Blue-footed Boobies
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Boobies are a small group of seabirds native to tropical and subtropical oceans throughout the world. Their diet consists mainly of fish. They are specialized fish eaters feeding on small school fish like sardines, anchovies, mackerel, and flying fish. When their prey is in sight, they fold their long wings back around their streamlined bodies and plunge into the water from as high as 80 feet, so streamlined they barely make a splash. They travel in parties of about 12 to areas of water with large schools of small fish. When the lead bird sees a fish shoal in the water, it will signal the rest of the group and they will all dive together. Surprisingly, individuals do not eat with the hunting group, preferring to eat on their own, usually in the early morning or late afternoon.
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There are three varieties on the Galapagos: the blue-footed, red-footed, and masked boobies. They are all members of the same family, and are not only different in appearance but also in behaviours. The blue-footed and red-footed boobies mate throughout the year, while the masked boobies have an annual mating cycle that differs from island to island. All catch fish in a similar manner, but in different areas: the blue-footed booby does its fishing close to shore, while the masked booby goes slightly farther out, and the red-footed booby fishes at the farthest distances from shore.
ix Origin of the booby's name
Although it is unknown where the name "Booby" emanates from, some conjecture it may come from the Spanish word for clown, "bobo", meaning "stupid". Its name was probably inspired by the bird's clumsiness on land and apparently unwarranted bravery. The blue footed booby is extremely vulnerable to human visitors because it does not appear to fear them. Therefore these birds received such name for their clumsiness on land in which they were easy, captured, killed, and eaten by humans.
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The blue-footed booby's characteristic feet play a significant part in their famous courtship ceremony, the 'booby dance'. The male walks around the female, raising his bright blue feet straight up in the air while bringing his 'shoulders' towards the ground and crossing the bottom tips of his wings high above the ground. Plus he'll raise his bill up towards the sky to try to win his mate over. The female may also partake in these activities – lifting her feet, sky pointing, and of course, squawking at her mate. After mating, another ritual occurs – the nest-building which ironically is never used because they nest on the bare ground. When the female is ready to lay her eggs, they scrape the existing nest away so she can nest on exposed ground. Sun-baked islands form the booby's breeding grounds. When ready the female Blue Footed Booby lays one to three eggs.
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After mating, two or three eggs are laid in a shallow depression on flat or gently sloping ground. Both male and female take turns incubating the eggs. Unlike most birds, booby doesn't develop brood patches (areas of bare skin on the breast) to warm the eggs during incubation. Instead, it uses its broad webbed feet, which have large numbers of prominent blood vessels, to transmit heat essential for incubation. The eggs are thick-shelled so they can withstand the full weight of an incubating bird.
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After hatching, the male plays a major role in bringing fish home. He can bring back a constant supply of small fish for the chicks, which must be fed continuously. The reason is that the male has a longer tail than the female in relation to his body size, which makes him able to execute shallower dives and to feed closer to shore. Then the female takes a greater part as time proceeds. Sooner or later, the need to feed the young becomes greater than the need to protect them and both adults must fish to provide enough.
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When times are good, the parents may successfully fledge all three chicks, but, in harder times, they may still lay as many eggs yet only obtain enough food to raise one. The problem is usually solved by the somewhat callous-sounding system of "opportunistic sibling murder." The first-born chick is larger and stronger than its nest mate(s) as a result of hatching a few days earlier and also because the parents feed the larger chick. If food is scarce, the first born will get more food than its nest mate(s) and will outcompete them, causing them to starve. The above system optimizes the reproductive capacity of the blue-foot in an unpredictable environment. The system ensures that, if possible, at least one chick will survive a period of shortage rather than all three dying of starvation under a more 'humane' system.
Hunting Perfume in Madagascar!
A Ever since the unguentari plied their trade in ancient Rome, perfumers have to keep abreast of changing fashions. These days they have several thousand ingredients to choose from when creating new scents, but there is always demand for new combinations. The bigger the 'palette' of smells, the better the perfumer's chance of creating something fresh and appealing. Even with everyday products such as shampoo and soap, kitchen cleaners and washing powders, consumers are becoming increasingly fussy. And many of today's fragrances have to survive tougher treatment than ever before, resisting the destructive power of bleach or a high temperature wash cycle. Chemists can create new smells from synthetic molecules, and a growing number of the odours on the perfumer's palette are artificial. But nature has been in the business far longer.
B The island of Madagascar is an evolutionary hot spot; 85% of its plants are unique, making it an ideal source for novel fragrances. Last October, Quest International, a company that develops fragrances for everything from the most delicate perfumes to cleaning products, sent an expedition to Madagascar in pursuit of some of nature's most novel fragrances. With some simple technology, borrowed from the pollution monitoring industry, and a fair amount of ingenuity, the perfume hunters bagged 20 promising new aromas in the Madagascan rainforest. Each day the team set out from their "hotel"-a wooden hut lit by kerosene lamps, and trailed up and down paths and animal tracks, exploring the thick vegetation up to 10 meters on either side of the trail. Some smells came from obvious places, often big showy flowers within easy reach. Others were harder to pin down. "Often it was the very small flowers that were much more interesting," says Clery. After the luxuriance of the rainforest, the little-known island of Nosy Hara was a stark, dry place-geologically and biologically very different from the mainland. "Apart from two beaches, the rest of the island is impenetrable, except by hacking through the bush," says Clery. One of the biggest prizes here was a sweet-smelling sap weeping from the gnarled branches of some ancient shrubby trees in the parched interior. So far no one has been able to identify the plant.
C With most flowers or fruits, the hunters used a technique originally designed to trap and identify air pollutants. The technique itself is relatively simple. A glass bell jar or flask is fitted over the flower. The fragrance molecules are trapped in this 'headspace' and can be extracted by pumping the air out over a series of filters which absorb different types of volatile molecules. Back home in the laboratory, the molecules are flushed out of the filters and injected into a gas chromatograph for analysis. If it is impossible to attach the headspace gear, hunters fix an absorbent probe close to the source of the smell. The probe looks something like a hypodermic syringe, except that the 'needle' is made of silicone rubber which soaks up molecules from the air. After a few hours, the hunters retract the rubber needle and seal the tube, keeping the odour molecules inside until they can be injected into the gas chromatograph in the laboratory.
D Some of the most promising fragrances were those given off by resins that oozed from the bark of trees. Resins are the source of many traditional perfumes, including frankincense and myrrh. The most exciting resin came from a Calophyllum tree, which produces a strongly scented medicinal oil. The sap of this Calophyllum smelt rich and aromatic, a little like church incense. But it also smelt of something like fragrance industry has learnt to live without, castoreum, a substance extracted from the musk glands of beavers and once a key ingredient in many perfumes. The company does not use animal products any longer, but it was wonderful to find a tree with an animal smell.
E The group also set out from the island to capture the smell of coral reefs. Odors that conjure up sun kissed seas are highly sought after by the perfume industry. " From the ocean, the only thing we have is seaweed, and that has a dark and heavy aroma. We hope to find something unique among the corals," says Dir. The challenge for the hunters was to extract a smell from water rather than air. This was an opportunity to try Clery's new "aquaspace" apparatus – a set of filters that work underwater. On Nosy Hara, jars were fixed over knobs of coral about 2 meters down and water pumped out over the absorbent filters. So what does coral smell like? "It's a bit like lobster and crab," says Clery. The team's task now is to recreate the best of their captured smells. First they must identify the molecules that make up each fragrance. Some ingredients may be quite common chemicals. But some may be completely novel, or they may be too complex or expensive to make in the lab. The challenge then is to conjure up the fragrances with more readily available materials. "We can avoid the need to import plants from the rainforest by creating the smell with a different set of chemicals from those in the original material," says Clery. "If we get it right, you can sniff the sample and it will transport you straight back to the moment you smelt it in the rainforest."
Using Mathematics to Secure Our Money
iii A brief history of keeping things safe
A Up until very recently people's wealth, mostly coins and jewels, was kept safe under lock and key. Rich medieval families would keep a strongbox with a large key, both of which were carefully hidden in different places. later the box may have been kept in a bank. In either case, potential thieves would need to find both the box and the key. A similar principle was used for sending secret diplomatic and military messages. The messages were written in code with both the sender and the receiver having the key to the code. Thus, while the message could be discovered its meaning could only be found if the 'key' was also known. And so began a long-running battle between code-makers who tried to make better keys and code-breakers who sought ways of finding them.
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B Nowadays, cryptography is central to how our money is kept secure, even though we may not be aware of it. Our money is no longer in a tangible form, but in the form of information kept with our banks. To keep everyone involved happy, the messages initiated by our plastic cards have to be sent and received safely and the entire operation must be carried out with a high level of confidentiality and security.
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C On a practical level, it is clear that the work of code-makers has been introduced into our daily financial lives. Our credit cards have 16-digit numbers on the front and a 3-digit number on the back. They also contain a 'chip' that can do all sorts of mysterious operations with these numbers. Finally, we also have a Personal Identification Number which we all need to memorize. All these numbers form a type of cryptographic key. However, as we shall see, modern cryptosystems are very different in the way the keys are used.
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D The main feature of the traditional systems was that only one key was needed by both the sender and the receiver to understand the message. However, the main problem was that the key itself needed to be communicated to both parties before they could use it. Obviously a major security risk. A very different approach was developed in the 1970s, based on a different way of using the keys. Now the main idea is that the typical user, let us call him Amir, has two keys; a 'public key' and a 'private key'. The public key is used to encrypt messages that other people wish to send to Amir, and the private key is used by Amir to decrypt these messages. The security of the system is based on keeping Amir's private key secret.
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E This system of public-key cryptography, known as RSA- from the names of the developers (Ronald Rivest, Adi Shamir and Leonard Adleman) – was developed in the late 1970s and is based on a collection of several mathematical algorithms. The first is a process that allows the user, Amir, to calculate two numerical keys: private and public, based on two prime numbers. To complete the RSA system, two more algorithms are then needed: one for encrypting messages and one for decrypting them.
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F The effectiveness of RSA depends on two things. It is efficient, because the encryption and decryption algorithms used by participants are easy, in a technical sense they can be made precise. On the other hand, it is believed to be secure, because no one has found an easy way of decrypting the encrypted message without knowing Amir's private key.
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G When the RSA system was first written about in Scientific American, the strength of the system was shown by challenging the readers to find the prime factors – the two original numbers – of a certain number with 129 digits. It took 17 years to solve this problem, using the combined efforts of over 600 people. So clearly it is a very secure system. Using mathematics in this way, scientists and technologists have enabled us to keep our money as secure as the rich medieval barons with their strong boxes and hidden keys.
