How Close Are We to Kubrick's AI-Controlled Vision of the Future?

21-10-2018 om 00:20 geschreven door peter

Why Haven't We Found Aliens? Because We're Just Not Looking Hard Enough.

21-10-2018 om 00:09 geschreven door peter

Gas giants orbiting young star may require astronomers to rethink planetary formation

BY TIBI PUIU

Illustration of CI Tau, which is surrounded by a planetary disc and has four gas giants orbiting around it.

Credit: University of Cambridge.

Astronomers have discovered a peculiar solar system some 500 light-years away from Earth that may force them to rethink how planets form. The star in question is only two million years old — a mere ‘toddler’ by astronomical standards — but despite its very young age, it’s orbited by four Jupiter and Saturn-sized planets.

A crowded baby star

Since the first confirmation of an exoplanet orbiting a sun-like star in 1995, and with only a few narrow slices of our Milky Way galaxy surveyed so far, astronomers have confirmed 2,327 exoplanets, with a further 2,244 awaiting confirmation.

A recent statistical estimate places, on average, at least one planet around every star in the galaxy. However, only 1% of the stars astronomers have surveyed so far host a hot Jupiter — a class of gas giant exoplanets that are inferred to be physically similar to Jupiter but that have a very short orbital period.

Most of the hot Jupiters currently identified orbit stars that are at least hundreds of millions of years old. This is why CI Tau, the young star recently studied by researchers at the University of Cambridge, is so interesting. What’s more, it has not one but four gas giants orbiting it.

The astronomers used Atacama Large Millimeter/submillimeter Array (ALMA) to identify the exoplanets. CI Tau is surrounded by a huge disc of dust and ice, known as a protoplanetary disc, which will seed planets, moons, asteroids, and other objects in its system. ALMA’s instruments were able to find distinct gaps in the disc which theoretical modeling showed would correspond to gas giant planets orbiting the star.

According to the new study published the Astrophysical Journal Letters, the four planets differ greatly in their orbit. The closest planet to CI Tau, a juvenile hot Jupiter, is within the equivalent orbit of Mercury.

The farthest orbits are at a distance three times greater than that of Neptune from the Sun. The two outer planets are about the mass of Saturn, while the two inner planets are around one and 10 times the mass of Jupiter respectively. Given that the outermost planet is more than a thousand times further from the star than the innermost one, the system has also set a new record for the most extreme range of orbits observed so far.

Scientists are not sure what to make of this anomalous system. Hot Jupiters have always puzzled astronomers because they are often thought to orbit too close to their parent stars to have formed in situ — instead, they might be captured rogue planets. But considering the age of CI Tau, the findings suggest that hot Jupiters could form within close proximity of a star.

“It is currently impossible to say whether the extreme planetary architecture seen in CI Tau is common in hot Jupiter systems because the way that these sibling planets were detected—through their effect on the protoplanetary disc – would not work in older systems which no longer have a protoplanetary disc,” said Professor Cathie Clarke from Cambridge’s Institute of Astronomy, the study’s first author.

In the future, the team of researchers plans on studying CI Tau at multiple wavelengths to learn more about the disc and its planets. For instance, they would like to see whether the outer planets played a role in driving their innermost sibling into such an ultra-close orbit. How the two outer planets formed in the first place is also a mystery.

“Planet formation models tend to focus on being able to make the types of planets that have been observed already, so new discoveries don’t necessarily fit the models,” said Clarke. “Saturn mass planets are supposed to form by first accumulating a solid core and then pulling in a layer of gas on top, but these processes are supposed to be very slow at large distances from the star. Most models will struggle to make planets of this mass at this distance.”

{ https://www.zmescience.com/ }

20-10-2018 om 23:36 geschreven door peter

There are plans to cause HAVOC on Venus.

NASA wants to send humans to Venus – here’s why that’s a brilliant idea

Popular science fiction of the early 20th century depicted Venus as some kind of wonderland of pleasantly warm temperatures, forests, swamps and even dinosaurs. In 1950, the Hayden Planetarium at the American Natural History Museum were soliciting reservations for the first space tourism mission, well before the modern era of Blue Origins, SpaceX and Virgin Galactic. All you had to do was supply your address and tick the box for your preferred destination, which included Venus.

Today, Venus is unlikely to be a dream destination for aspiring space tourists. As revealed by numerous missions in the last few decades, rather than being a paradise, the planet is a hellish world of infernal temperatures, a corrosive toxic atmosphere and crushing pressures at the surface. Despite this, NASA is currently working on a conceptual manned mission to Venus, named the High Altitude Venus Operational Concept – (HAVOC).

But how is such a mission even possible? Temperatures on the planet’s surface (about 460°C) are in fact hotter than Mercury, even though Venus is roughly double the distance from the sun. This is higher than the melting point of many metals including bismuth and lead, which may even fall as “snow” onto the higher mountain peaks. The surface is a barren rocky landscape consisting of vast plains of basaltic rock dotted with volcanic features, and several continent-scale mountainous regions.

It is also geologically young, having undergone catastrophic resurfacing events. Such extreme events are caused by the build up of heat below the surface, eventually causing it to melt, release heat and re-solidify. Certainly a scary prospect for any visitors.

Hovering in the atmosphere

Luckily, the idea behind NASA’s new mission is not to land people on the inhospitable surface, but to use the dense atmosphere as a base for exploration. No actual date for a HAVOC type mission has been publicly announced yet. This mission is a long term plan and will rely on small test missions to be successful first. Such a mission is actually possible, right now, with current technology. The plan is to use airships which can stay aloft in the upper atmosphere for extended periods of time.

As surprising as it may seem, the upper atmosphere of Venus is the most Earth-like location in the solar system. Between altitudes of 50km and 60km, the pressure and temperature can be compared to regions of the Earth’s lower atmosphere. The atmospheric pressure in the Venusian atmosphere at 55km is about half that of the pressure at sea level on Earth. In fact you would be fine without a pressure suit, as this is roughly equivalent to the air pressure you would encounter at the summit of Mount Kilimanjaro. Nor would you need to insulate yourself as the temperature here ranges between 20°C and 30°C.

The atmosphere above this altitude is also dense enough to protect astronauts from ionising radiation from space. The closer proximity of the sun provides an even greater abundance of available solar radiation than on Earth, which can be used to generate power (approximately 1.4 times greater).

The conceptual airship would float around the planet, being blown by the wind. It could, usefully, be filled with a breathable gas mixture such as oxygen and nitrogen, providing buoyancy. This is possible because breathable air is less dense than the Venusian atmosphere and, as result, would be a lifting gas.

The Venusian atmosphere is comprised of 97% carbon dioxide, about 3% nitrogen and trace amounts of other gases. It famously contains a sprinkling of sulphuric acid which forms dense clouds and is a major contributor to its visible brightness when viewed from Earth. In fact the planet reflects some 75% of the light that falls onto it from the sun. This highly reflective cloud layer exists between 45km and 65km, with a haze of sulphuric acid droplets underneath down to about 30km. As such, an airship design would need to be resistant to the corrosive effect of this acid.

Luckily we already have the technology required to overcome the problem of acidity. Several commercially available materials, including teflon and a number of plastics, have a high acidic resistance and could be used for the outer envelope of the airship. Considering all these factors, conceivably you could go for a walk on a platform outside the airship, carrying only your air supply and wearing a chemical hazard suit.

Life on Venus?

The surface of Venus has been mapped from orbit by radar on the US Magellan mission. However, only a few locations on the surface have ever been visited, by the series of Venera missions of Soviet probes in the late 1970s. These probes returned the first – and so far only – images of the Venusian surface. Certainly surface conditions seem utterly inhospitable to any kind of life.

The upper atmosphere is a different story however. Certain kinds of extremophile organisms already exist on Earth which could withstand the conditions in the atmosphere at the altitude at which HAVOC would fly. Species such as Acidianus infernus can be found in highly acidic volcanic lakes in Iceland and Italy. Airborne microbes have also been found to exist in Earth’s clouds. None of this proves that life exists in the Venusian atmosphere, but it is a possibility that could be investigated by a mission like HAVOC.

The current climatic conditions and composition of the atmosphere are the result of a runaway greenhouse effect (an extreme greenhouse effectthat cannot be reversed), which transformed the planet from a hospitable Earth-like “twin” world in its early history. While we do not currently expect Earth to undergo a similarly extreme scenario, it does demonstrate that dramatic changes to a planetary climate can happen when certain physical conditions arise.

By testing our current climate models using the extremes seen on Venus we can more accurately determine how various climate forcing effects can lead to dramatic changes. Venus therefore provides us with a means to test the extremes of our current climate modelling, with all the inherent implications for the ecological health of our own planet.

We still know relatively little about Venus, despite it being our nearest planetary neighbour. Ultimately, learning how two very similar planets can have such different pasts will help us understand the evolution of the solar system and perhaps even that of other star systems.

{ https://theconversation.com/uk }

20-10-2018 om 23:09 geschreven door peter

Mysterious Signals at the Center of Our Galaxy May Be an Optical Illusion

20-10-2018 om 22:52 geschreven door peter

'Roswell, New Mexico' Series Has a Fresh Take on Themes in the Original Alien Drama

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Roswell, New Mexico

✔@CWRoswellNM

#Roswell, New Mexico is coming soon to The CW.

6:37 PM - May 17, 2018

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20-10-2018 om 21:55 geschreven door peter

{ https://www.ancient-origins.net/ }

20-10-2018 om 01:00 geschreven door peter

New study confirms that Earth’s inner core is solid

BY MIHAI ANDREI 

A new study has sent ripples throughout the seismological world — a team of researchers from the Australian National University have found a new way to confirm that the Earth’s core is solid.

A simplified schematic of the Earth’s structure.

If you think about it, the very fact that we know so much about the Earth’s interior is stunning. The deepest hole we’ve dug is “only” around 12 km deep, whereas the radius of our planet is 6378 km — so how could we know so much about the Earth’s structure?

Seismic waves

Scientists use many bits and pieces of information to study this structure, but the most important clues come from seismic waves. Whenever an earthquake takes place, it sends out pressure waves in all directions — much like the acoustic waves we use to speak and hear sounds. These waves propagate through the subsurface, reflecting and refracting as they move from one environment to the other. Eventually, they reach the surface, where they are picked up by seismographs — devices that measure the movement of the earth.

Using seismographs, researchers can infer a surprisingly large amount of information. For instance, by measuring the arrival time of seismic waves at different seismograph stations, the position of the earthquakes’ epicentres can be triangulated — this is how we know where earthquakes happen.

But that’s just the start of it.

A typical seismogram.

More than just data about the earthquake itself, we can derive data about the rocks through which the seismic wave has traveled. For instance, generally speaking, there are three types of seismic waves:

• P or Primary waves, which are longitudinal waves (these are the fastest and the first to arrive);
• S or Secondary waves, which are shear waves; and
• Surface waves, which are slower than both P and S waves, but have larger amplitude and more complex movements.

A simple simulation of an S wave structure.

P waves travel through any type of medium, whereas S waves only move through solid environments — not liquid. This was a huge indication that the Earth’s outer core is a liquid, as S waves don’t appear to pass through it. It’s not a liquid in a conventional sense (think of it more like viscous, molten lava, or thick honey), but it’s definitely not a solid.

A depiction of different seismic waves propagating through the Earth.

This also revealed that the inner core is solid, as S waves appear to be able to pass through it. However, the small size of the inner core makes detecting shear waves very difficult, and this theory could still use additional verification. This is where the new study comes in.

J waves

A J wave is nothing more than an S wave that passes through the inner core — seismologists love giving different names to waves depending on where they pass through, but don’t let it confuse you, it’s still a shear, S wave.

J waves are rather elusive because they have small amplitudes, and the Earth’s inner core has a relatively small volume, which means that many seismic waves simply go around it. The small, feeble amplitude is so problematic that detecting J-waves has sometimes been referred to as the “Holy Grail” of global seismology.

However, Associate Professor Hrvoje Tkalčić and PhD Scholar Than-Son Phạm believe they’ve found a new way to identify J waves. What they did is pretty creative: instead of looking directly at the wave as it comes, they simply ignore it for the most part and look at the wave signal hours after the largest rumbles have passed. By studying the similarities between these signals at two receivers after a major earthquake, they’re able to observe a correlation of patterns, and this correlation is the key to the J-wave identification. A similar approach was used by other scientists to study the thickness of Antarctic ice.

“Using a global network of stations, we take every single receiver pair and every single large earthquake – that’s many combinations – and we measure the similarity between the seismograms,” lead author Hrvoje Tkalčić explained.

“That’s called cross correlation, or the measure of similarity. From those similarities we construct a global correlogram – a sort of fingerprint of the Earth.”

“We’re throwing away the first three hours of the seismogram and what we’re looking at is between three and 10 hours after a large earthquake happens. We want to get rid of the big signals,” Dr. Tkalčic added.

Using this approach, they confirmed that the inner core seems indeed solid, though it seems to exhibit some differences from current models. In fact, it’s a bit like two very familiar materials: gold and platinum.

“We found the inner core is indeed solid, but we also found that it’s softer than previously thought,” Associate Professor Tkalčić said.

“It turns out – if our results are correct – the inner core shares some similar elastic properties with gold and platinum. The inner core is like a time capsule, if we understand it we’ll understand how the planet was formed, and how it evolves.”

We should still wait for additional observations to confirm this study but, for now, it seems like the information about the nature of the inner core is becoming more and more solid.

• This research was published in Science.

{ https://www.zmescience.com/ }

20-10-2018 om 00:35 geschreven door peter

China Will Have An Artificial Moon In 2 Years

Artificial moon instead of street lamps?

In 2020, China plans to send an artificial moon into space to replace street lighting. It is an earth satellite that will reflect sunlight and be about nine times brighter than the moon.

As the authors of the project, including the Institute of Space Microelectronics, claim, it will be possible to regulate the illumination zone on the Earth's surface - the light field will vary between 10 and 80 kilometers.

According to experts, neither humans nor animals perceive artificial moonlight as a disturbance because it will be similar to dusk.

The main challenges in creating an artificial moon are the cost of the project and the technical problems of launching mirrors into orbit and assembling them in the midst of space debris.

READ NEXT

• Australien Telescopes Doubles The Number Of Mysterious Alien Signals

{ https://www.disclose.tv/ }

19-10-2018 om 01:45 geschreven door peter

19-10-2018 om 01:13 geschreven door peter

X-37B Military Space Plane Wings Past 400 Days on Latest Mystery Mission

Flight duration

Each X-37B/OTV mission has set a new flight-duration record for the program:

• OTV-1 began April 22, 2010, and concluded on Dec. 3, 2010, after 224 days in orbit.
• OTV-2 began March 5, 2011, and concluded on June 16, 2012, after 468 days on orbit.
• OTV-3 chalked up nearly 675 days in orbit before finally coming down on Oct. 17, 2014.
• OTV-4 conducted on-orbit experiments for 718 days during its mission, extending the total number of days spent in space for the OTV program at that point to 2,085 days.

What's up?

Most X-37B payloads and activities are classified. The only OTV-5 payload revealed to date by Air Force officials is the Advanced Structurally Embedded Thermal Spreader, or ASETS-II.

Developed by the U.S. Air Force Research Laboratory (AFRL), this cargo is testing experimental electronics and oscillating heat pipes for long-duration stints in the space environment. According to AFRL, the three primary science objectives are to measure the initial on-orbit thermal performance, to gauge long-duration thermal performance and to assess any lifetime degradation.

Landing site

When the space plane will land is unknown. The last X-37B mission, OTV-4, touched down at the Shuttle Landing Facility at NASA's Kennedy Space Center in Florida on May 7, 2017 — a first for the program. All prior missions had ended with a tarmac touchdown at Vandenberg Air Force Base in California.

The next X-37B mission,B OTV-6, may lift off in 2019 aboard a United Launch Alliance Atlas-V (501) rocket. Launch would be from Cape Canaveral Air Force Station's Space Launch Complex-41.

Reusable vehicles

The Air Force's X-37B "fleet" consists of two known reusable vehicles, both of which were built by Boeing at several locations in Southern California, including Huntington Beach, Seal Beach and El Segundo. 

The program transitioned to the U.S. Air Force in 2004 after earlier funded research efforts by Boeing, NASA and the Defense Advanced Research Projects Agency.

Looking like a miniature version of NASA's now-retired space shuttle orbiter, the military space plane is 29 feet (8.8 meters) long and 9.6 feet (2.9 m) tall, with a wingspan of nearly 15 feet (4.6 m). The X-37B space plane has a payload bay measuring 7 feet by 4 feet (2.1 by 1.2 m), which can be outfitted with a robotic arm. The X-37B has a launch weight of 11,000 lbs. (4,990 kilograms) and is powered on orbit by gallium-arsenide solar cells with lithium-ion batteries.

On-orbit duties

The missions of the X-37B space planes are carried out under the auspices of the Air Force Rapid Capabilities Office, and mission control for OTV flights is handled by the 3rd Space Experimentation Squadron at Schriever Air Force Base in Colorado. This squadron oversees operations of the X-37B Orbital Test Vehicle.

This Schriever Air Force Base unit is billed as the Air Force Space Command's premier organization for space-based demonstrations, pathfinders and experiment testing. It gathers information on objects high above Earth and carries out other intelligence-gathering duties.

And that may be a signal as to what the robotic craft is doing — both looking down at Earth and upward.

Repeating ground tracks

Ted Molczan, a Toronto-based satellite analyst, told Inside Outer Space that OTV-5's orbit at the start of August was about 197 miles (317 kilometers) high, inclined 54.5 degrees to the equator. Its ground track repeated nearly every five days, after 78 revolutions.

"Maneuvers on August 18 and 21 raised its orbit by 45 miles (74 kilometers) which caused its ground track to exactly repeat every three days, after 46 revolutions. It was still in that orbit when last observed, on September 8, by Alberto Rango, from Rome, Italy," Molczan said.

"Repeating ground tracks are very common," he added, "especially for spacecraft that observe the Earth. I do not know why OTV has repeating ground tracks."

• Leonard David is author of "Mars: Our Future on the Red Planet," published by National Geographic. The book is a companion to the National Geographic Channel series "Mars."
• A longtime writer for Space.com, David has been reporting on the space industry for more than five decades. Follow us @Spacedotcom, Facebook or Google+.
• This version of the story published on Space.com.

{ https://www.space.com/ }

18-10-2018 om 23:54 geschreven door peter

When Will We Find Planet Nine?

18-10-2018 om 23:39 geschreven door peter

“Space … the final frontier.”

That, of course, is the opening line from the first “Star Trek” series. No one (outside of China, as we will soon see) would watch if the line was, “Space, the next street light.” Yet that’s exactly what the Chinese space program is saying. In 2020, it plans to launch a satellite with a reflective coating that it claims will be capable of beaming sunlight at night on a 50 square mile area that apparently hasn’t yet heard of street lights. Or Las Vegas. Or what animals and humans do when they can’t sleep. What could possibly go wrong?

“The satellite light will be like a twilight glow.”

Kang Weimin – the director of the Institute of Optics at the Harbin Institute of Technology’s School of Aerospace – gave that very non-technical description after the announcement by Wu Chunfeng — chairman of Chengdu Aerospace Science and Technology Microelectronics System Research Institute Co. – that Chengdu, a city 0f 14 million residents in southwestern China, will soon get a second moon “eight times brighter than the Moon” (please update your definition of “twilight” to ‘reflect’ this). At a technology conference in Chengdu, he told the audience that the beam from this satellite will be bright enough to entirely replace street lights.” (Better update “twilight” again.) Why? Chengdu Business Daily gives one answer:

“According to reports, in the civilian sector, the project can replace night street lighting, saving a lot of infrastructure electricity consumption. In view of the 50 square kilometers of Chengdu, providing radiation, for example, can save electricity costs of about 1.2 billion yuan ($173 million USD) per year.”

People’s Daily reports that Chengdu officials also expressed that the artificial moon would increase tourism (see Las Vegas and New York City) while Asia Times points out that the light can be directed to specific locations such as construction sites or disaster areas.

What could possibly go wrong? Ask the people who live in far northern or southern areas with summers filled with midnight suns. Or ask their psychologists who say perpetual sunlight affects internal clocks, creates a feeling of perpetual jet lag and contributes to insomnia and all of its associated serious problems (see Insomnia). The artificial moon will certainly upset astronomers who will be able to see it as its light blocks their view, and it will affect businesses that depend on night darkness. (Note to self: sell stock in nightlight company.)

Then there’s the animals. Kang Weimin says the all-night “twilight” won’t affect them, but that’s not the case in midnight sun areas, which report the animals are out hunting longer, birds are chirping and crowing at all hours, bears are cranky from not hibernating and those all-important nighttime insect-eating bats are eating less often. And those are just the obvious signs.

What could possibly go wrong? Plenty. Enough to offset the profits of a billionaire space entrepreneur, his rich business friends and money-hungry government officials? What do you think?

“Space … the final profit center.”

{ https://mysteriousuniverse.org/ }

18-10-2018 om 21:55 geschreven door peter

After the recent passing of Microsoft co-founder Paul Allen, there was much coverage of the billionaire’s many notable accomplishments and activities – inventor, investor, philanthropist, private rocket builder, shipwreck hunter, brain researcher and owner of sports teams, yachts and an island. However, one major achievement that didn’t get much press was his early and substantial financial contributions to the Search for Extraterrestrial Intelligence (SETI). That’s right – the other half of the IBM side of the personal computer revolution was also a key member of the SETI revolution … and the evidence starts with the Allen Telescope Array, located in the Cascade Mountains in California.

“The chance that we are going to pick up the phone and an alien is going to be on the other end is small, but it is certainly worth—on a modest scale, for me—seeing if we can enable some of that research.”

Paul Allen

In a 2007 interview with Discover magazine, Paul Allen describes how his interest in space and extraterrestrials began with the movie 2001: A Space Odyssey. However, a little thing called software got in the way of that interest and Allen didn’t give it much thought until he had had made some of his billions and one day received a call from a fellow computer industry pioneer. According to Motherboard, Allen, along with Hewlett-Packard founders Bill Hewlett and David Packard and Intel founder Gordon Moore, received a call from Hewlett Packard laboratories founder Barney Oliver asking each to invest $5 million in Project Phoenix, which scanned for signals from 800 stars within 200-light years of Earth.

Allen Telescope Array

When Project Phoenix ended, astronomers interested in SETI designed a large array of radio telescopes and convinced Allen to contribute the $25 million (he later invested $5 million more) needed to build what became the Allen Telescope Array – the first array in the U.S. built specifically for SETI. While it has received 200 million signals from thousands of stars and recently scanned the Oumuamua intergalactic space rock, a definitive ET message hasn’t been identified yet. Despite that, Allen never lost his excitement for the search.

“That would be such a life-changing thing, for us all to know that there are other beings out there who we could potentially communicate with, or maybe we are listening to a signal that they transmitted hundreds of millennia ago.”

While Paul Allen had many other successes, the search for extraterrestrial intelligence wasn’t one of them. However, his quest lives on in the Allen Telescope Array. While we wait for a message, perhaps Allen has finally received it.

{ https://mysteriousuniverse.org/ }

18-10-2018 om 21:19 geschreven door peter

A couple of common aspects in discussions about a Planet X or Planet Nine or Nibiru are that it’s a danger to Earth and it’s coming back. A new study suggests that while a giant ninth planet may have once existed in the solar system, it’s not coming back and it may actually have been good to Earth. Why? Because it saved our planet from Jupiter’s gravitational power by making that giant planet use it instead to fling this Planet X out of the solar system and turn it into a rogue wandering the galaxy aimlessly. Is it true? Should we feel guilty?

“We shouldn’t fall into the trap of looking at the outer solar system and thinking it was always like that.”

In Dynamical Evolution of the Early Solar System, a study published in the Annual Review of Astronomy and Astrophysicsand reviewed recently by Knowable Magazine, David Nesvorný of the Department of Space Studies at Southwest Research Institute in Colorado describes how computer simulations of how the solar system was formed seem to always end up with Uranus or Neptune getting flung out of the array by Jupiter’s massive gravitational force. There’s a pretty big hole – two of them, actually – in those simulations. Some astronomers added a planet that disappeared 4 billion years ago to the simulations – a change that led them to create our current solar system but pointed to no evidence left behind of the one-time existence of such a planet.

Except for the orbit of Jupiter. The simulations indicate that at one time Jupiter was farther away from the sun and closer to Saturn. The combined gravitational pulls of the two ice giants could have been a threat to the inner planets, including Earth. However, during a million-year dynamical instability in the early life of the solar system, something happened to move Jupiter away from Saturn, reducing the danger to the inner planets … something that looked like it was caused by the blowback from Jupiter flinging a huge planet out of the system. That fixes the simulations, except for the fact that an exiting giant would have had some visible effect on the Kuiper belt of space rocks outside of Neptune.

Kuiper belt in relation to the ice giants

Nesvorný thinks he found the hole in the Kuiper belt. The belt is generally in sync with Neptune’s orbit … except for an area called the ‘kernel’ which has a different orbit and may even have a different composition of space rocks. The simulations show that as Neptune moved into its final orbit, it suffered a bump that could have created a gravitational push that created the kernel. And – you guessed it – that bump could have been caused by the force of the gravitational effort needed by Jupiter to knock out Planet X.

“You end up with something like the kernel. It’s circumstantial evidence … but it’s not conclusive.”

Nesvorný admits that while this addition of an exiting Planet X makes the simulations work, he needs more proof. One piece of evidence he proposes is the fact that astronomers are constantly finding Jupiter-sized rogue planets floating between the stars and most were likely deported by similar cataclysmic events in their own solar systems. And it’s not just a few … some estimates put the number in the billions. That means that while we may never again see the Planet X that saved us from Jupiter, there’s a good chance we’ll be visited by a different rogue. Nesvorný has this warning that it may only be a matter of time:

“I bet there will be many. It’s surprising how organized the solar system has remained.”

Which planet will save Earth and the inner planets the next time … or is it our turn?

{ https://mysteriousuniverse.org/ }

18-10-2018 om 21:08 geschreven door peter

NASA wants to send humans to Venus – here's why that's a brilliant idea

 by Gareth Dorrian And Ian Whittaker, The Conversation

Popular science fiction of the early 20th century depicted Venus as some kind of wonderland of pleasantly warm temperatures, forests, swamps and even dinosaurs. In 1950, the Hayden Planetarium at the American Natural History Museum were soliciting reservations for the first space tourism mission, well before the modern era of Blue Origins, SpaceX and Virgin Galactic. All you had to do was supply your address and tick the box for your preferred destination, which included Venus.

Today, Venus is unlikely to be a dream destination for aspiring space tourists. As revealed by numerous missions in the last few decades, rather than being a paradise, the planet is a hellish world of infernal temperatures, a corrosive toxic atmosphere and crushing pressures at the surface. Despite this, NASA is currently working on a conceptual manned mission to Venus, named the High Altitude Venus Operational Concept – (HAVOC).

But how is such a mission even possible? Temperatures on the planet's surface (about 460°C) are in fact hotter than Mercury, even though Venus is roughly double the distance from the sun. This is higher than the melting point of many metals including bismuth and lead, which may even fall as "snow" onto the higher mountain peaks. The surface is a barren rocky landscape consisting of vast plains of basaltic rock dotted with volcanic features, and several continent-scale mountainous regions.

It is also geologically young, having undergone catastrophic resurfacing events. Such extreme events are caused by the build up of heat below the surface, eventually causing it to melt, release heat and re-solidify. Certainly a scary prospect for any visitors.

Hovering in the atmosphere

Luckily, the idea behind NASA's new mission is not to land people on the inhospitable surface, but to use the dense atmosphere as a base for exploration. No actual date for a HAVOC type mission has been publicly announced yet. This mission is a long term plan and will rely on small test missions to be successful first. Such a mission is actually possible, right now, with current technology. The plan is to use airships which can stay aloft in the upper atmosphere for extended periods of time.

As surprising as it may seem, the upper atmosphere of Venus is the most Earth-like location in the solar system. Between altitudes of 50km and 60km, the pressure and temperature can be compared to regions of the Earth's lower atmosphere. The atmospheric pressure in the Venusian atmosphere at 55km is about half that of the pressure at sea level on Earth. In fact you would be fine without a pressure suit, as this is roughly equivalent to the air pressure you would encounter at the summit of Mount Kilimanjaro. Nor would you need to insulate yourself as the temperature here ranges between 20°C and 30°C.

The atmosphere above this altitude is also dense enough to protect astronauts from ionising radiation from space. The closer proximity of the sun provides an even greater abundance of available solar radiation than on Earth, which can be used to generate power (approximately 1.4 times greater).

The conceptual airship would float around the planet, being blown by the wind. It could, usefully, be filled with a breathable gas mixture such as oxygen and nitrogen, providing buoyancy. This is possible because breathable air is less dense than the Venusian atmosphere and, as result, would be a lifting gas.

The Venusian atmosphere is comprised of 97% carbon dioxide, about 3% nitrogen and trace amounts of other gases. It famously contains a sprinkling of sulphuric acid which forms dense clouds and is a major contributor to its visible brightness when viewed from Earth. In fact the planet reflects some 75% of the light that falls onto it from the sun. This highly reflective cloud layer exists between 45km and 65km, with a haze of sulphuric acid droplets underneath down to about 30km. As such, an airship design would need to be resistant to the corrosive effect of this acid.

Luckily we already have the technology required to overcome the problem of acidity. Several commercially available materials, including teflon and a number of plastics, have a high acidic resistance and could be used for the outer envelope of the airship. Considering all these factors, conceivably you could go for a walk on a platform outside the airship, carrying only your air supply and wearing a chemical hazard suit.

Life on Venus?

The surface of Venus has been mapped from orbit by radar on the US Magellan mission. However, only a few locations on the surface have ever been visited, by the series of Venera missions of Soviet probes in the late 1970s. These probes returned the first – and so far only – images of the Venusian surface. Certainly surface conditions seem utterly inhospitable to any kind of life.

The upper atmosphere is a different story however. Certain kinds of extremophile organisms already exist on Earth which could withstand the conditions in the atmosphere at the altitude at which HAVOC would fly. Species such as Acidianus infernus can be found in highly acidic volcanic lakes in Iceland and Italy. Airborne microbes have also been found to exist in Earth's clouds. None of this proves that life exists in the Venusian atmosphere, but it is a possibility that could be investigated by a mission like HAVOC.

The current climatic conditions and composition of the atmosphere are the result of a runaway greenhouse effect (an extreme greenhouse effect that cannot be reversed), which transformed the planet from a hospitable Earth-like "twin" world in its early history. While we do not currently expect Earth to undergo a similarly extreme scenario, it does demonstrate that dramatic changes to a planetary climate can happen when certain physical conditions arise.

By testing our current climate models using the extremes seen on Venus we can more accurately determine how various climate forcing effects can lead to dramatic changes. Venus therefore provides us with a means to test the extremes of our current climate modelling, with all the inherent implications for the ecological health of our own planet.

We still know relatively little about Venus, despite it being our nearest planetary neighbour. Ultimately, learning how two very similar planets can have such different pasts will help us understand the evolution of the solar system and perhaps even that of other star systems.

• Explore further: Mystery of rare volcanoes on Venus

{

18-10-2018 om 01:37 geschreven door peter

And, more to the point, are any asteroids that might be hidden in the Taurid meteor stream potentially hazardous to Earth?

A Taurid fireball – or exceptionally bright meteor – caught during the unusually strong 2015 shower by Bill Allen.

It’s the time of year for the long-lasting Taurid meteor shower. If you glimpse any, think about this. Last year, a team of researchers from the Czech Academy of Sciences in the Czech Republic found evidence to suggest Earth is at greater risk than we thought of being hit by an asteroid associated with these meteors. They identified a new swarm of meteoroids – icy debris in space, left behind by a comet – related to the Taurid meteor stream. More importantly, they said, this new meteoroid stream might also contain still-undiscovered asteroids, some good-sized, say, a few tens of meters (yards) or even larger.

Their study was published in 2017 in the peer-reviewed journal Astronomy & Astrophysics.

Let’s be clear. We are no more in danger of being hit by a space rock from the newly discovered stream of Taurids than we were before scientists discovered it. So there is no imminent danger here. It simply means that scientists will be searching the newly identified streams of meteoroids, with the goal of detecting any medium-sized or even moderately large asteroids with orbits that might bring them near Earth.

What are meteoroids? They’re typically bits of debris in space, often left behind by comets as they orbit the sun. The Taurid meteor shower, for example, is produced by debris of Comet 2P/Encke. When debris from a comet enters our atmosphere, meteoroids vaporize due to friction with the air, leaving streaks of light in our night sky that we call meteors. Sometimes, a random meteor (usually not associated with one of the annual meteor showers) hits the ground, and then its name changes again to meteorite.

There are many comets orbiting the sun, leaving debris behind. As Earth orbits the sun, as our planet encounters these small particles left by comets, we see meteor showers. Some meteoroid streams produce only a few visible meteors, but sometimes Earth passes by a denser swarm of particles, thus causing a more impressive or active meteor shower.

These particles are usually very small, maybe as tiny as sand, or grains of rice, although the sizes do vary. New research suggests some recent Taurid fireballs – or exceptionally bright meteors – were produced by much-larger particles. At least one meteor observed in 2015 had an estimated size of about a meter (3.28 feet). Another very bright meteor – observed in 2015 and recently studied – might have been caused by a space rock 10 times more massive.

The 2015 Taurid shower produced many fireballs, or exceptionally bright meteors. Here’s another one, captured in 2015 by Jeff Dai in Tibet.

The Taurid meteor shower occurs every year, beginning in late October and extending through November. It usually offers only a few bright meteors. However, 2015 was an exceptional year for the Taurids. In November 2015, a network of meteor cameras located in Europe detected about 200 fireballs. Of those, 24 were very bright, and 10 were as bright or even brighter than the full moon.

Bright Taurid meteors were also recorded in Puerto Rico and Thailand, and elsewhere. EarthSky received many photos and videos of the Taurids in 2015.

Since then, astronomers have made an extensive analysis of some of the incoming 2015 Taurids and found that most of the meteors showed a trajectory or orbit that points to the same new branch of meteoroid material. And hence a new meteoroid stream has been found.

Then something else got astronomers’ attention. They realized that some large space rocks, including asteroids 2015 TX24 and 2005 UR, share the same orbits as the newly found swarm of Taurid meteoroids. These asteroids are now assumed to be members of the newly detected meteoroid stream. Asteroid 2015 TX24 – discovered on October 8, 2015 – was closest to Earth 20 days later, on October 28, a date very close to the Taurid meteor shower’s enhanced activity in 2015.

These asteroids are between 200 and 300 meters (656 and 984 feet) in diameter.

And so it appears likely that the newly discovered meteoroid streams contains other still-undiscovered, but relatively large, space rocks.

Remember, some Taurid meteors encounter Earth’s atmosphere each year. Is it possible that larger objects in the newly found Taurid meteor stream might also encounter Earth? For this reason, astronomers speak of these objects as potentially hazardous. They say the objects would be large enough to cause some regional damage if they were indeed to strike Earth, but – as yet – no asteroid has been identified as threatening or having a collision course with Earth.

Clearly, further research and observations are needed.

Some bright meteors were seen during the enhanced Taurid meteor shower of November 2015, including this impressive meteor seen in Thailand:

Another bright Taurid meteor was captured from the Caribbean by the Sociedad de Astronomia del Caribe:

Bottom line: A new stream of meteoroidal material has been discovered for the Taurids. Some relatively large asteroids are known to be in this same orbit. Could there be potentially hazardous asteroids in the stream as well?

• Source: Discovery of a new branch of the Taurid meteoroid stream as a real source of potentially hazardous bodies

{ http://earthsky.org/ }

16-10-2018 om 23:26 geschreven door peter

When the U.S. football field–size, cigar-shaped object ‘Oumuamua entered our solar system last year, it didn’t just give us our first glimpse of an interstellar piece of rock. It also bolstered the plausibility of space rocks spreading life among the stars by ferrying microbes between distant star systems, according to a new study. “Life could potentially be exchanged over thousands of light-years,” says author Idan Ginsburg, a postdoc at the Harvard-Smithsonian Center for Astrophysics in Cambridge, Massachusetts.

The idea, known as panspermia, has been around for centuries. Some astronomers have even speculated that life on Earth was seeded by microbes that hitched a ride on debris ejected from another life-harboring world in the solar system, perhaps on meteorites from Mars. But it seemed improbable that life could have come from interstellar space.

Take computer simulations in 2003 by planetary scientist H. Jay Melosh, now at Purdue University in Lafayette, Indiana. The analysis revealed that about a third of the meteorites shot off Earth were eventually thrown out of the solar system by Jupiter or Saturn, but that the process took millions or tens of millions of years—a long stretch for even the toughest bugs or spores to be exposed to the vacuum and radiation of space. And vanishingly few rocks would ever be captured by some distant system, Melosh found.

The outlook improves if the receiving system is a binary star, which has a more complex gravitational field than the solar system. Yet any system that’s good at capturing is also good at ejecting, meaning refugees from another system are far more likely to be tossed back out in a game of interstellar hot potato than to settle on a hospitable world.

‘Oumuamua is providing fresh hope for the idea of galactic panspermia. For the telescopic survey that found it, the Panoramic Survey Telescope and Rapid Response System, to have detected such an object in the region it had scanned, our Galaxy needs to have 1 trillion of them per cubic light-year, according to study published earlier this year. To fill space like this, every star in the Milky Way would have to eject 10 quadrillion such objects, and a few should be passing through our solar system at any given moment.

In the new study, Ginsburg, along with astrophysicists Manasvi Lingam and Abraham Loeb, also of the Harvard-Smithsonian Center for Astrophysics, calculated the chances of such objects delivering life to an alien world. A binary star such as Alpha Centauri would ensnare a few thousand rocks of ‘Oumuamua’s size every year, and our solar system might snag one a century, the team estimates in a preprint posted last week on arXiv and in a forthcoming paper in The Astronomical Journal.

The researchers then multiplied this capture rate by the number of stars an interstellar object will encounter before whatever bugs it carries all die. If the objects move, like ‘Oumuamua, at a velocity of 26 kilometers per second through interstellar space, 10 million of them will be captured somewhere in the Milky Way in a million years. “If you look at the galaxy as a whole, you expect this to happen fairly often,” Ginsburg says.

Astronomer Jason Wright of Pennsylvania State University in State College says the analysis has merit: “For reasonable numbers, this suggests that planets and asteroids are commonly exchanged between stars.”

But astronomer Ed Turner of Princeton University says the authors may be reading too much into the single example of ‘Oumuamua. “There’s no rigorous mathematical argument you can write about one event evaluated a posteriori,” he says.

And even if our galaxy is thick with ‘Oumuamuas, they are unlikely vectors of panspermia, Melosh says. ‘Oumuamua is way too big to have been ejected from an inhabited planet, he says.

Still, Loeb says more data could settle where galactic panspermia is plausible. Additional discoveries of interstellar interlopers would clarify their prevalence, and Loeb says the detection of life on other worlds would show whether it tends to cluster, as it would if it arose in one place and spread elsewhere by panspermia. If so, he says, our entire galaxy might be considered biologically interconnected, its vast distances offset by vast spans of time and the vast number of objects that set out to cross the void.

• *Correction, 16 October, 10:55 a.m.: This story has been updated to note that the new study will appear in The Astronomical Journal. A link to the study has been added. 

{ http://science.sciencemag.org/ }

16-10-2018 om 22:23 geschreven door peter

Record Breaker: 4 Huge Alien Planets Spotted Around Baby Star

16-10-2018 om 22:14 geschreven door peter

Jupiter’s moon Ganymede shows signs of “strike-slip” tectonic activity

BY MIHAI ANDREI

Ganymede, the largest moon in the solar system, appears to have undergone periods of intense geological activity.

Ganymede. Image credits: NASA / JPL.

Among the many things that make the Earth so special, plate tectonics have a special role. We don’t give it much credit, but without it, life on Earth would perhaps not have been able to exist — or at the very least, would have been dramatically different from what we see today.

The Earth’s crust is split into several rigid plates, which move relative to each other at a speed of a few cm/year. It’s not much, but if you multiply that on the scale of millions of years, it becomes quite significant. Plates can move towards each other convergently (as seen in most high mountain ranges such as the Himalayas), away from each other divergently (as seen on rifts, such as the East African Rift), or simply slide by each other in a motion called “strike-slip”. The most famous example of strike-slip movement is the San Andreas fault in California. Now, astronomers have found signs of this type of movement on another celestial body: Ganymede.

“The heavily fractured surface of Ganymede displays many distinctive regions of inferred strike-slip faulting that may be important to the structural development of its surface,” said Marissa E. Cameron, lead author of this study who completed the work as a doctoral candidate in SOEST’s Department of Earth Sciences.

Ganymede is Jupiter’s and the solar system’s largest moon. Like Europa, it is believed to be an ocean world. Although its surface is frozen, researchers believe that beneath its frozen shell there lies an ocean of liquid water heated up by friction stress caused by Jupiter’s tidal forces.

Europa is widely considered the most likely place in the solar system to hold life outside of Earth, but Ganymede is also an interesting candidate. The liquid water would provide the necessary environment for life to develop, while the ice shell would protect the water from radiation.

Several studies have shown that Europa is still tectonically active, whereas Ganymede isn’t — but it used to be. Studying this process along with its causes and effects could teach us a great deal not only about Ganymede’s past and present but also about Europa’s future.

Astronomers were intrigued to see just how much evidence of strike-slip they found.

“The unexpected finding was how commonplace strike-slip faulting was. Indicators of strike-slip were observed at all nine sites, representing various geographic locations on Ganymede,” said Cameron. “Additionally, the similarities between the sites may be indicative of a past, larger scale process. Incorporating our observations with previous studies provides an improved representation of Ganymede’s tectonic history and allows us to learn more about its neighbor, Europa.”

Journal Reference: Marissa E. Cameron, Bridget R. Smith-Konter, Liliane Burkhard, Geoffrey C. Collins, Fiona Seifert, Robert T. Pappalardo. Morphological mapping of Ganymede: Investigating the role of strike-slip tectonics in the evolution of terrain types. Icarus, 2018; 315: 92 DOI: 10.1016/j.icarus.2018.06.024

{ https://www.zmescience.com/ }

16-10-2018 om 21:25 geschreven door peter