingredients of an All-Natural Kiwi

Welcome Kiwi to the all-natural gang.

Merchandise is in the T-Shirt Store.

Also, some exciting changes are coming to the T-Shirt Store very soon.

Ingredients of an All-Natural Kiwi POSTER
Click for large JPEG

Meet the Terpenes: A Visual Introduction from Isoprene to Latex

Inspiration for Meet the Terpenes came from the rhetological fallacies graphic over at Information is Beautiful, while motivation came from a 45°C heat wave this week that prevented any sensible Australians from going outside. So I stayed at home and did this.

Meet the Terpenes - A Visual Introduction from Isoprene to Latex
Click to download 200dpi JPEG (5.4Mb)

It took about three days to sketch, research and create.

Three days ago, I knew nothing about terpenes. My undergraduate phytochemistry class was really difficult. The teacher was a genius, and put huge amounts of effort into his tutorials, giving us thick booklets at each seminar filled with his hand-written notes and dozens of chemical structures. But for some reason, I just didn’t get it.

So this week, I decided to make the graphic I wish I’d had when I took the phytochemistry class many years ago. Having this poster on my wall would have answered all my questions and made the class much more enjoyable. I hope you find it useful, too.

As always, I welcome all feedback, corrections, suggestions and comments, etc.

Enjoy 🙂 James