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Team USA

*Continued from above (previous page)

11. Supercooling Materials To Provide Radiation Sheilding And Energy Storage

NASA Kennedy Space Center’s Robert Youngquist is the principle investigator for Cryogenic Selective Surfaces, a project to develop surfaces for extreme passive cooling. By creating materials with with wavelength-dependent emissivity and absorption properties, the research team is hoping they can create new cryogenic storage and large-scale superconducting systems that can be used in deep space for galactic cosmic radiation shielding or energy storage. The prototype materials have been tested on Earth to cool to -50°C below ambient temperatures, but could theoretically work much better in a vacuum.

12. Sunlight-Drills To Capture And Mine Asteroids For Water

1249995954110171209.jpg


The APIS (Asteroid Provided In-Situ Supplies): 100MT Of Water from a Single Falcon 9 is the idea of Joel Sercel of ICS Associates Inc to fix the problem of how to find usable water in space in an affordable, accessible manner. The team hopes that they can wrap asteroids in bags, then use optical mining to concentrate sunlight to drill into them. The project is designed to be lightweight and compact enough that all the equipment can be loaded unto a single rocket launch (Falcon 9 or equivalent), harnessing the technology of the Asteroid Redirect Mission to capture a target and trap outgassing water released during optical mining.

13. WindBots To Explore The Cloudy Skies Of Gas Giants

1249995954190733129.jpg


The WindBots: persistent in-situ science explorers for gas giants is exactly what it says on the label: a project to create autonomous robots that can investigate the atmospheres of Jupiter, Saturn, Uranus, or Neptune. Under the guidance of Jet Propulsion Laboratory’s Adrian Stoica, the project is hoping to design robots that can directly harvest energy locally, allowing them to persistently explore their assigned gas giant. That same technology could theoretically be applied to other planetary robotic explorers, reducing their reliance on expensive nuclear energy.

14. Deformable Mirrors Shaped By Magnetic Fields

1249995954250313545.jpg


Melville Ulmer at Northwestern University is partnering with researchers at the University of Illinois to investigate the feasibility of creating shapable telescope mirrors with magnetic fields.Aperture: A Precise Extremely large Reflective Telescope Using Re-configurable Elements is a concept that combines a flying magnetic write head with magnetic smart material coating the back of a mirror, creating a deformable reflecting membrane. Earlier iterations of the concept ran into problems with distorting the mirror outside of correctable error-bounds, and creating a mirror that can keep its shape for long periods of time.

15. New Type Of Lens To Reduce The Cost Of Large Telescopes

1249995954439400521.jpg


One of the most expensive things about building telescopes is developing beautiful, flawless lenses to focus light. Nelson Tabirian is leading the Thin-Film Broadband Large Area Imaging System project at BEAM Engineering for Advanced Measurements Co. to apply their waveplate lens technology to creating a new type of light-weight, economical thin film lens. The waveplate lenses and mirrors could theoretically be used to build telescopes with a far larger aperture than currently feasible under current technology and economic considerations, leading to a new generation of ultra-enormous telescopes. The technology uses techniques developed for laser communication to correct chromatic aberrations, permitting submicroradian angular radiation.

@levina @thesolar65 @Nihonjin1051 @AMDR @Armstrong - there I tagged you:p: @Transhumanist
 
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Squid inspired submarines on Europa sounds like a great idea. :)

Don't know anybody in California. Most people here seem to be from the ~Northeast area of the US.

So I was at my local wholesale club and the guy in front of me waved his iPhone6 at the credit card swiper machine and that was that...payment all done. Now I've seen this before with Android phones (and on both using the 3D barcode thing) but this was the first I saw ApplePay being used. I have an iPhone6 myself so maybe I'll have to sign up.

Using your SmartPhone to pay: Apple Pay - Wikipedia, the free encyclopedia

View attachment 211381


Places that support Apple Pay:
Apple - Apple Pay
In this part of the world, many iPhone users use an app called "beam wallet".
I decided to download it, and that when I read the review :P :lol:

image.jpg
 
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. .
Stop trying to cut NASA's budget:pissed:!!!!!!

Here's How Planet Hunters Are Going to Find the Next Earth


Twenty years ago, discovering another Earth sounded like a science fictional dream. But within a generation, astronomers now believe we might do just that.

“Finding evidence of life beyond Earth is not a pipe dream,” said Natalie Batalha, an astronomer at NASA’s Ames research center. “Its something we can accomplish—maybe not within my lifetime, maybe within my daughter’s life.”

Batalha’s sentiment was echoed last Saturday by the men and women who spoke at the opening ceremony of the Carl Sagan Institute at Cornell University. The institute, brainchild of astronomer Lisa Kaltenegger, was founded to explore the diversity of worlds we’ve just begun to glimpse on the cosmic horizon. If we’re lucky, we may find another planet like Earth. Or a dozen. Or a thousand.

“How do you figure out if a world orbiting another star is a habitable place?” Kaltenegger said. “We’re living in the first time in history that we have the tools to answer that question.”

Finding Earth 2.0 won’t be easy. It’ll be an enormous effort, but the astronomers, planetary
scientists, chemists and biologists leading the Carl Sagan Institute have a plan to get us there. Here’s how we’re trying to find the next pale blue dot and an end to our cosmic loneliness.

Billions and Billions
It’s a great time to be alive if you’re interested in worlds beyond our solar system. Over the past two decades, exoplanet science has undergone nothing short of a revolution, and even if you’re skeptical about the idea of alien life, the discoveries we’ve made are damn impressive.

1256279949350289510.jpg


Consider the numbers: Twenty years ago, astronomers hadn’t confirmed a single planet outside our solar system. In the past six years, NASA’s Kepler mission—a space-based telescope that orbits our sun, looking at over 100 thousand stars simultaneously—has uncovered over 4100 planetary candidates and 1000 confirmed planets. Kepler is not scanning the whole sky. Rather, the scope monitors a tiny sliver of our galaxy, taking a cosmic census of sorts. With this census, astronomers have used statistics to extrapolate the distribution of planets throughout the Milky Way.

“We have learned most stars have planets, that Earth sized planets are common, and a good fraction are in the habitable zone of their star,” said Bill Borucki, the lead investigator for the Kepler mission. “And when you put the numbers together: 100 billion stars, 10 percent with Earth-sized planets, 10 percent stars like the sun, that’s a billion Earth-sized planets in the habitable zone of stars like the sun.”

Let me repeat that last bit. There may be a billion Earth-sized planets in the habitable zone of a sun-like star. Thirty years ago, astronomers weren’t sure of any. And that, of course, is just within our galaxy.

“There are billions of stars in our galaxy alone, billions of galaxies out there,” Kaltenegger said. “The numbers are, fortunately, very much in our favor.”

1256279949424003430.png


The technology behind this incredible discovery is in principle quite simple. Most exoplanets to date have been detected via transit—a slight dip in the light emitted from a star as a planet crosses its path within the line of sight of a telescope. In practice, however, pinpointing these planetary shadows is insanely hard, because the brief change in starlight caused by a transit event is utterly miniscule.

“Imagine you’re looking at the tallest skyscraper in New York City, and it’s nighttime,” Batalha said. “Every single window is open and every light is on. One person goes and lowers the blinds on one window by about a centimeter. That’s the change in light you have to measure to find an Earth-sized planet.”

And you need to do so at least twice, to be sure you didn’t just make it up.


For transit to work, we’ve had to develop photometers a thousand times more precise than any built before. As Borucki explained, these light sensors must monitor thousands of stars at once, because the chance a planet lines up in the path of a star in a telescope’s line of sight is less than 1 percent. The scope’s photometer also has to remain perfectly still at all times—not anchored to the ground, but in outer space.

And for how ambitious those specifications are—it took Borucki nearly two decades to design, prototype, and convince NASA to green-light Kepler—all that transit gives us is a planet’s radius, orbital period, and sometimes its mass. And so far, only for worlds that are at Earth’s orbital distance or inward. (The transit of more distant planets is too faint for Kepler’s photometer to detect.) Through mass and radius we can calculate planetary density, which tells us whether we’re looking at a rocky, Earth-like world or a Jupiter-like ball of gas.

1256279949492810086.png


So far, the galaxy has been full of surprises. Many stars harbor large worlds orbiting far closer than Mercury, a situation which was considered nigh impossible thirty years ago. The two most common types of planets known to humanity right now—so called “super Earths” and “mini-Neptunes”—are not even represented in our solar system. We have hints of incredibly bizarre places out there, of gas giants as light as styrofoam, of ocean worlds and lava planets.

“There are planets orbiting binary stars, that have not one sun rising in the east and setting in the west but two,” said Batalha. “We find planets in star clusters, with 25 stars packed into a single cubic parsec of space. On these planets, you’d be look up and see a bejeweled sky.”

“There’s an incredibly wondrous diversity of worlds out there, and we haven’t even started to scratch the surface,” Kaltenegger said.

1256279949534837862.jpg


Scattered amongst these exotic worlds, we’ve also found a handful of “Goldilocks” planets—worlds that are not-too-hot and not-too cold, that are rocky, that are orbiting stars like our sun. Worlds that could be the next Earth.

“These [potentially habitable] planets are relatively common, and using statistics, we know they’re likely to be nearby,” Batalha said.

Still, for a world to go from potentially habitable to a bonafide Earth, we’ll need to get a much better look at it. That’s exactly what we’re hoping to do with the next generation of scopes. With future missions, we’ll look not only look at the ebb and flow of light from distant stars, but at the atmospheres of planets themselves. From light years away, our scopes will effectively sample the air of other worlds.

When that happens, astronomers across the world will become alien hunters.

Hunting for Goldilocks
Earth may be a cozy blue marble today, but it wasn’t always sunshine and roses. Four billion years ago, our planet’s rocky surface was erupting in fiery volcanoes, bombarded with comets and asteroids, awash in sterilizing UV radiation, and contained practically no oxygen, to boot.

1256279949581396326.jpg


It was life that terraformed the Earth—early, hardy colonizers that, over the course of billions of years, turned a rocky wasteland into a comfortable, breathable biosphere. Ancient cyanobacteria were probably the first to produce significant amounts of oxygen as a waste product from photosynthesis. Today, our air contains a healthy supply of O2, replenished constantly by Earth’s plant life and phytoplankton, as well as a thin layer of ozone, which shields us from damaging ultraviolet radiation. Earth’s atmosphere also contains trace amounts of reducing gases —things like CO2 and methane—replenished by the collective exhale of life’s metabolism, and, recently, by the burning of fossil fuels.

Taken alone, oxygen or methane don’t make a strong case for life—both can be produced by inorganic chemical reactions. But put them together, sprinkle in a little water, and it’s a different story.

“Our best signature [for life] to date is the combination of oxygen or ozone with a reducing gas—something that should make oxygen go away,” Kaltenegger told me.“A lot of the things that are biological, like methane alone, or CO2 alone, can also come from rocks, so we can’t just use those. But if oxygen is found together with methane, then something has to be producing it in large amounts right now.”

So, our alien hunters already have some promising fingerprints in mind. Find these ingredients in the atmosphere of a Goldilocks planet circling sun-like star, and we may just have ourselves another Earth. Now how the hell do we go about searching?

1256279949649451622.png


Through a pipeline of future space missions, beginning with the Transit Exoplanet Survey Satellite (TESS), which launches in 2017. While most of Kepler’s targets were 500-1,000 light years away, TESS is going to be our friendly neighborhood planet hunter—it’ll scan the entire sky, monitoring more than half a million stars in our very close cosmic vicinity.

“TESS will be like Kepler, just doing transit, but instead of staring at one particular part of sky, it’ll scan the entire sky, focusing on our nearest neighbors,” Kaltenegger told me. “It’ll allow us to pick a lot of promising targets that are much closer than the Kepler planets.”

TESS may turn up many hopeful candidates, but it won’t be studying their atmospheres. That process starts gearing up with the James Webb Space Telescope, a 6.5 meter-long solar-powered observatory slated to launch in 2018. With unprecedented detection power, JWST will become the premier observatory of the next decade. Its sensitivity comes in part from a massive sunshield that chills the scope’s instruments to below -370 degrees Fahrenheit. At such low temperatures, the JWST itself emits very little radiation, allowing for the detection of faint energy signatures from far away—including slight dips in the light emitted from a distant star as it filters through a planet’s atmosphere.

1256279949722974566.jpg


“You take that planet, that one tiny pixel, and you split the light,” Kaltenegger said. “You look at the different colors—basically what happens when sunlight passes through a raindrop and makes a rainbow—and if energy is missing, you can pinpoint, over light years away, what chemicals molecules are there, in the air of that world.”

But. Impressive as JWST will be, this scope still won’t be powerful enough to study many rocky, Earth-like planets. (If, Kaltenegger says, we find a rocky super-Earth around a dim red dwarf very close by, we may have a chance of looking at its atmosphere.) JWST’s eyes will be fixed on mostly larger worlds—and these will typically be blustery blobs of gas.

“JWST is going to knock it out of the ballpark for mini-Neptunes and super Earths, it’s going to understand the diversity of their atmospheres, but its not tailored to find Earth-sized planets,” Batalha said.

Next up after JWST is the Wide Field Infrared Survey Telescope (WFIRST), a retrofitted spy scope that, using a technique called microlensing, will have the sensitivity to detect smaller than Earth-sized planets orbiting at distances beyond 1 AU (the distance between Earth and the Sun). Using a starlight-blocking coronagraph, WFIRST will also be able to directly see reflected light from some larger planets.

“Kepler is getting the statistics of exoplanets within an Earth orbit and inward,” Batalha said. “WFIRST is going to get the statistics of planets orbiting at an Earth orbit or outward. So, over time, we’re going to build up this comprehensive picture of what exoplanets are out there.”

And once WFIRST launches in the mid-2020’s, space agencies finally plan to double down on a “life finder” mission. It’s this future mission which we’re hoping has the power to decode the atmospheres of many rocky, Earth-sized planets orbiting stars throughout our stellar neighborhood.

“Between now and the life finder, we’re not going to find nearby Earths in great numbers,” Batalha said. “But as long as we’re well positioned by 2025 to start putting money into a life finder, then I think we’ll have a hope of really making headway in three decades.”

Three decades till we’ve got a good chance of finding the next Earth seems to be the ballpark most exoplanet hunters are comfortable with. But if Earths turn out to be very common, we may get lucky and find ourselves a neighbor sooner.

“TESS is going to find a few dozen planets that are small enough, rocky, within the right distance to their star,” Kaltenegger said. “Then we’ll have a list of the closest promising worlds that we can put all of our telescopes on and observe night after night. It’s going to be crazy how much work it’ll be, but it’s also going to be an incredible opportunity.”

How We’ll Know It When We See It
It may take several decades for the technology needed to spot Earth 2.0 to come online. But astronomers aren’t just twiddling their thumbs waiting.

“We want to be as prepared as we can by asking the question now: among the thousands of worlds, among the dozens that are close by, which ones will we want to pick?” Kaltenegger said. “Combining what we know about life on the Earth with astronomy is one of the strongest ways to do that.”

At the Carl Sagan Institute, Kaltenegger and her colleagues are amassing troves of information that will help alien hunters hone in on the most promising candidate worlds. These include afingerprint database containing hundreds of hypothetical atmospheric chemistries—some that look like our Earth today, some that look like Earth’s geologic past, others which are totally alien. The database, which Kaltenegger once described to me as “CSI for exoplanets” will be used to categorize distant worlds and rank them in terms of how Earth-like they are.

1256279949922600038.jpg


A color catalog will help us search for an entirely different type of fingerprint. Just as Earth’s green landscapes and blue oceans hint at life’s presence, the vibrant biota on distant worlds might offer telltale clues. In a study published in March, researchers examined over 100 microorganisms across planet Earth, including many that live in extreme environs, and documented their reflection signatures. The diversity of colors represented in these critters will help alien hunters imagine what life might look like and how we might detect it beyond the pale blue dot.

“If a world had a different biota than what is dominant here, it would look different,” Kaltenegger said. “If you think about this in colors—how does a world look in the blue, red and green—the different surfaces would appear different colors. And that’s what you could use to prioritize which planets look more like they could host life.

Right now, in this time, with thousands of planets on the horizon, and new missions coming up in the next five to ten years—now is when we need to understand what we could be finding and how we could find it.”

Once We Find It, Then What?
It’s incredible to consider the possibility of finding a second Earth. But even definitive proof of life on another world won’t eliminate our desire to explore. Quite the opposite.

Which brings me to a question posed at the very end of the Carl Sagan Institute inaugural ceremony, to a panel full of astronomers, astrobiologists and planet hunters. Say we find another Earth. Say it’s close—a couple light years or so from our solar system. Then what?

The resounding response was exactly what any science fiction fan would have hoped to hear. We have try to get there.

“If somebody finds a real Earth-like planet within a few light years, my reaction is, lets start building a spacecraft,” said Cornell astronomer Steve Squyres, the lead investigator on the Mars Exploration Rover.

“Look,” said Didier Queloz, an exoplanet researcher at the University of Cambridge, “it took the human species ten thousand years to spread across the Earth. When I came here, it took me eight hours by plane to cross the Atlantic ocean. Maybe we need another hundred, or a thousand years, but it doesn’t seem so crazy to think we’ll be sending probes to these nearby planets. There is no fundamental limitation but the time.”

Batalha agrees. “Once we know that there’s life—once we can point to a star in the sky and say there’s life there—I personally think we’re going to figure out how to get to it.”

A manned interstellar voyage would almost certainly be a multigenerational trip. In a world that seems increasingly obsessed with instant gratification, it can be hard to imagine people sacrificing their lives for a journey they’d never see the end of. And yet, as Ann Druyan, co-writer and producer of Cosmos pointed out, everyone involved with exoplanet discovery today is a multigenerational thinker.

“Only seventy five to eighty years ago, the notion that there were other worlds circling stars was not even, scientifically, a respectable position to take,” she said. “And here we are today, engaged in multigenerational projects.”

“Look at cathedrals,” Queloz said. “Most people who first built them didn’t think they’d see the end. I think we’re building cathedrals—science is a modern way of expressing that. I think as a species, we’re used to working together, teaming together, and it’s in our genes to do this.”

:usflag::usflag::usflag:
 
.
Stop trying to cut NASA's budget:pissed:!!!!!!

Here's How Planet Hunters Are Going to Find the Next Earth


Twenty years ago, discovering another Earth sounded like a science fictional dream. But within a generation, astronomers now believe we might do just that.

“Finding evidence of life beyond Earth is not a pipe dream,” said Natalie Batalha, an astronomer at NASA’s Ames research center. “Its something we can accomplish—maybe not within my lifetime, maybe within my daughter’s life.”

Batalha’s sentiment was echoed last Saturday by the men and women who spoke at the opening ceremony of the Carl Sagan Institute at Cornell University. The institute, brainchild of astronomer Lisa Kaltenegger, was founded to explore the diversity of worlds we’ve just begun to glimpse on the cosmic horizon. If we’re lucky, we may find another planet like Earth. Or a dozen. Or a thousand.

“How do you figure out if a world orbiting another star is a habitable place?” Kaltenegger said. “We’re living in the first time in history that we have the tools to answer that question.”

Finding Earth 2.0 won’t be easy. It’ll be an enormous effort, but the astronomers, planetary
scientists, chemists and biologists leading the Carl Sagan Institute have a plan to get us there. Here’s how we’re trying to find the next pale blue dot and an end to our cosmic loneliness.

Billions and Billions
It’s a great time to be alive if you’re interested in worlds beyond our solar system. Over the past two decades, exoplanet science has undergone nothing short of a revolution, and even if you’re skeptical about the idea of alien life, the discoveries we’ve made are damn impressive.

1256279949350289510.jpg


Consider the numbers: Twenty years ago, astronomers hadn’t confirmed a single planet outside our solar system. In the past six years, NASA’s Kepler mission—a space-based telescope that orbits our sun, looking at over 100 thousand stars simultaneously—has uncovered over 4100 planetary candidates and 1000 confirmed planets. Kepler is not scanning the whole sky. Rather, the scope monitors a tiny sliver of our galaxy, taking a cosmic census of sorts. With this census, astronomers have used statistics to extrapolate the distribution of planets throughout the Milky Way.

“We have learned most stars have planets, that Earth sized planets are common, and a good fraction are in the habitable zone of their star,” said Bill Borucki, the lead investigator for the Kepler mission. “And when you put the numbers together: 100 billion stars, 10 percent with Earth-sized planets, 10 percent stars like the sun, that’s a billion Earth-sized planets in the habitable zone of stars like the sun.”

Let me repeat that last bit. There may be a billion Earth-sized planets in the habitable zone of a sun-like star. Thirty years ago, astronomers weren’t sure of any. And that, of course, is just within our galaxy.

“There are billions of stars in our galaxy alone, billions of galaxies out there,” Kaltenegger said. “The numbers are, fortunately, very much in our favor.”

1256279949424003430.png


The technology behind this incredible discovery is in principle quite simple. Most exoplanets to date have been detected via transit—a slight dip in the light emitted from a star as a planet crosses its path within the line of sight of a telescope. In practice, however, pinpointing these planetary shadows is insanely hard, because the brief change in starlight caused by a transit event is utterly miniscule.

“Imagine you’re looking at the tallest skyscraper in New York City, and it’s nighttime,” Batalha said. “Every single window is open and every light is on. One person goes and lowers the blinds on one window by about a centimeter. That’s the change in light you have to measure to find an Earth-sized planet.”

And you need to do so at least twice, to be sure you didn’t just make it up.


For transit to work, we’ve had to develop photometers a thousand times more precise than any built before. As Borucki explained, these light sensors must monitor thousands of stars at once, because the chance a planet lines up in the path of a star in a telescope’s line of sight is less than 1 percent. The scope’s photometer also has to remain perfectly still at all times—not anchored to the ground, but in outer space.

And for how ambitious those specifications are—it took Borucki nearly two decades to design, prototype, and convince NASA to green-light Kepler—all that transit gives us is a planet’s radius, orbital period, and sometimes its mass. And so far, only for worlds that are at Earth’s orbital distance or inward. (The transit of more distant planets is too faint for Kepler’s photometer to detect.) Through mass and radius we can calculate planetary density, which tells us whether we’re looking at a rocky, Earth-like world or a Jupiter-like ball of gas.

1256279949492810086.png


So far, the galaxy has been full of surprises. Many stars harbor large worlds orbiting far closer than Mercury, a situation which was considered nigh impossible thirty years ago. The two most common types of planets known to humanity right now—so called “super Earths” and “mini-Neptunes”—are not even represented in our solar system. We have hints of incredibly bizarre places out there, of gas giants as light as styrofoam, of ocean worlds and lava planets.

“There are planets orbiting binary stars, that have not one sun rising in the east and setting in the west but two,” said Batalha. “We find planets in star clusters, with 25 stars packed into a single cubic parsec of space. On these planets, you’d be look up and see a bejeweled sky.”

“There’s an incredibly wondrous diversity of worlds out there, and we haven’t even started to scratch the surface,” Kaltenegger said.

1256279949534837862.jpg


Scattered amongst these exotic worlds, we’ve also found a handful of “Goldilocks” planets—worlds that are not-too-hot and not-too cold, that are rocky, that are orbiting stars like our sun. Worlds that could be the next Earth.

“These [potentially habitable] planets are relatively common, and using statistics, we know they’re likely to be nearby,” Batalha said.

Still, for a world to go from potentially habitable to a bonafide Earth, we’ll need to get a much better look at it. That’s exactly what we’re hoping to do with the next generation of scopes. With future missions, we’ll look not only look at the ebb and flow of light from distant stars, but at the atmospheres of planets themselves. From light years away, our scopes will effectively sample the air of other worlds.

When that happens, astronomers across the world will become alien hunters.

Hunting for Goldilocks
Earth may be a cozy blue marble today, but it wasn’t always sunshine and roses. Four billion years ago, our planet’s rocky surface was erupting in fiery volcanoes, bombarded with comets and asteroids, awash in sterilizing UV radiation, and contained practically no oxygen, to boot.

1256279949581396326.jpg


It was life that terraformed the Earth—early, hardy colonizers that, over the course of billions of years, turned a rocky wasteland into a comfortable, breathable biosphere. Ancient cyanobacteria were probably the first to produce significant amounts of oxygen as a waste product from photosynthesis. Today, our air contains a healthy supply of O2, replenished constantly by Earth’s plant life and phytoplankton, as well as a thin layer of ozone, which shields us from damaging ultraviolet radiation. Earth’s atmosphere also contains trace amounts of reducing gases —things like CO2 and methane—replenished by the collective exhale of life’s metabolism, and, recently, by the burning of fossil fuels.

Taken alone, oxygen or methane don’t make a strong case for life—both can be produced by inorganic chemical reactions. But put them together, sprinkle in a little water, and it’s a different story.

“Our best signature [for life] to date is the combination of oxygen or ozone with a reducing gas—something that should make oxygen go away,” Kaltenegger told me.“A lot of the things that are biological, like methane alone, or CO2 alone, can also come from rocks, so we can’t just use those. But if oxygen is found together with methane, then something has to be producing it in large amounts right now.”

So, our alien hunters already have some promising fingerprints in mind. Find these ingredients in the atmosphere of a Goldilocks planet circling sun-like star, and we may just have ourselves another Earth. Now how the hell do we go about searching?

1256279949649451622.png


Through a pipeline of future space missions, beginning with the Transit Exoplanet Survey Satellite (TESS), which launches in 2017. While most of Kepler’s targets were 500-1,000 light years away, TESS is going to be our friendly neighborhood planet hunter—it’ll scan the entire sky, monitoring more than half a million stars in our very close cosmic vicinity.

“TESS will be like Kepler, just doing transit, but instead of staring at one particular part of sky, it’ll scan the entire sky, focusing on our nearest neighbors,” Kaltenegger told me. “It’ll allow us to pick a lot of promising targets that are much closer than the Kepler planets.”

TESS may turn up many hopeful candidates, but it won’t be studying their atmospheres. That process starts gearing up with the James Webb Space Telescope, a 6.5 meter-long solar-powered observatory slated to launch in 2018. With unprecedented detection power, JWST will become the premier observatory of the next decade. Its sensitivity comes in part from a massive sunshield that chills the scope’s instruments to below -370 degrees Fahrenheit. At such low temperatures, the JWST itself emits very little radiation, allowing for the detection of faint energy signatures from far away—including slight dips in the light emitted from a distant star as it filters through a planet’s atmosphere.

1256279949722974566.jpg


“You take that planet, that one tiny pixel, and you split the light,” Kaltenegger said. “You look at the different colors—basically what happens when sunlight passes through a raindrop and makes a rainbow—and if energy is missing, you can pinpoint, over light years away, what chemicals molecules are there, in the air of that world.”

But. Impressive as JWST will be, this scope still won’t be powerful enough to study many rocky, Earth-like planets. (If, Kaltenegger says, we find a rocky super-Earth around a dim red dwarf very close by, we may have a chance of looking at its atmosphere.) JWST’s eyes will be fixed on mostly larger worlds—and these will typically be blustery blobs of gas.

“JWST is going to knock it out of the ballpark for mini-Neptunes and super Earths, it’s going to understand the diversity of their atmospheres, but its not tailored to find Earth-sized planets,” Batalha said.

Next up after JWST is the Wide Field Infrared Survey Telescope (WFIRST), a retrofitted spy scope that, using a technique called microlensing, will have the sensitivity to detect smaller than Earth-sized planets orbiting at distances beyond 1 AU (the distance between Earth and the Sun). Using a starlight-blocking coronagraph, WFIRST will also be able to directly see reflected light from some larger planets.

“Kepler is getting the statistics of exoplanets within an Earth orbit and inward,” Batalha said. “WFIRST is going to get the statistics of planets orbiting at an Earth orbit or outward. So, over time, we’re going to build up this comprehensive picture of what exoplanets are out there.”

And once WFIRST launches in the mid-2020’s, space agencies finally plan to double down on a “life finder” mission. It’s this future mission which we’re hoping has the power to decode the atmospheres of many rocky, Earth-sized planets orbiting stars throughout our stellar neighborhood.

“Between now and the life finder, we’re not going to find nearby Earths in great numbers,” Batalha said. “But as long as we’re well positioned by 2025 to start putting money into a life finder, then I think we’ll have a hope of really making headway in three decades.”

Three decades till we’ve got a good chance of finding the next Earth seems to be the ballpark most exoplanet hunters are comfortable with. But if Earths turn out to be very common, we may get lucky and find ourselves a neighbor sooner.

“TESS is going to find a few dozen planets that are small enough, rocky, within the right distance to their star,” Kaltenegger said. “Then we’ll have a list of the closest promising worlds that we can put all of our telescopes on and observe night after night. It’s going to be crazy how much work it’ll be, but it’s also going to be an incredible opportunity.”

How We’ll Know It When We See It
It may take several decades for the technology needed to spot Earth 2.0 to come online. But astronomers aren’t just twiddling their thumbs waiting.

“We want to be as prepared as we can by asking the question now: among the thousands of worlds, among the dozens that are close by, which ones will we want to pick?” Kaltenegger said. “Combining what we know about life on the Earth with astronomy is one of the strongest ways to do that.”

At the Carl Sagan Institute, Kaltenegger and her colleagues are amassing troves of information that will help alien hunters hone in on the most promising candidate worlds. These include afingerprint database containing hundreds of hypothetical atmospheric chemistries—some that look like our Earth today, some that look like Earth’s geologic past, others which are totally alien. The database, which Kaltenegger once described to me as “CSI for exoplanets” will be used to categorize distant worlds and rank them in terms of how Earth-like they are.

1256279949922600038.jpg


A color catalog will help us search for an entirely different type of fingerprint. Just as Earth’s green landscapes and blue oceans hint at life’s presence, the vibrant biota on distant worlds might offer telltale clues. In a study published in March, researchers examined over 100 microorganisms across planet Earth, including many that live in extreme environs, and documented their reflection signatures. The diversity of colors represented in these critters will help alien hunters imagine what life might look like and how we might detect it beyond the pale blue dot.

“If a world had a different biota than what is dominant here, it would look different,” Kaltenegger said. “If you think about this in colors—how does a world look in the blue, red and green—the different surfaces would appear different colors. And that’s what you could use to prioritize which planets look more like they could host life.

Right now, in this time, with thousands of planets on the horizon, and new missions coming up in the next five to ten years—now is when we need to understand what we could be finding and how we could find it.”

Once We Find It, Then What?
It’s incredible to consider the possibility of finding a second Earth. But even definitive proof of life on another world won’t eliminate our desire to explore. Quite the opposite.

Which brings me to a question posed at the very end of the Carl Sagan Institute inaugural ceremony, to a panel full of astronomers, astrobiologists and planet hunters. Say we find another Earth. Say it’s close—a couple light years or so from our solar system. Then what?

The resounding response was exactly what any science fiction fan would have hoped to hear. We have try to get there.

“If somebody finds a real Earth-like planet within a few light years, my reaction is, lets start building a spacecraft,” said Cornell astronomer Steve Squyres, the lead investigator on the Mars Exploration Rover.

“Look,” said Didier Queloz, an exoplanet researcher at the University of Cambridge, “it took the human species ten thousand years to spread across the Earth. When I came here, it took me eight hours by plane to cross the Atlantic ocean. Maybe we need another hundred, or a thousand years, but it doesn’t seem so crazy to think we’ll be sending probes to these nearby planets. There is no fundamental limitation but the time.”

Batalha agrees. “Once we know that there’s life—once we can point to a star in the sky and say there’s life there—I personally think we’re going to figure out how to get to it.”

A manned interstellar voyage would almost certainly be a multigenerational trip. In a world that seems increasingly obsessed with instant gratification, it can be hard to imagine people sacrificing their lives for a journey they’d never see the end of. And yet, as Ann Druyan, co-writer and producer of Cosmos pointed out, everyone involved with exoplanet discovery today is a multigenerational thinker.

“Only seventy five to eighty years ago, the notion that there were other worlds circling stars was not even, scientifically, a respectable position to take,” she said. “And here we are today, engaged in multigenerational projects.”

“Look at cathedrals,” Queloz said. “Most people who first built them didn’t think they’d see the end. I think we’re building cathedrals—science is a modern way of expressing that. I think as a species, we’re used to working together, teaming together, and it’s in our genes to do this.”

:usflag::usflag::usflag:

Freaking awesome!!! NASA:yahoo::usflag:!
 
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Relaxing in the backyard

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Birds




I trade my cardinal for a hummingbird any-day. This is what I wake up to everyday... everyday:angry:!!!


Cardinals are prone to attacking their own reflection. Nice birds otherwise:

Northern Cardinal, Identification, All About Birds - Cornell Lab of Ornithology

  • Size & Shape
    The Northern Cardinal is a fairly large, long-tailed songbird with a short, very thick bill and a prominent crest. Cardinals often sit with a hunched-over posture and with the tail pointed straight down.

  • Color Pattern
    Male cardinals are brilliant red all over, with a reddish bill and black face immediately around the bill. Females are pale brown overall with warm reddish tinges in the wings, tail, and crest. They have the same black face and red-orange bill.

  • Behavior
    Northern Cardinals tend to sit low in shrubs and trees or forage on or near the ground, often in pairs. They are common at bird feeders but may be inconspicuous away from them, at least until you learn their loud, metallic chip note.

  • Habitat
    Look for Northern Cardinals in inhabited areas such as backyards, parks, woodlots, and shrubby forest edges. Northern Cardinals nest in dense tangles of shrubs and vines.
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NORTHERN-CARDINAL2.jpg
 
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Stop trying to cut NASA's budget:pissed:!!!!!!

Here's How Planet Hunters Are Going to Find the Next Earth


Twenty years ago, discovering another Earth sounded like a science fictional dream. But within a generation, astronomers now believe we might do just that.

“Finding evidence of life beyond Earth is not a pipe dream,” said Natalie Batalha, an astronomer at NASA’s Ames research center. “Its something we can accomplish—maybe not within my lifetime, maybe within my daughter’s life.”

Batalha’s sentiment was echoed last Saturday by the men and women who spoke at the opening ceremony of the Carl Sagan Institute at Cornell University. The institute, brainchild of astronomer Lisa Kaltenegger, was founded to explore the diversity of worlds we’ve just begun to glimpse on the cosmic horizon. If we’re lucky, we may find another planet like Earth. Or a dozen. Or a thousand.

“How do you figure out if a world orbiting another star is a habitable place?” Kaltenegger said. “We’re living in the first time in history that we have the tools to answer that question.”

Finding Earth 2.0 won’t be easy. It’ll be an enormous effort, but the astronomers, planetary
scientists, chemists and biologists leading the Carl Sagan Institute have a plan to get us there. Here’s how we’re trying to find the next pale blue dot and an end to our cosmic loneliness.

Billions and Billions
It’s a great time to be alive if you’re interested in worlds beyond our solar system. Over the past two decades, exoplanet science has undergone nothing short of a revolution, and even if you’re skeptical about the idea of alien life, the discoveries we’ve made are damn impressive.

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Consider the numbers: Twenty years ago, astronomers hadn’t confirmed a single planet outside our solar system. In the past six years, NASA’s Kepler mission—a space-based telescope that orbits our sun, looking at over 100 thousand stars simultaneously—has uncovered over 4100 planetary candidates and 1000 confirmed planets. Kepler is not scanning the whole sky. Rather, the scope monitors a tiny sliver of our galaxy, taking a cosmic census of sorts. With this census, astronomers have used statistics to extrapolate the distribution of planets throughout the Milky Way.

“We have learned most stars have planets, that Earth sized planets are common, and a good fraction are in the habitable zone of their star,” said Bill Borucki, the lead investigator for the Kepler mission. “And when you put the numbers together: 100 billion stars, 10 percent with Earth-sized planets, 10 percent stars like the sun, that’s a billion Earth-sized planets in the habitable zone of stars like the sun.”

Let me repeat that last bit. There may be a billion Earth-sized planets in the habitable zone of a sun-like star. Thirty years ago, astronomers weren’t sure of any. And that, of course, is just within our galaxy.

“There are billions of stars in our galaxy alone, billions of galaxies out there,” Kaltenegger said. “The numbers are, fortunately, very much in our favor.”

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The technology behind this incredible discovery is in principle quite simple. Most exoplanets to date have been detected via transit—a slight dip in the light emitted from a star as a planet crosses its path within the line of sight of a telescope. In practice, however, pinpointing these planetary shadows is insanely hard, because the brief change in starlight caused by a transit event is utterly miniscule.

“Imagine you’re looking at the tallest skyscraper in New York City, and it’s nighttime,” Batalha said. “Every single window is open and every light is on. One person goes and lowers the blinds on one window by about a centimeter. That’s the change in light you have to measure to find an Earth-sized planet.”

And you need to do so at least twice, to be sure you didn’t just make it up.


For transit to work, we’ve had to develop photometers a thousand times more precise than any built before. As Borucki explained, these light sensors must monitor thousands of stars at once, because the chance a planet lines up in the path of a star in a telescope’s line of sight is less than 1 percent. The scope’s photometer also has to remain perfectly still at all times—not anchored to the ground, but in outer space.

And for how ambitious those specifications are—it took Borucki nearly two decades to design, prototype, and convince NASA to green-light Kepler—all that transit gives us is a planet’s radius, orbital period, and sometimes its mass. And so far, only for worlds that are at Earth’s orbital distance or inward. (The transit of more distant planets is too faint for Kepler’s photometer to detect.) Through mass and radius we can calculate planetary density, which tells us whether we’re looking at a rocky, Earth-like world or a Jupiter-like ball of gas.

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So far, the galaxy has been full of surprises. Many stars harbor large worlds orbiting far closer than Mercury, a situation which was considered nigh impossible thirty years ago. The two most common types of planets known to humanity right now—so called “super Earths” and “mini-Neptunes”—are not even represented in our solar system. We have hints of incredibly bizarre places out there, of gas giants as light as styrofoam, of ocean worlds and lava planets.

“There are planets orbiting binary stars, that have not one sun rising in the east and setting in the west but two,” said Batalha. “We find planets in star clusters, with 25 stars packed into a single cubic parsec of space. On these planets, you’d be look up and see a bejeweled sky.”

“There’s an incredibly wondrous diversity of worlds out there, and we haven’t even started to scratch the surface,” Kaltenegger said.

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Scattered amongst these exotic worlds, we’ve also found a handful of “Goldilocks” planets—worlds that are not-too-hot and not-too cold, that are rocky, that are orbiting stars like our sun. Worlds that could be the next Earth.

“These [potentially habitable] planets are relatively common, and using statistics, we know they’re likely to be nearby,” Batalha said.

Still, for a world to go from potentially habitable to a bonafide Earth, we’ll need to get a much better look at it. That’s exactly what we’re hoping to do with the next generation of scopes. With future missions, we’ll look not only look at the ebb and flow of light from distant stars, but at the atmospheres of planets themselves. From light years away, our scopes will effectively sample the air of other worlds.

When that happens, astronomers across the world will become alien hunters.

Hunting for Goldilocks
Earth may be a cozy blue marble today, but it wasn’t always sunshine and roses. Four billion years ago, our planet’s rocky surface was erupting in fiery volcanoes, bombarded with comets and asteroids, awash in sterilizing UV radiation, and contained practically no oxygen, to boot.

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It was life that terraformed the Earth—early, hardy colonizers that, over the course of billions of years, turned a rocky wasteland into a comfortable, breathable biosphere. Ancient cyanobacteria were probably the first to produce significant amounts of oxygen as a waste product from photosynthesis. Today, our air contains a healthy supply of O2, replenished constantly by Earth’s plant life and phytoplankton, as well as a thin layer of ozone, which shields us from damaging ultraviolet radiation. Earth’s atmosphere also contains trace amounts of reducing gases —things like CO2 and methane—replenished by the collective exhale of life’s metabolism, and, recently, by the burning of fossil fuels.

Taken alone, oxygen or methane don’t make a strong case for life—both can be produced by inorganic chemical reactions. But put them together, sprinkle in a little water, and it’s a different story.

“Our best signature [for life] to date is the combination of oxygen or ozone with a reducing gas—something that should make oxygen go away,” Kaltenegger told me.“A lot of the things that are biological, like methane alone, or CO2 alone, can also come from rocks, so we can’t just use those. But if oxygen is found together with methane, then something has to be producing it in large amounts right now.”

So, our alien hunters already have some promising fingerprints in mind. Find these ingredients in the atmosphere of a Goldilocks planet circling sun-like star, and we may just have ourselves another Earth. Now how the hell do we go about searching?

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Through a pipeline of future space missions, beginning with the Transit Exoplanet Survey Satellite (TESS), which launches in 2017. While most of Kepler’s targets were 500-1,000 light years away, TESS is going to be our friendly neighborhood planet hunter—it’ll scan the entire sky, monitoring more than half a million stars in our very close cosmic vicinity.

“TESS will be like Kepler, just doing transit, but instead of staring at one particular part of sky, it’ll scan the entire sky, focusing on our nearest neighbors,” Kaltenegger told me. “It’ll allow us to pick a lot of promising targets that are much closer than the Kepler planets.”

TESS may turn up many hopeful candidates, but it won’t be studying their atmospheres. That process starts gearing up with the James Webb Space Telescope, a 6.5 meter-long solar-powered observatory slated to launch in 2018. With unprecedented detection power, JWST will become the premier observatory of the next decade. Its sensitivity comes in part from a massive sunshield that chills the scope’s instruments to below -370 degrees Fahrenheit. At such low temperatures, the JWST itself emits very little radiation, allowing for the detection of faint energy signatures from far away—including slight dips in the light emitted from a distant star as it filters through a planet’s atmosphere.

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“You take that planet, that one tiny pixel, and you split the light,” Kaltenegger said. “You look at the different colors—basically what happens when sunlight passes through a raindrop and makes a rainbow—and if energy is missing, you can pinpoint, over light years away, what chemicals molecules are there, in the air of that world.”

But. Impressive as JWST will be, this scope still won’t be powerful enough to study many rocky, Earth-like planets. (If, Kaltenegger says, we find a rocky super-Earth around a dim red dwarf very close by, we may have a chance of looking at its atmosphere.) JWST’s eyes will be fixed on mostly larger worlds—and these will typically be blustery blobs of gas.

“JWST is going to knock it out of the ballpark for mini-Neptunes and super Earths, it’s going to understand the diversity of their atmospheres, but its not tailored to find Earth-sized planets,” Batalha said.

Next up after JWST is the Wide Field Infrared Survey Telescope (WFIRST), a retrofitted spy scope that, using a technique called microlensing, will have the sensitivity to detect smaller than Earth-sized planets orbiting at distances beyond 1 AU (the distance between Earth and the Sun). Using a starlight-blocking coronagraph, WFIRST will also be able to directly see reflected light from some larger planets.

“Kepler is getting the statistics of exoplanets within an Earth orbit and inward,” Batalha said. “WFIRST is going to get the statistics of planets orbiting at an Earth orbit or outward. So, over time, we’re going to build up this comprehensive picture of what exoplanets are out there.”

And once WFIRST launches in the mid-2020’s, space agencies finally plan to double down on a “life finder” mission. It’s this future mission which we’re hoping has the power to decode the atmospheres of many rocky, Earth-sized planets orbiting stars throughout our stellar neighborhood.

“Between now and the life finder, we’re not going to find nearby Earths in great numbers,” Batalha said. “But as long as we’re well positioned by 2025 to start putting money into a life finder, then I think we’ll have a hope of really making headway in three decades.”

Three decades till we’ve got a good chance of finding the next Earth seems to be the ballpark most exoplanet hunters are comfortable with. But if Earths turn out to be very common, we may get lucky and find ourselves a neighbor sooner.

“TESS is going to find a few dozen planets that are small enough, rocky, within the right distance to their star,” Kaltenegger said. “Then we’ll have a list of the closest promising worlds that we can put all of our telescopes on and observe night after night. It’s going to be crazy how much work it’ll be, but it’s also going to be an incredible opportunity.”

How We’ll Know It When We See It
It may take several decades for the technology needed to spot Earth 2.0 to come online. But astronomers aren’t just twiddling their thumbs waiting.

“We want to be as prepared as we can by asking the question now: among the thousands of worlds, among the dozens that are close by, which ones will we want to pick?” Kaltenegger said. “Combining what we know about life on the Earth with astronomy is one of the strongest ways to do that.”

At the Carl Sagan Institute, Kaltenegger and her colleagues are amassing troves of information that will help alien hunters hone in on the most promising candidate worlds. These include afingerprint database containing hundreds of hypothetical atmospheric chemistries—some that look like our Earth today, some that look like Earth’s geologic past, others which are totally alien. The database, which Kaltenegger once described to me as “CSI for exoplanets” will be used to categorize distant worlds and rank them in terms of how Earth-like they are.

1256279949922600038.jpg


A color catalog will help us search for an entirely different type of fingerprint. Just as Earth’s green landscapes and blue oceans hint at life’s presence, the vibrant biota on distant worlds might offer telltale clues. In a study published in March, researchers examined over 100 microorganisms across planet Earth, including many that live in extreme environs, and documented their reflection signatures. The diversity of colors represented in these critters will help alien hunters imagine what life might look like and how we might detect it beyond the pale blue dot.

“If a world had a different biota than what is dominant here, it would look different,” Kaltenegger said. “If you think about this in colors—how does a world look in the blue, red and green—the different surfaces would appear different colors. And that’s what you could use to prioritize which planets look more like they could host life.

Right now, in this time, with thousands of planets on the horizon, and new missions coming up in the next five to ten years—now is when we need to understand what we could be finding and how we could find it.”

Once We Find It, Then What?
It’s incredible to consider the possibility of finding a second Earth. But even definitive proof of life on another world won’t eliminate our desire to explore. Quite the opposite.

Which brings me to a question posed at the very end of the Carl Sagan Institute inaugural ceremony, to a panel full of astronomers, astrobiologists and planet hunters. Say we find another Earth. Say it’s close—a couple light years or so from our solar system. Then what?

The resounding response was exactly what any science fiction fan would have hoped to hear. We have try to get there.

“If somebody finds a real Earth-like planet within a few light years, my reaction is, lets start building a spacecraft,” said Cornell astronomer Steve Squyres, the lead investigator on the Mars Exploration Rover.

“Look,” said Didier Queloz, an exoplanet researcher at the University of Cambridge, “it took the human species ten thousand years to spread across the Earth. When I came here, it took me eight hours by plane to cross the Atlantic ocean. Maybe we need another hundred, or a thousand years, but it doesn’t seem so crazy to think we’ll be sending probes to these nearby planets. There is no fundamental limitation but the time.”

Batalha agrees. “Once we know that there’s life—once we can point to a star in the sky and say there’s life there—I personally think we’re going to figure out how to get to it.”

A manned interstellar voyage would almost certainly be a multigenerational trip. In a world that seems increasingly obsessed with instant gratification, it can be hard to imagine people sacrificing their lives for a journey they’d never see the end of. And yet, as Ann Druyan, co-writer and producer of Cosmos pointed out, everyone involved with exoplanet discovery today is a multigenerational thinker.

“Only seventy five to eighty years ago, the notion that there were other worlds circling stars was not even, scientifically, a respectable position to take,” she said. “And here we are today, engaged in multigenerational projects.”

“Look at cathedrals,” Queloz said. “Most people who first built them didn’t think they’d see the end. I think we’re building cathedrals—science is a modern way of expressing that. I think as a species, we’re used to working together, teaming together, and it’s in our genes to do this.”

:usflag::usflag::usflag:
Svenny boy, pat your back you've been posting some awesome stuff these days.:tup::tup::tup:
what about your thread on micro stories???
 
.
. . .
Inside New York’s Newest Architectural Masterpiece for the Mega-Rich

$70 million might net you the duplex penthouse of 53W53, Jean Nouvel’s MoMA Tower

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The newest condominium tower in midtown Manhattan's billionaires district is ready to open its doors to buyers. It took almost a decade to get there.

The skyscraper at 53 W. 53rd St., designed by French architect Jean Nouvel and rising next to the Museum of Modern Art, will start marketing its 139 apartments next week, with prices starting at $3 million. Planned since 2006, the project endured the real estate bust and a global financial crisis that decimated demand for luxury homes. Now it's emerging when buyers can't seem to get enough of them.

"We're very eager to begin,'' said David Penick, the New York-based managing director for developer Hines, which is building the project with Goldman Sachs Group and Singapore-based Pontiac Land Group. "We're confident in what we have to sell in the market we're in, and we'll see how it goes.''

The project's latest challenge: competing for buyers with about a half-dozen other luxury condo towers that are under construction nearby. The developments—including Vornado Realty Trust's 220 Central Park South and Aby Rosen's 100 E. 53rd St.—are transforming Midtown neighborhoods known for hotels and corporate offices into communities of wealthy people from around the world who are hungry for large living spaces and panoramic views.

It would certainly be better if there weren't so many new buildings coming on the market right now,'' Penick says at the Fifth Avenue sales gallery for the project, known as 53W53. "But I think we have a uniquely attractive package to offer."

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Diagonal Beams
The 1,050-foot (320-meter) tower, the size of the Chrysler Building, will rise near the corner of Sixth Avenue between 53rd and 54th streets, on land once owned by the adjacent museum. MoMA will expand its galleries in the bottom three floors of the residential building, whose signature architectural flourish is a web of diagonal concrete beams that gird the structure from the outside before tapering into a pinnacle more than 82 stories into the sky.

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"It is the flag—not only of the building—but the flag of the MoMA on the skyline,'' says Nouvel, who also designed a Ferrari factory in Italy, an art museum in Abu Dhabi, and a23-story condo building near Manhattan's Chelsea waterfront.

Unobstructed views of Central Park, five blocks away, start on the 48th story, which is where the building's larger half-floor units also begin, according to Penick and preliminary plans filed with the New York state attorney general's office. The most expensive apartment, a 6,643-square-foot (617-square-meter) duplex spanning the 81st and 82nd floors, will be priced at more than $70 million, Penick says.

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Skyline Views
Smaller one- and two-bedroom units on the lower floors will have views of the Midtown skyline. The least-expensive condo is a one-bedroom of about 1,450 sq. ft. on the 17th floor; it will be listed for sale at $3 million, according to Penick.

"It's not immediately on the park, so the apartments in the lower part of the building, we think, would sell better if they were not so large,'' says Penick. "Very intentionally, we sought to have a range in unit sizes."

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Every apartment is shaped a little differently because the building's exterior support beams cross the floor-to-ceiling windows at various angles, Nouvel said. It made for an interesting design challenge.

"We tried to do a kind of dialogue with the views and with the buildings around,'' he says. "You frame it with different shapes in the city and the neighboring buildings."

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Wine Vaults
Amenities at the tower include a movie theater, a private dining room overlooking Central Park, and temperature-controlled wine vaults. Residents can buy studio apartments on the 14th through 16th floors for their personal service staff.

The project was conceived in 2006, before Houston-based Hines acquired the site from the museum for $126 million. The tower—initially planned to be 200 feet taller, about the height of the Empire State Building—was shelved amid the credit crisis, which brought property sales to a near standstill and made construction financing scarce.

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In 2013, closely held Pontiac Land Group helped revive the project with a $200 million equity investment. A consortium of Asian banks provided $860 million of construction financing. Hines expects to finish construction by November 2018.

Manhattan's luxury property market has soared in recent years, with wealthy investors paying ever-higher prices for trophy homes. A duplex atop Extell Development's One57 tower sold in December for $100.5 million, a New York City record. A penthouse at Macklowe Properties and CIM Group's 432 Park Ave., the tallest residential building in the Western hemisphere at 1,397 feet, is under contract for $95 million.

While plans for 53W53 predate those transactions, the developers always intended the project to be in an elite sliver of Manhattan's luxury market, Penick says.

"The basic strategy hasn't really changed,'' he says. "It's a very attractive location adjoining the Museum of Modern Art. We always knew that it would be high end.''

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From MoMA Tower's $70 Million Duplex Newest Addition to NYC Skyline - Bloomberg Business
 
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The US Is Testing a Storm Surge Warning System for Hurricanes

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The wall of wind-driven ocean that accompanies a hurricane is called a “surge” for a reason: This isn’t a gentle rising of the water level, it’s violent and destructive—sometimes more so than the hurricane’s winds. This hurricane season, for the first time, the National Hurricane Center will be testing a prototype storm surge warning system which it hopes will be fully operational in 2017.

The National Weather Service already issues watches and warnings for hurricanes and tropical storms, but those are based on the odds of a storm making landfall with strong enough winds to qualify it for a place on the Saffir-Simpson scale—the familiar Category 1 to Category 5 ranking system for hurricanes. The Saffir-Simpson scale is based entirely on wind speed; any storm with winds of 74 to 95 mph is a tropical storm, and any storm with winds over 95 mph is a hurricane.

But high winds are only one of the ways a hurricane can wreck everything in its path. Hurricane winds push water into a big pile ahead of the storm, and as the hurricane moves toward landfall, it drives the sea toward the shore as well.

Once the storm surge warning is in place, the new system will give the National Weather Service the ability to issue storm surge watches and warnings to coastal areas threatened by approaching hurricanes. That’s very good news for people who live there. Right now, the Saffir-Simpson scale doesn’t convey any information about potential storm surges at all.

A Lesson From Hurricane Ike

When Hurricane Ike made landfall on Galveston Island, Texas in 2008, it was only a Category 2 storm, but it packed a devastating storm surge. The storm’s sheer size meant that 12 to 16 feet of water swept across Bolivar Peninsula, destroying almost 90 percent of the homes in the communities there.

Then the storm surge picked up the broken remains of many of those homes and washed them across the eastern arm of the bay, where 10 to 20 feet of water, laden with debris from Bolivar Peninsula, washed over the cattle-grazing land. When the water receded, it left lines of debris that stretched for miles across the muddy cattle fields.

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Meteorologists later said that Ike’s storm surge had been closer to what they would expect from a Category 4 storm, but the fact is that the Saffir-Simpson scale just doesn’t give forecasters, emergency managers, or coastal residents a good way to predict storm surge. It had been on the table since at least 2005, but Ike drew attention to the need for a better watch and warning system for storm surges.

After Hurricane Katrina in 2005, focus began to shift to storm surge predictions and warnings, according to Phil Klotzbach of Colorado State University’s Tropical Meteorology Project. “Prior to 2004/2005, it seemed like the focus was on the wind hazard (e.g., Hurricane Andrew in 1992) and the inland rainfall hazard (Dennis and Floyd, 1999),” he wrote in an email.

“We knew, more than 10 years ago, that there was a need for a storm surge watch and warning out there,” Brian Zachry, PhD, meteorologist and storm surge expert at the National Hurricane Center, told Gizmodo. But developing a way to predict storm surge and issue advisories about it would require time, effort, and resources. Then Ike, in 2008, drove home the need for storm surge watches and warnings.

Zachry explains: “About 24 hours before landfall, long before the winds started coming up to hurricane strength, the storm surge was already inundating Bolivar Peninsula and Galveston Island. So we really didn’t, at that point, have a watch and warning that we could put out well ahead of time, because the winds weren’t even there yet.”

In 2012, Hurricane Sandy provided another impetus to develop a warning system for storm surge, separate from the Saffir-Simpson scale based on wind speed. After the storm, the National Hurricane Center received supplemental funding to work on the problem.

A Prototype Warning System

Last year, as Hurricane Arthur approached the North Carolina coast, the National Hurricane Center released a prototype of a potential storm surge flooding map. The map showed how much flooding forecasters expected to see along the coastline, in three-foot increments. It wasn’t a formal watch or warning, but it gave local governments and residents a much clearer idea of what was coming.

The National Hurricane Center created the maps based on probabilistic data, taking into account every possible change in direction, size, speed, or intensity before the storm makes landfall. These can be created for each storm, said Zachry. “We’re doing potentially five to ten thousand different storm surge simulations to come up with different possible scenarios.”

The maps were a good tool, especially for the public, according to Klotzbach. “I also really like that they have the new surge maps displayed relative to ground level at your location. That is a simple benchmark that the general public can easily understand,” he said.

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The prototype watch and warning map will be available on the National Hurricane Center’s website, where it will be accessible to the public, media, and local weather forecasters. Zachry said that it may be picked up by local news stations or even the Weather Channel, which used the prototype flooding map last year during Hurricane Arthur. It won’t yet be an official National Weather Service warning, though.

This season, Zachry and his colleagues hope to get feedback from local forecasters and emergency managers. “We can test how we would create a watch and warning for past storms. We’ve done that many, many times now—we’ve worked on that a lot. But we really need to go through a season, talk with emergency managers and local weather forecasters, to see how this watch and warning for storm surge will work during a storm,” he said. “The only way to get feedback is during a season.”

Based on this year’s feedback, the National Hurricane Center will make improvements and release an updated prototype next year. They’ll get make more improvements, and by 2017, the National Weather Service will begin issuing official storm surge watches and warnings, accompanied by flood prediction maps.

And hopefully, coastal residents will heed those warnings.
 
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Nebraska lawmakers vote to abolish death penalty

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Nebraska lawmakers gave final approval on Wednesday to a bill abolishing the death penalty with enough votes to override a promised veto from Republican Gov. Pete Ricketts.

The vote was 32 to 15 in Nebraska's unicameral Legislature.

If that vote holds in a veto override, Nebraska would become the first conservative state to repeal the death penalty since North Dakota in 1973.

The Nebraska vote is notable in the national debate over capital punishment because it was bolstered by conservatives who oppose the death penalty for religious reasons and say it is a waste of taxpayer money.

Nebraska hasn't executed a prisoner since 1997, and some lawmakers have argued that constant legal challenges will prevent the state from doing so again.

Republican Gov. Pete Ricketts, a death penalty supporter, has vowed to veto the bill. Ricketts announced last week that the state has bought new lethal injection drugs to resume executions.

Ricketts, who is serving his first year in office, argued in his weekly column Tuesday that the state's inability to carry out executions was a "management problem" that he is committed to fixing.

Maryland was the last state to end capital punishment, in 2013. Three other moderate to liberal states have done so in recent years: New Mexico in 2009, Illinois in 2011, Connecticut in 2012. The death penalty is legal in 32 states, including Nebraska.

Independent Sen. Ernie Chambers of Omaha, who sponsored the Nebraska legislation, has fought for four decades to end capital punishment in the state.

Nebraska lawmakers passed a death-penalty repeal bill once before, in 1979, but it was vetoed by then-Gov. Charles Thone.
 
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