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Friday, July 1, 2011

Cleaning Up with Small-Scale Sanitation


One of the most repulsive moments in cinematic history is the outhouse scene in the Oscar-winning films SlumdogMillionaireThe hero, Jamal, is trapped in an outhouse when his favorite celebrity lands nearby in a helicopter. The only way to see his hero is to jump into the excrement. Happily, he gets to see the star and get an autographed photo: nothing parts a crowd like a filth-covered child.


 

Perhaps the director included the scene for shock value. But it also highlights a health issue that is reality for 2.6 billion people: a lack of safe sanitation. Of this group, 1.4 billion defecate in the open. The implications reach far beyond offended noses and human dignity. Over 5,000 children die every day from diseases related to human waste, particularly diarrhea, which kills more children than malaria, AIDS and tuberculosis combined.

So what’s being done to address this? Traditionally, the development community has tackled sanitation issues through infrastructure projects, working directly with governments. But this often isn’t enough. Often, the problems exist in slums, some of which are technically illegal settlements. Building infrastructure is such places become a political issue.

But a new trend is emerging. Managing human waste provides opportunities for businesses, all the way down to the micro level. Even the outhouse in Slumdog Millionaire is a fee-based service (Jamal and his brother charge for it). But there are also opportunities in the manufacture of latrines, waste collection, and pit cleaning. This doesn’t just reduce the waste problem, it also provide income opportunities, and treats the poor as paying customers for a much-needed (and appreciated) service.

One example is the service of emptying latrine pits. When these pits fill up, people often have to defecate in the open. But with the right equipment, such as theNibbler or theGulper, latrine pits can quickly be emptied. The small businesses that provide the service then take the waste to a sewage treatment plant, or at least dispose of it in a safe place.

The Bank’s WaterandSanitationProgram (WSP) has taken this idea further by testingsanitationmarketingapproaches tocreatedemand and support thesupplyofaffordableproducts that are valuable to poor households as a way to rapidly reach this lower tier of the market.

Perhaps not every sanitation entrepreneur will end up as a millionaire, like Jamal in the film. But hopefully, more and more people will earn an income providing small-scale sanitation services, and reducing health risks at the same time.

Shaoxing, China: Keeping History Alive and People in Place





Rehabilitating and restoring old neighborhoods is the goal of the Zhejiang Urban Environment Project in Shaoxing, China. The project aims to preserve these modest Ming and Qing Dynasty buildings for their low-income and aging occupants.
STORY HIGHLIGHTS
  • An urban environmental management project in the historic city of Shaoxing shows that heritage conservation can be integrated into urban renewal.
  • Historic neighborhoods can be upgraded while keeping communities in place and retaining unique characteristics.
  • What has been achieved in Shaoxing can be a model for other historic cities in China and around the world.

Shaoxing, CHINA, May 31, 2011 – 
The city of Shaoxing in Zhejiang Province is 2,500 years old and has played a key role as a political, economic, and cultural center throughout the centuries. However, the city has gradually been losing its historic attributes and the potential to generate social and economic benefits from these assets. 
Jin Caijuan lives next to an ancient canal in one of the city’s five remaining traditional neighborhoods that offer a waterside lifestyle. But for years, Jin and her neighbors have been paying the price of living in an ancient urban area: lack of sanitation facilities, deteriorating public services, and poor environmental conditions. 
The World Bank-supported Zhejiang Urban Environment Project began addressing these issues in 2004. Jin’s house, which was built during the Ming Dynasty (1368 to 1644 A.D.), has benefited from a residential upgrading program that repaired windows, doors, and roofs. The project also connected each house to sewer pipes and upgraded electrical and telecommunication lines. Twenty kilometers of the city’s canals also were refurbished to increase the water flow and quality.
Jin is one of about 26,000 people living in Shaoxing’s inner city neighborhoods who have benefited from this project. “Life is getting better year by year,” she says. “The house itself has been restored and the surrounding environment has been improved a lot.”
Integrating Conservation into Development
The Zhejiang Urban Environment Project is intended to strengthen the collection and treatment of wastewater and improve urban infrastructure services, including the rehabilitation of inner waterways, lakes, and roads in Shaoxing.
For Shaoxing, which is one of China’s best known historical and cultural cities, “the project integrated cultural heritage conservation into urban development,” says Axel Baeumler, a Senior Infrastructure Economist at the World Bank who leads the project. “This is a very innovative concept for urban development in China, challenging the conventional thinking that new development means demolishing the old.”
In Shaoxing, the project focuses on conserving cultural heritage sites, repairing housing, and maintaining the characteristics of the old town, as well as improving basic infrastructure and residents’ standard of living.
For 74-year-old Chen Mingzhao, who has lived in the old town all his life, the project has meant “drastic changes.” “From my old house, now I can browse news on the websites of foreign countries and chat with relatives living far from here,” he says. “Also, after the rebuilding of the main street, there are more shops and more businesses, more tourists and more income.”
Boosting Tourism
Each year, Shaoxing’s rich cultural heritage attracts millions of visitors. Over 10 percent of the residents in the old town earn their living from tourism, including making souvenirs, providing food and hotel services, and acting as guides. Consequently, the World Bank supported the development of a sustainable tourism project, which has financed construction of a new state-of-the-art municipal museum to house Shaoxing’s world-class collection of artifacts.
Chen Jing, who sells traditionally made yellow rice wine in the old town, says her business has grown rapidly since the upgrading and conservation work. “The street will be even more attractive when there are more businesses selling traditional Chinese products here,” she says.
Since the early 1990s, the Bank has developed 12 projects in China supporting cultural heritage conservation through more than US$1.3 billion in financing that includes about US$260 million specifically for cultural heritage conservation. These figures make it the largest single-country program supporting cultural heritage conservation at the World Bank.
Creating a Model
Shaoxing is one of more than 100 Historical Cities designated by China’s State Council. “What has been achieved in Shaoxing could be a model for other cities. We have improved the livelihoods of the local residents, while keeping history alive.” says Li Bo, director of Shaoxing’s Historical Cultural City Management Office.
“The most important thing to come from the project is a raised awareness in Shaoxing of the importance of cultural heritage conservation and the value of a long-term strategy,” says Xuan Chuanzhong, head of the Cultural Relics Bureau and Tourism Commission of Shaoxing. “In Shaoxing this has meant preserving the urban fabric of whole traditional neighborhoods, rather than just one major historic building in an area.”
“I like living in the old town, it is much nicer than living in the modern part of the city. Life is easy, and it is nice and green here,” says Jin Caijuan
.

The Secret of Tibetan Singing Bowls

The Secret of Tibetan Singing Bowls

Credit: Denis Terwagne
Credit: Institute of Physics
Buddhists have used the lulling hum of Tibetan singing bowls for thousands of years to begin and end their meditations. Today, physicists are using these same bowls to better understand fluid dynamics. The bronze alloy bowls are standing bells that resonate when struck or rubbed (right). When filled with water, the liquid dances to the vibrations. In a paper published today inNonlinearity, researchers examined these hydroacoustic properties in four 5th-century singing bowls from the Himalayas. They rigged a speaker to play tones resonant with each individual bowl and then watched how the water responded at different amplitudes. As the amplitude increased, waves formed on the surface, eventually grew chaotic, then crashed into one another, shooting up droplets (top). At certain frequencies and amplitudes, these droplets appear to float and wander across the surface. Though scientists have extensively studied similar dynamics in wine glasses, this is the first study to do so in singing bowls.

Genetic detectives: tracking the real culprits the German E. coli outbreak


Genetic detectives: tracking the real culprits the German E. coli outbreak
KATHRYN HOLT, THE CONVERSATION   

The genomes of the recent German E. coli outbreak have revealed crucial insights into the origins of this deadly strain. The bacteria was found in German bean sprouts but it didn’t originate from the gut of an animal, as first suspected – it came from humans.
Humans are engaged in a never-ending conflict with bacteria, viruses and other microbes that make us ill. New genes such as toxins can make a bacteria more virulent and cause more serious illness, like we saw in the German outbreak.
Our weapons against these microbes include drugs, vaccines, sanitation and hygiene. But the ability to share genetic information is the number one weapon in the bacterial arsenal.
Understanding bacteria through their DNA

We often hear about human genetics and the human genome project, but bacterial genomics – the study of bacteria through their complete DNA sequence – has been around for a lot longer.

Bacterial genome sequencing gives us a complete picture of all the genes the bacterium has at its disposal, which can have a significant impact on human health.

It helps us to track the bacteria’s movements and to identify its weaknesses, allowing us to design new drugs and vaccines.

Much like DNA fingerprinting of humans links individuals to a crime scene, we can use DNA fingerprinting of bacteria to link potential sources of bacteria to specific infections and outbreaks.

By identifying the genes encoded in a particular bacterium’s DNA, we can predict how dangerous it is to human health, how it might spread and what drugs it is likely to be resistant to.

Since bacteria share DNA so readily, we can also examine where the various bits of DNA have come from, which can give us clues about where the bacterium originated.
Information-sharing in the German E. coli investigation
The ongoing German E. coli outbreak is the first time the technology has been available to study the cause of a foodborne outbreak at the whole genome level.
Rather than having multiple scientists working in silos to come up with their own analysis, experts around the globe shared their data online.
On June 2, BGI (formerly Beijing Genome Institute) in China released the first genome sequence data from a strain associated with the German outbreak.
Within days, genome data from two additional strains was released, and as of June 23 there arenine genomes available.
All of this data was released to the public and deposited in publicly accessible databases, prompting a flurry of analysis by bacterial genomicists all over the world.
Within hours, scientists began posting analysis of the outbreak genomes, providing novel insights into the genome of the outbreak strain.
These analysts include many who, like myself, don’t work for any agency with responsibility for outbreak control. This public sharing of results and analyses is called “crowd-sourcing”.
In the German E. Coli outbreak, crowd-sourcing allowed scientists to identify the source of the toxins and the antibiotic resistant genes that are problematic for human health.
Lessons from the outbreak
The key puzzle in the German E. coli outbreak strain was its unusual combination of genes.
It carried genes to encode Shiga-toxin, which makes it much nastier than a regular diarrhoeal infection. But it didn’t carry other genes typically associated with the symptoms it was causing (genes from enterohaemorrhagic E. coli, or EHEC).
Instead, it carried some genes from enteroagreggative E. coli, or EAEC, which usually causes short bouts of diarrhoea in children.
These genes are associated with “aggregative adhesion”, which makes the bacterium able to stick easily to human and other cells.
But it was unclear whether the outbreak strain was an EHEC that had picked up some aggregative adhesion genes, or an EAEC which had picked up some EHEC genes.
It was even suggested that this was a completely new bacterium, unlike anything seen before.
The crowd-sourced, publicly available analysis of the outbreak strain’s DNA showed it was in fact an enteroagreggative E. coli (EAEC), which had acquired the Shiga-toxin via a phage(viruses that can integrate their own DNA and toxins into the bacterial genome).
In fact it is nearly identical to the genome of an E. coli isolated from a child with diarrhoea a decade ago, except that the new outbreak strain has acquired the toxin. And worryingly, it can resist whole swathes of antibiotics.
While EHEC is common in animals (with outbreaks often traced back to cows), EAEC has only ever been found in humans. This outbreak has been linked to contamination of the food chain with human feces rather than cow feces. So hygiene, rather than agricultural practice, is the likely culprit.
But how the sprouts became contaminated is still a mystery. Several of the farm’s workers were sick with the outbreak strain, but it’s difficult to tell whether they became infected at work or if one of them could be the initial source of the contamination.
The way forward
Crowd-sourcing analysis holds great promise for the future understanding of infectious diseases and outbreak investigation.
It’s interesting that while holes have been identified in the sharing of outbreak information across agencies – even within the European Union – the sharing of DNA sequence data was able to happen so rapidly and openly.
But this kind of open analysis raises other issues around ownership of sequence data, and in particular, around authorship of research articles based on the analysis.
The data issues have been clarified by BGI which has released its data under a “Creative Commons 0” license, enabling completely free use and distribution without attribution.
But the open publication of analysis via blogs and wikis may affect the ability of scientists to publish their more complete analyses later in peer-reviewed scientific journals.
If we are to win the war against infectious disease outbreaks, the genomics and public health communities still have some lessons to learn from the bugs about the free flow of information.

DR SABESAN Tamil young scientist



பொருட்களின் இருப்பிடத்தை அறிவதற்கான மிகவும் மலிவான புதிய மின்னணு பொறிமுறை ஒன்றை தமிழ் விஞ்ஞானி ஒருவர் பிரிட்டனில் கண்டுபிடித்திருக்கிறார்.
பிரிட்டனின் கேம்பிரிஜ் பல்கலைக்கழகத்தின் ஆய்வு மாணவரான டாக்டர். சிதம்பரநாதன் சபேசன் அவர்களே இந்தக் கண்டுபிடிப்பை செய்திருக்கிறார்

Human Ancestor Older Than Previously Thought; Finding Offers New Insights Into Evolution


Generalized composite sedimentary geology of the Ngandong and Jigar “20 meter terrace" denoting stratigraphic positions of Homo erectus fossil material and dated pumices. (Credit: Etty Indriati, Carl C. Swisher, Christopher Lepre, Rhonda L. Quinn, Rusyad A. Suriyanto, Agus T. Hascaryo, Rainer Grün, Craig S. Feibel, Briana L. Pobiner, Maxime Aubert, Wendy Lees, Susan C. Antón. The Age of the 20 Meter Solo River Terrace, Java, Indonesia and the Survival of Homo erectus in Asia. PLoS ONE, 2011; 6 (6): e21562 DOI: 10.1371/journal.pone.0021562)
The work was conducted by the Solo River Terrace (SoRT) Project, an international group of scientists directed by anthropologists Etty Indriati of Gadjah Mada University in Indonesia and Susan Antón of New York University.
Science Daily  — Modern humans never co-existed with Homo erectus -- a finding counter to previous hypotheses of human evolution -- new excavations in Indonesia and dating analyses show. The research, reported in the journal PLoS ONE, offers new insights into the nature of human evolution, suggesting a different role for Homo erectus than had been previously thought.
Homo erectus is widely considered a direct human ancestor -- it resembles modern humans in many respects, except for its smaller brain and differently shaped skull -- and was the first of our ancestors to migrate out of Africa, approximately 1.8 million years ago. Homo erectus went extinct in Africa and much of Asia by about 500,000 years ago, but appeared to have survived in Indonesia until about 35,000 to 50,000 years ago at the site of Ngandong on the Solo River. These late members of Homo erectus would have shared the environment with early members of our own species, Homo sapiens, who arrived in Indonesia by about 40,000 years ago.
The existence of the two species simultaneously has important implications for models about the origins of modern humans. One of the models, the Out of Africa or replacement model, predicts such overlap. However, another, the multiregional model, which posits that modern humans originated as a result of genetic contributions from hominin populations all around the Old World (Africa, Asia, Europe), does not. The late survival of Homo erectus in Indonesia has been used as one line of support for the Out of Africa model.
However, findings by the SoRT Project show that Homo erectus' time in the region ended before modern humans arrived there. The analyses suggest that Homo erectus was gone by at least 143,000 years ago -- and likely by more than 550,000 years ago. This means the demise of Homo erectus occurred long before the arrival of Homo sapiens.
"Thus, Homo erectus probably did not share habitats with modern humans," said Indriati.
The SoRT Project's investigations occurred in Ngandong and Jigar, two sites in the "20-meter terrace" of the Solo River, Indonesia. The sediments in the terrace were formed by the flooding of the ancient river, but currently sit above the Solo River because the river has cut downward through time. The terrace has been a rich source for the discovery of Homo erectus and other animal fossils since the 1930s.
As recently as 1996, a research team dated these sites of hominin, or early human, fossils to as young as 35,000-50,000 years old. The analyses used a technique that dates teeth, and thus provided ages for several animals discovered at the sites. However, other scholars suggested the sites included a mixture of older hominins and younger animals, raising questions about the true age of the hominin remains.
The goal of the SoRT team, which included both members of the 1996 group and its critics, was to understand how the sites in the terrace formed, whether there was evidence for mixing of older and younger remains, and just how old the sites were.
Since 2004, team members have conducted analyses of animal remains, geological surveys, trenching, and archaeological excavations. The results from all of these provide no evidence for the mixing of older and younger remains. All the evidence suggests the sites represent just a short time period.
"The postmortem damage to the animal remains is consistent and suggests very little movement of the remains by water," explained Briana Pobiner, the project's archaeologist and a paleoanthropologist at the Smithsonian Institution's National Museum of Natural History. "This means that it is unlikely that very old remains were mixed into younger ones."
In addition, clues from the sediments exposed during excavation suggest to the projects' geoarchaeologists, Rhonda Quinn, Chris Lepre, and Craig Feibel, of Seton Hall, Columbia, and Rutgers universities, that the deposits occurred over a short time period. The teeth found in different excavation layers at Jigar are also all nearly identical in age, supporting the conclusion that mixing across geological periods did not occur.
"Whatever the geological age of the sites is, the hominins, animals, and sediments at Ngandong and Jigar are all the same age," said project co-leader Susan Antón.
The team applied two different dating techniques to the sites. Like earlier work, they used the techniques -- U-series and Electron Spin Resonance, or ESR -- that are applied to fossilized teeth. They also used a technique called argon-argon dating that is applied to volcanic minerals in the sediments. All three methods use radioactive decay in different ways to assess age and all yielded robust and methodologically valid results, but the ages were inconsistent with one another.
The argon-argon results yielded highly precise ages of about 550,000 years old on pumices -- very light, porous volcanic products found at Ngandong and Jigar.
"Pumices are hard to rework without breaking them, and these ages are quite good, so this suggests that the hominins and fauna are this old as well," said project geochronologist Carl Swisher of Rutgers University.
By contrast, the oldest of the U-series and ESR ages, which were conducted at Australian National University by Rainer Grün, are just 143,000 years.
The difference in the ages means that one of the systems is providing an age for something other than the formation of the sites and fossils in them. One possibility is that the pumices are, in fact, reworked, or mixed in, from older rocks. The other possibility is that the ESR and U-series ages are dating an event that occurred after the sites were formed, perhaps a change in the way groundwater moved through the sites.
Either way, the ages provide a maximum and a minimum for the sites -- and both of these ages are older than the earliest Homo sapiens fossils in Indonesia. Thus, the authors concluded that the idea of a population of Homo erectus surviving until late in time in Indonesia and potentially interacting with Homo sapiens seems to have been disproven.
The study's other co-authors included: Rusyad Suriyanto and Agus Hascaryo of Indonesia's Gadjah Mada University and Wendy Lees and Maxime Aubert of the Australian National University.
The National Science Foundation sponsored field and laboratory work by the Solo River Terrace Project

'Zombie' Stars Key to Measuring Dark Energy


This is a Chandra X-ray image of Tycho's supernova remnant. This Type Ia sueprnova was observed by Tycho Brahe in 1572, and today is just an expanding ball of gas. Astronomers used to have to wait years for a close, bright supernova to learn about them. Today big surveys are discovering supernovae by the thousands. (Credit: NASA/Chandra X-ray Observatory)


Science Daily  — "Zombie" stars that explode like bombs as they die, only to revive by sucking matter out of other stars. According to an astrophysicist at UC Santa Barbara, this isn't the plot for the latest 3D blockbuster movie. Instead, it's something that happens every day in the universe -- something that can be used to measure dark energy.

This special category of stars, known as Type Ia supernovae, help to probe the mystery of dark energy, which scientists believe is related to the expansion of the universe.
Andy Howell, adjunct professor of physics at UCSB and staff scientist at Las Cumbres Observatory Global Telescope (LCOGT), wrote a review article about this topic, published recently in Nature Communications. LCOGT, a privately funded global network of telescopes, works closely with UCSB.
Supernovae are stars that have been observed since 1054 A.D., when an exploding star formed the crab nebula, a supernova remnant.
More recently, the discovery of dark energy is one of the most profound findings of the last half-century, according to Howell. Invisible dark energy makes up about three-fourths of the universe. "We only discovered this about 20 years ago by using Type Ia supernovae, thermonuclear supernovae, as standard or 'calibrated' candles," said Howell. "These stars are tools for measuring dark energy. They're all about the same brightness, so we can use them to figure out distances in the universe."
These supernovae are so bright that they shine with the approximate power of a billion suns, noted Howell.
He calls Type Ia supernovae "zombie" stars because they're dead, with a core of ash, but they come back to life by sucking matter from a companion star. Over the past 50 years, astrophysicists have discovered that Type Ia supernovae are part of binary systems -- two stars orbiting each other. The one that explodes is a white dwarf star. "That's what our sun will be at the end of its life," he said. "It will have the mass of the sun crammed into the size of the Earth."
The white dwarf stars that tend to explode as Type Ia supernovae have approximately the same mass. This was considered a fundamental limit of physics, according to Howell. However, in an article in Nature about five years ago, Howell reported his discovery of stars that go beyond this limit. These previously unknown Type Ia supernovae have more than typical mass before they explode -- a fact that confounds scientists.
Howell presented a hypothesis to understand this new class of objects. "One idea is that two white dwarfs could have merged together; the binary system could be two white dwarf stars," he said. "Then, over time, they spiral into each other and merge. When they merge, they blow up. This may be one way to explain what is going on."
Astrophysicists are using Type Ia supernovae to build a map of the history of the universe's expansion. "What we've found is that the universe hasn't been expanding at the same rate," said Howell. "And it hasn't been slowing down as everyone thought it would be, due to gravity. Instead, it has been speeding up. There's a force that counteracts gravity and we don't know what it is. We call it dark energy."
The new findings relate to Einstein's concept of the cosmological constant. This is a term he added into his equations to make them valid. However, Einstein did it because he thought the universe was static; he didn't know the universe was expanding. When it was revealed that the universe is expanding, Einstein believed this concept was his biggest blunder. "It turns out that this cosmological constant was actually one of his greatest successes," said Howell. "This is because it's what we need now to explain the data."
He said that dark energy is probably a property of space. "Space itself has some energy associated with it," said Howell. "That's what the results seem to indicate, that dark energy is distributed everywhere in space. It looks like it's a property of the vacuum, but we're not completely sure. We're trying to figure out how sure are we of that -- and if we can improve Type Ia supernovae as standard candles we can make our measurements better."
Throughout history, people have noticed a few supernovae so bright they could be seen with the naked eye. With telescopes, astronomers have discovered supernovae farther away. "Now we have huge digital cameras on our telescopes, and really big telescopes," said Howell, "We've been able to survey large parts of the sky, regularly. We find supernovae daily." Astronomers have discovered thousands of supernovae in recent years.
During his career, Howell has used these powerful telescopes to study supernovae. Currently, besides teaching at UCSB, he is involved in LCOGT's detailed study of supernovae that is aimed at helping to understand dark energy. With this extensive network of observatories, it will be possible to study the night sky continuously.
"The next decade holds real promise of making serious progress in the understanding of nearly every aspect of supernovae Ia, from their explosion physics, to their progenitors, to their use as standard candles," writes Howell in Nature Communications. "And with this knowledge may come the key to unlocking the darkest secrets of dark energy.

New Fossils Demonstrate That Powerful Eyes Evolved in a Twinkling


A half-billion-year-old fossil compound eye, showing exquisite detail of the visual surface (the individual lenses can be seen as darker spots). (Credit: Photo by John Paterson (University of New England).)

Science Daily — Palaeontologists have uncovered half-a-billion-year-old fossils demonstrating that primitive animals had excellent vision. An international team led by scientists from the South Australian Museum and the University of Adelaide found the exquisite fossils, which look like squashed eyes from a recently swatted fly.

This discovery will be published on June 30, 2011) in the journal Nature. The lead author is Associate Professor Michael Lee from the South Australian Museum and the University of Adelaide's School of Earth & Environmental Sciences.
Compound Eyes
Modern insects and crustaceans have "compound eyes" consisting of hundreds or even thousands of separate lenses. They see their world as pixels -- each lens produces a pixel of vision. More lenses mean more pixels and better visual resolution. (Each lens does not form a miniature image -- a myth often perpetuated by Hollywood.)
Evolutionary Advantage
The fossil compound eyes were found on Kangaroo Island, South Australia and are 515 million years old. They have over 3000 lenses, making them more powerful than anything from that era, and probably belonged to an active predator that was capable of seeing in dim light.
Their discovery reveals that some of the earliest animals possessed very powerful vision; similar eyes are found in many living insects, such as robber flies. Sharp vision must therefore have evolved very rapidly, soon after the first predators appeared during the 'Cambrian Explosion' of life that began around 540 million years ago.
Given the tremendous adaptive advantage conferred by sharp vision for avoiding predators and locating food and shelter, there must have been tremendous evolutionary pressure to elaborate and refine visual organs.
Who owned them?
As the fossil eyes were found isolated, it's not certain what animal they came from, but they probably belonged to a large shrimp-like creature. The rocks containing the eyes also preserve a dazzling array of ancient marine creatures, many new to science. They include primitive trilobite-like creatures, armored worms, and large swimming predators with jointed feeding appendages.
More pixels: more chance of survival
The recently discovered fossil eyes would have seen the world with over 3000 pixels, giving its owner a huge visual advantage over its contemporaries, which would have seen a very blurry world with about 100 pixels. This is much better than the living horseshoe crab, which sees the world as 1000 pixels, but not as good as living dragonflies, which have the best compound eyes and see the world as ~28 000 pixels

Evidence Of Iridescence In 40 Million-Year-Old Feather Fossil


Scientists discovered that nanostructures found in this 40-million-year-old fossil were responsible for producing iridescent colors in the living feather. (Credit: Jakob Vinther/Yale University)
Science Daily  — Known for their wide variety of vibrant plumage, birds have evolved various chemical and physical mechanisms to produce these beautiful colors over millions of years. A team of paleontologists and ornithologists led by Yale University has now discovered evidence of vivid iridescent colors in feather fossils more than 40 million years old.

The finding, published online August 26 in Biology Letters, signifies the first evidence of a preserved color-producing nanostructure in a fossilized feather.
Iridescence is the quality of changing color depending on the angle of observation, such as the rainbow of colors seen in an oil slick. The simplest iridescent feather colors are produced by light scattering off the feather's surface and a smooth surface of melanin pigment granules within the feather protein. Examining feather fossils from the Messel Shale in Germany with an electron microscope, scientists have documented this smooth layer of melanin structures, called melanosomes.
"These feathers produced a black background with a metallic greenish, bluish or coppery color at certain angles—much like the colors we see in starlings and grackles today," said Richard Prum, chair of the Department of Ecology & Evolutionary Biology at Yale and one of the paper's authors.
For more than 25 years, paleontologists have found microscopic tubular structures on fossilized feathers and hair. These were long interpreted as bacteria that had digested the feathers at the time they were fossilized. The team had previously discovered that these structures were in fact not bacteria but melanosomes, which then allowed them to document the original color patterns. Following up on the new finding, they are racing to discover what additional coloration features may be found in fossil feathers.
"The discovery of ultra-structural detail in feather fossils opens up remarkable possibilities for the investigation of other features in soft-bodied fossils, like fur and even internal organs," said Derek Briggs, Yale's Frederick William Beinecke Professor of Geology and Geophysics, and an author of the study.
The discovery could pave the way for determining color features of other ancient birds and even dinosaurs, the team said.
"Of course, the 'Holy Grail' in this program is reconstructing the colors of the feathered dinosaurs," said Yale graduate student and lead author Jakob Vinther. "We are working hard to determine if this will be possible."
Other authors of the paper include Julia Clarke (University of Texas at Austin) and Gerald Mayr (Senckenberg Research Institute, Germany).
Funding was provided by the National Science Foundation, the National Geographic Society and Yale University

Secrets of Birds' Sexual Signals Revealed



Zebra Finch. (Credit: Image by Thanh-Lan Gluckman)

Science Daily  — Patterned feathers, previously thought to be used only for camouflage in birds, can play an important role in attracting a mate and fending off rivals, a University of Melbourne study reveals.

Thanh-Lan Gluckman, co-author of the paper and Masters of Philosophy student from the Department of Zoology at the University of Melbourne, said this finding brought a new perspective to research in animal communication and evolution.
"The implication of this study is that feathers don't need to be bright and showy to be used in sexual signalling and hence this changes our understanding of animal communication," she said.
Hundreds of bird species such as Zebra Finches and Cuckoos have "barred" patterns on their feathers, which are made up of horizontal bars alternating dark and light pigmentation side by side.
"Since Darwin wrote of visual communication in birds, we have known that bright coloured feathers play a role in sexual signalling, for example to attract females. But the role of barred patterns as a communication signal has largely been overlooked," Gluckman said.
The study was a large-scale comparison of plumage of around 8900 bird species worldwide (90% of all bird species), and was conducted with former University of Melbourne lecturer Dr. Gonçalo Cardoso, now at the Research Centre in Biodiversity and Genetic Resources (CIBIO), Portugal.
The researchers compared barred plumage and other patterns on the body of males, females, and juvenile birds, to assess what they might be used for.
While the researchers found evidence that barred plumage is predominantly used as camouflage, they also found that barred plumage was much more likely to appear only in males, or only at sexual maturity, compared to other patterns.
"Furthermore, we found these differences on the front of the birds, which is an important area for communication during face-to-face interactions, not on their back, which is more useful for camouflage when running away or hiding from predators," she said.
"This is an exciting finding showing an elegant evolutionary solution to the needs of birds to camouflage as well as to signal to a potential mate or rival."
The study has been published in the Journal of Evolutionary Biology