Yearly Archives: 2013

Environs

Plagiarism is the Sincerest Form of Capitalism

Plagiarism is fine art in China. But, it’s also very big business. The nation knocks off everything, from Hollywood and Bollywood movies, to software, electronics, appliances, drugs, and military equipment. Now, it’s moved on to copying architectural plans.

[div class=attrib]From the Telegraph:[end-div]

China is famous for its copy-cat architecture: you can find replicas of everything from the Eiffel Tower and the White House to an Austrian village across its vast land. But now they have gone one step further: recreating a building that hasn’t even been finished yet. A building designed by the Iraqi-British architect Dame Zaha Hadid for Beijing has been copied by a developer in Chongqing, south-west China, and now the two projects are racing to be completed first.

Dame Zaha, whose Wangjing Soho complex consists of three pebble-like constructions and will house an office and retail complex, unveiled her designs in August 2011 and hopes to complete the project next year.

Meanwhile, a remarkably similar project called Meiquan 22nd Century is being constructed in Chongqing, that experts (and anyone with eyes, really) deem a rip-off. The developers of the Soho complex are concerned that the other is being built at a much faster rate than their own.

“It is possible that the Chongqing pirates got hold of some digital files or renderings of the project,” Satoshi Ohashi, project director at Zaha Hadid Architects, told Der Spiegel online. “[From these] you could work out a similar building if you are technically very capable, but this would only be a rough simulation of the architecture.”

So where does the law stand? Reporting on the intriguing case, China Intellectual Property magazine commented, “Up to now, there is no special law in China which has specific provisions on IP rights related to architecture.” They added that if it went to court, the likely outcome would be payment of compensation to Dame Zaha’s firm, rather than the defendant being forced to pull the building down. However, Dame Zaha seems somewhat unfazed about the structure, simply remarking that if the finished building contains a certain amount of innovation then “that could be quite exciting”. One of the world’s most celebrated architects, Dame Zaha – who recently designed the Aquatics Centre for the London Olympics – has 11 current projects in China. She is quite the star over there: 15,000 fans flocked to see her give a talk at the unveiling of the designs for the complex.

[div class=attrib]Read the entire article after the jump.[end-div]

[div class=attrib]Image: Wangjing Soho Architecture. Courtesy of Zaha Hadid Architects.[end-div]

BigBang

You Are Different From Yourself

The next time your spouse tells you that you’re “just not the same person anymore” there may be some truth to it. After all, we are not who we thought we would become, nor are we likely to become what we think. That’s the overall result of a recent study of human personality changes in around 20,000 people over time.

[div class=attrib]From Independent:[end-div]

When we remember our past selves, they seem quite different. We know how much our personalities and tastes have changed over the years. But when we look ahead, somehow we expect ourselves to stay the same, a team of psychologists said Thursday, describing research they conducted of people’s self-perceptions.

They called this phenomenon the “end of history illusion,” in which people tend to “underestimate how much they will change in the future.” According to their research, which involved more than 19,000 people ages 18 to 68, the illusion persists from teenage years into retirement.

“Middle-aged people — like me — often look back on our teenage selves with some mixture of amusement and chagrin,” said one of the authors, Daniel T. Gilbert, a psychologist at Harvard. “What we never seem to realize is that our future selves will look back and think the very same thing about us. At every age we think we’re having the last laugh, and at every age we’re wrong.”

Other psychologists said they were intrigued by the findings, published Thursday in the journal Science, and were impressed with the amount of supporting evidence. Participants were asked about their personality traits and preferences — their favorite foods, vacations, hobbies and bands — in years past and present, and then asked to make predictions for the future. Not surprisingly, the younger people in the study reported more change in the previous decade than did the older respondents.

But when asked to predict what their personalities and tastes would be like in 10 years, people of all ages consistently played down the potential changes ahead.

Thus, the typical 20-year-old woman’s predictions for her next decade were not nearly as radical as the typical 30-year-old woman’s recollection of how much she had changed in her 20s. This sort of discrepancy persisted among respondents all the way into their 60s.

And the discrepancy did not seem to be because of faulty memories, because the personality changes recalled by people jibed quite well with independent research charting how personality traits shift with age. People seemed to be much better at recalling their former selves than at imagining how much they would change in the future.

Why? Dr. Gilbert and his collaborators, Jordi Quoidbach of Harvard and Timothy D. Wilson of the University of Virginia, had a few theories, starting with the well-documented tendency of people to overestimate their own wonderfulness.

“Believing that we just reached the peak of our personal evolution makes us feel good,” Dr. Quoidbach said. “The ‘I wish that I knew then what I know now’ experience might give us a sense of satisfaction and meaning, whereas realizing how transient our preferences and values are might lead us to doubt every decision and generate anxiety.”

Or maybe the explanation has more to do with mental energy: predicting the future requires more work than simply recalling the past. “People may confuse the difficulty of imagining personal change with the unlikelihood of change itself,” the authors wrote in Science.

The phenomenon does have its downsides, the authors said. For instance, people make decisions in their youth — about getting a tattoo, say, or a choice of spouse — that they sometimes come to regret.

And that illusion of stability could lead to dubious financial expectations, as the researchers showed in an experiment asking people how much they would pay to see their favorite bands.

When asked about their favorite band from a decade ago, respondents were typically willing to shell out $80 to attend a concert of the band today. But when they were asked about their current favorite band and how much they would be willing to spend to see the band’s concert in 10 years, the price went up to $129. Even though they realized that favorites from a decade ago like Creed or the Dixie Chicks have lost some of their luster, they apparently expect Coldplay and Rihanna to blaze on forever.

“The end-of-history effect may represent a failure in personal imagination,” said Dan P. McAdams, a psychologist at Northwestern who has done separate research into the stories people construct about their past and future lives. He has often heard people tell complex, dynamic stories about the past but then make vague, prosaic projections of a future in which things stay pretty much the same.

[div class=attrib]Read the entire article after the jump.[end-div]

BigBang

Planets From Stardust

Stunning images captured by Atacama Millimetre-submillimetre Array (ALMA) radio telescope in Chile show the early stages of a planet forming from stardust around a star located 450 light-years from Earth. This is the first time that astronomers have snapped such a clear picture of the process, confirming long-held theories of planetary formation.

[div class=attrib]From Independent:[end-div]

The world’s highest radio telescope, built on a Chilean plateau in the Andes 5,000 metres above sea level, has captured the first image of a new planet being formed as it gobbles up the cosmic dust and gas surrounding a distant star.

Astronomers have long predicted that giant “gas” planets similar to Jupiter would form by collecting the dust and debris that forms around a young star. Now they have the first visual evidence to support the phenomenon, scientists said.

The image taken by the Atacama Millimetre-submillimetre Array (ALMA) in Chile shows two streams of gas connecting the inner and outer disks of cosmic material surrounding the star HD 142527, which is about 450 light-years from Earth.

Astronomers believe the gas streamers are the result of two giant planets – too small to be visible in this image – exerting a gravitational pull on the cloud of surrounding dust and gas, causing the material to flow from the outer to inner stellar disks, said Simon Casassus of the University of Chile in Santiago.

“The most natural interpretation for the flows seen by ALMA is that the putative proto-planets are pulling streams of gas inward towards them that are channelled by their gravity. Much of the gas then overshoots the planets and continues inward to the portion of the disk close to the star, where it can eventually fall onto the star itself,” Dr Casassus said.

“Astronomers have been predicting that these streams exist, but this is the first time we’ve been able to see them directly. Thanks to the new ALMA telescope, we’ve been able to get direct observations to illuminate current theories of how planets are formed,” he said.

[div class=attrib]Read the entire article following the jump.[end-div]

[div class=attrib]Image: Observations (left) made with the ALMA telescope of the young star HD 142527. The dust in the outer disc is shown in red. Dense gas in the streams flowing across the gap, as well as in the outer disc, is shown in green. Diffuse gas in the central gap is shown in blue. The gas filaments can be seen at the three o’clock and ten o’clock positions, flowing from the outer disc towards the centre. And (right) an artist’s impression. Courtesy of Independent.[end-div]

BigBang

Curiosity’s 10K Hike

Scientists and engineers at JPL have Mount Sharp in their sites. It’s no ordinary mountain — it’s situated on Mars. The 5,000 meter high mountain is home to exposed layers of some promising sedimentary rocks, which hold clues to Mars’ geologic, and perhaps biological, history. Unfortunately, Mount Sharp is 10K away from the current home of the Curiosity rover. So, at a top speed of around 100 meters per day it will take Curiosity until the fall of 2013 to reach its destination.

[div class=attrib]From the New Scientist:[end-div]

NASA’S Curiosity rover is about to have its cake and eat it too. Around September, the rover should get its first taste of layered sediments at Aeolis Mons, a mountain over 5 kilometres tall that may hold preserved signs of life on Mars.

Previous rovers uncovered ample evidence of ancient water, a key ingredient for life as we know it. With its sophisticated on-board chemistry lab, Curiosity is hunting for more robust signs of habitability, including organic compounds – the carbon-based building blocks of life as we know it.

Observations from orbit show that the layers in Aeolis Mons – also called Mount Sharp – contain minerals thought to have formed in the presence of water. That fits with theories that the rover’s landing site, Gale crater, was once a large lake. Even better, the layers were probably laid down quickly enough that the rocks could have held on to traces of microorganisms, if they existed there.

If the search for organics turns up empty, Aeolis Mons may hold other clues to habitability, says project scientist John Grotzinger of the California Institute of Technology in Pasadena. The layers will reveal which minerals and chemical processes were present in Mars’s past. “We’re going to find all kinds of good stuff down there, I’m sure,” he says.

Curiosity will explore a region called Glenelg until early February, and then hit the gas. The base of the mountain is 10 kilometres away, and the rover can drive at about 100 metres a day at full speed. The journey should take between six and nine months, but will include stops to check out any interesting landmarks. After all, some of the most exciting discoveries from Mars rovers were a result of serendipity.

[div class=attrib]Read the entire article following the jump.[end-div]

[div class=attrib]Image: Base of Mount Sharp, Mars. Courtesy of Credit: NASA/JPL-Caltech/MSSS.[end-div]

BigBang

Evolution and Autocatalysis

A clever idea about the process of emergence from mathematicians at the University of Vermont has some evolutionary biologists thinking.

[div class=attrib]From MIT Review:[end-div]

One of the most puzzling questions about the origin of life is how the rich chemical landscape that makes life possible came into existence.

This landscape would have consisted among other things of amino acids, proteins and complex RNA molecules. What’s more, these molecules must have been part of a rich network of interrelated chemical reactions which generated them in a reliable way.

Clearly, all that must have happened before life itself emerged. But how?

One idea is that groups of molecules can form autocatalytic sets. These are self-sustaining chemical factories, in which the product of one reaction is the feedstock or catalyst for another. The result is a virtuous, self-contained cycle of chemical creation.

Today, Stuart Kauffman at the University of Vermont in Burlington and a couple of pals take a look at the broader mathematical properties of autocatalytic sets. In examining this bigger picture, they come to an astonishing conclusion that could have remarkable consequences for our understanding of complexity, evolution and the phenomenon of emergence.

They begin by deriving some general mathematical properties of autocatalytic sets, showing that such a set can be made up of many autocatalytic subsets of different types, some of which can overlap.

In other words, autocatalytic sets can have a rich complex structure of their own.

They go on to show how evolution can work on a single autocatalytic set, producing new subsets within it that are mutually dependent on each other.  This process sets up an environment in which newer subsets can evolve.

“In other words, self-sustaining, functionally closed structures can arise at a higher level (an autocatalytic set of autocatalytic sets), i.e., true emergence,” they say.

That’s an interesting view of emergence and certainly seems a sensible approach to the problem of the origin of life. It’s not hard to imagine groups of molecules operating together like this. And indeed, biochemists have recently discovered simple autocatalytic sets that behave in exactly this way.

But what makes the approach so powerful is that the mathematics does not depend on the nature of chemistry–it is substrate independent. So the building blocks in an autocatalytic set need not be molecules at all but any units that can manipulate other units in the required way.

These units can be complex entities in themselves. “Perhaps it is not too far-fetched to think, for example, of the collection of bacterial species in your gut (several hundreds of them) as one big autocatalytic set,” say Kauffman and co.

And they go even further. They point out that the economy is essentially the process of transforming raw materials into products such as hammers and spades that themselves facilitate further transformation of raw materials and so on. “Perhaps we can also view the economy as an (emergent) autocatalytic set, exhibiting some sort of functional closure,” they speculate.

[div class=attrib]Read the entire article after the jump.[end-div]