Jupiter Impact!

[Eboard10]

Just imagining the moon or something of similar size hitting the Earth is rather sobering.

What is even more sobering, is the very likely possibility that an object doesn't even have to hit the earth to effect it significantly.

Reminds me of what remote viewer Major Ed Dames predicted happening in the near future. Apparently, a large cometary object would intersect Earth's orbit and the electrical alignment with the Sun would lead to a sequence of very large Solar flares that would impinge on Earth's atmosphere also causing a shift in the Earth's axis of rotation and all that goes with it. It's fairly old but still worth a watch (6:00-9:00)

http://video.google.com/videoplay?docid=-6578438521104676713

 

[Ca.]

Some commentary (excuse the pun) from the web-site of Astro Bob:Posted on September 12, 2012
_http://astrobob.areavoices.com/2012/09/12/meteor-likely-cause-of-jupiter-flash-saturns-b-ring-gets-scrambled/

Meteor likely cause of Jupiter flash;

Still no sign of an impact in Jupiter’s cloud belts by amateur and professional astronomers. I’ve looked at lots of pictures of the planet since Monday and while there are plenty of odd-looking swirls and patches in the clouds, but nothing like the spots that appeared in 2004 and 2009.

Odd is the norm when it comes to the solar system’s biggest planet. Jupiter’s ever changing cloudscapes defy the imagination in their weird variety, making it the most rewarding to follow in a telescope. The weather and cloud patterns change constantly much like they do on Earth.

The flash location has been corrected to longitude 345 degrees (System I) and +2 degrees north, putting it squarely within the white Equatorial Zone we talked about yesterday. Based on its brightness and lack of a dark scar, Dr. Michael Wong, ( http://astro.berkeley.edu/~mikewong/index_12.php#impact2012 ) assistant researcher University of California astronomy department, concluded that the object that struck Jupiter was too small to singe the cloudtops.

The impacting meteoroid is estimated to have been under 33 feet (10 meters) across. Had an object this size hit Earth’s atmosphere, it would have flared at least as bright as the sun and perhaps sprinkled meteorites along its path.

Unfortunately it appears the space rock that hit Jupiter didn’t have the energy to affect the chemistry of its atmosphere enough to leave a visible trace. In this regard, it resembles the previous two impacts in 2010.

Jupiter’s a big planet with a lot of gravitational pull. Meteors must routinely come crashing in and burn up in its atmosphere. We almost certainly miss most of them just as we do on Earth when bright meteors flash across vast, remote locales like the central Pacific and Canadian Arctic.

Still, not much gets by Earth’s army of amateur astronomers who love the sky and spend countless hours watching and recording it. To date, there have been five confirmed instances of meteoroids/comets bashing Jupiter. The first one was predicted to happen after astronomers discovered that a busted comet would rain down on the planet in July 1994. All the remaining events were discovered by amateurs.

 

[Deleted member 8431]

Wow c.a.!

That's a lot of energy!

2.5*1014 watts means 250TJ/sec.

A 50kT nuclear weapon will release about 200TJ or energy according to wikipedia. Nagasaki was app. 20kT.

Geez...

 

[mkrnhr]

Astronomer G. Kernbauer from Austria caught what seems to be an impact on Jupiter on March 17th :

https://youtu.be/4LiL7RYG7ac

Edit: The same impact was observed by another astronomer J. Mckeon here:

https://youtu.be/qAJI4gqX3Zg

 

[Gaby]

Looks like it would have been pretty devastating if it would have been the Earth.

 

[mkrnhr]

There is still hope (sarcasm) for earth. This month and the one before have been quite active. For example, this asteroid (although of just 4 to 9m diameter) was observed between 27 and 28 of March, and it passed at ~46% lunar distance from the earth, and ~26% lunar distance from earth's orbit on March 25th

 

[The Mechanic]

Here's a very nice time lapse video of the hours before the event (the thing the astronomer was actually working on that night). I like how he makes the picture so stable and clear, somehow he does a lot of really nice processing:
_https://www.youtube.com/watch?v=HakDInn_pHE

 

[Chad]

Just to say that its all over social media now - particularly the science ones, and fairly reputable ones too.

The youtube i saw, fairly sure S0 claimed it was energy related rather than a meteor, but most of the above sites do not agree, they're saying meteor/asteroid.

 

[Duke]

Thanks for posting! That was awesome. imagine what NASA's gear would have seen!?

 

[Niall]

Jupiter was hit again on 17 March 2016:

Incoming! Jupiter slammed by another comet - Sixth time since 1994

 

[Chad]

Just to say that its all over social media now - particularly the science ones, and fairly reputable ones too.

The youtube i saw, fairly sure S0 claimed it was energy related rather than a meteor, but most of the above sites do not agree, they're saying meteor/asteroid.

Suspicious0bservers16 hours ago

It was no impact. See the jupiter flash from a few years ago - concentric circles, no sign of material in the clouds or a cloud hole punch -- this was an energetic event! Amazing footage. I will have to report on this, it is a serious event, but will use only a small portion or this video and will give all credit back to you. I promise not to overstep the fair use provisions of the US code. Much respect for your work. -Ben

and his newest show - Published on Mar 30, 2016 - has no mention, maybe it was uploaded before the event. Either way, just for the record, i'm no S0 fanboy.

 

[paralleloscope]

It was no impact. See the jupiter flash from a few years ago - concentric circles, no sign of material in the clouds or a cloud hole punch -- this was an energetic event! Amazing footage. I will have to report on this, it is a serious event, but will use only a small portion or this video and will give all credit back to you. I promise not to overstep the fair use provisions of the US code. Much respect for your work. -Ben

and his newest show - Published on Mar 30, 2016 - has no mention, maybe it was uploaded before the event. Either way, just for the record, i'm no S0 fanboy.

His report on that event just came up, behind paywall so can't link it here. He only develops a bit on the above quote, in drawing a parallel of resemblance to the 2012 event:

https://youtu.be/5-msU-YVb9E

Where they apparently couldn't find a cloud hole punch from an incoming object, or molecular traces of an exploded object in the nearby clouds. He remarks on the similarity of brightness build-up and fade. The 2012 event had the concentric ringlike flashes, which he thinks excludes an impact and speaks for a plasma event.

 

[Niall]

That's an interesting possibility. I've updated the article accordingly.

 

[Chad]

https://youtu.be/7h2HlMD7kRo

Brief mention on today's show - begins at 2mins 43 seconds and is very brief, because it's featured more extensively in the 'deeper look' as per Parallel's comment - says that the events from 2010 and 2012 are 'great footage' and 2012 in particular demonstrates it's not an impact, with 2016 some of it suggests it's not an 'impacter' whereas it's 'plain from 2012 event'.

 

[Ca.]

If i did not Know better, i think that they my positioning for a possible event. But that is just speculation.

Video file: NASA's Juno to Fly Closer to Jupiter than Any Other Spacecraft
JPLraw
Published on Jun 16, 2016 5:00
https://www.youtube.com/watch?v=f0eom8iwmBc

On July 4, 2016, NASA's Juno will perform a suspenseful Jupiter orbit insertion maneuver -- a 35-minute burn of its main engine -- which will slow the solar-powered spacecraft by about 1,200 mph so it can be captured into orbit around the planet's poles.

Juno Mission Media Reel (B-roll and Animations)
Published on Jun 29, 2016
https://www.youtube.com/watch?v=1S_NRX1C9L0

B-roll for media. Juno's goal is to understand the origin and evolution of Jupiter. The spacecraft launched Aug. 5, 2011, and will orbit the giant planet more than 30 times, skimming to within 3,000 miles (5,000 kilometers) above the planet's cloud tops every 14 days. During the flybys, Juno will probe beneath the obscuring cloud cover of Jupiter and study its auroras to learn more about the planet's formation, structure, atmosphere and magnetosphere.

Juno Mission Media Reel (Additional Animations 1)
Published on Jun 30, 2016
https://www.youtube.com/watch?v=

Juno's goal is to understand the origin and evolution of Jupiter. The spacecraft launched Aug. 5, 2011, and will orbit the giant planet more than 30 times, skimming to within 3,000 miles (5,000 kilometers) above the planet's cloud tops every 14 days. During the flybys, Juno will probe beneath the obscuring cloud cover of Jupiter and study its auroras to learn more about the planet's formation, structure, atmosphere and magnetosphere.

Related
Data Recorded as Juno Entered Magnetosphere
Uploaded on Jun 30, 2016

https://youtu.be/utzN1XKoQA4

This chart presents data that the Waves investigation on NASA's Juno spacecraft recorded as the spacecraft entered Jupiter's magnetosphere on June 25, 2016, while approaching Jupiter. Audio accompanies the animation, with volume and pitch correlated to the amplitude and frequency of the recorded waves.

Time runs from left to right, with a total elapsed time of one hour and 45 minutes. The label

"Magnetopause" at just over 20 minutes into the chart marks entry into the magnetosphere, as detected by the sudden onset of a type of high-amplitude wave activity called "Trapped Continuum Radiation."

The graph uses color coding to indicate wave amplitudes as a function of wave frequency (vertical axis, in hertz) and time (horizontal axis).

The trapped continuum radiation -- in the red and yellow area of this spectrogram -- consists of electromagnetic waves that are trapped in a low-density cavity in Jupiter's outer magnetosphere. The walls of the cavity are like a conductor, hence, the cavity traps these low-frequency waves. The low-frequency limit of these waves -- the lower edge of the band on the graph -- is a function of the density of particles in this outer region of the magnetosphere. The density here is roughly one electron per hundred cubic centimeters (6 cubic inches), about one percent of thedensity Juno detected in the solar wind just outside of the bow shock.

The vertical bar to the right of the chart indicates the color coding of wave amplitude, in decibels (dB) above the background level detected by the Waves instrument. Each step of 10 decibels marks a tenfold increase in wave power.

When Juno collected these data, the distance from the spacecraft to Jupiter was about 4.95 million miles (7.97 million kilometers), indicated on the chart as 114 times the radius of Jupiter. Jupiter's magnetic field is tilted about 10 degrees from the planet's axis of rotation. The note of 12 degrees on the chart indicates that at the time these data were recorded, the spacecraft was 12 degrees north of the magnetic-field equator. The "LT" notation is local time on Jupiter at the longitude of the planet directly below the spacecraft, with a value of 6.2 indicating approximately dawn.

The University of Iowa, Iowa City, provided Juno's Waves instrument. NASA's Jet Propulsion Laboratory, Pasadena, California. manages the Juno mission for the principal investigator, Scott Bolton, of Southwest Research Institute in San Antonio. The Juno mission is part of the New Frontiers Program managed at NASA's Marshall Space Flight Center in Huntsville, Alabama. Lockheed Martin Space Systems, Denver, built the spacecraft. JPL is a division of Caltech in Pasadena.

Five years after its launch the Juno probe NASA should go into orbit around Jupiter on July 5 to unravel the mysteries of the largest planet in the solar system that hides under a thick cover layer.

"In just a few days we will arrive at Jupiter which is difficult to achieve," he told the press this week before Scott Bolton, of Southwest Research Institute in San Antonio (Texas), the scientist in charge of the mission.

37 overflights in 18 months

The 3.6-ton probe powered by solar energy will perform a series of 37 flybys of Jupiter, most between 10,000 and 4667 km above the clouds of the gas giant for a scientific mission for 18 months. Juno overflights are much closer than the previous record of 43,000 km set by the American probe Pioneer 11 in 1974.

July 5 at 3:18 GMT (5:18 pm CET) -still July 4 in the US, Juno nationale-- party who will advance to 64 km per second, will light its main engine for 35 minutes to slow its course so as to be captured by the gravity of Jupiter and fit into a polar orbit of 53.5 days.

Given the distance from Jupiter to Earth, about 869 million km, the radio signal confirming the ignition of the engine will reach the flight controllers 48 minutes, or 4:06 GMT.

Pierce the cloud cover

After the first two revolutions of 53.5 days, Juno will fit from October next in an orbit of 14 days will graze him successively the two poles. During its overflights, the instruments of the probe will penetrate the thick cloud cover to study the gigantic aurora borealis, atmosphere and magnetosphere.

"Juno will approach Jupiter in unprecedented distance to pierce its mysteries," said Diane Brown, program manager at NASA. One of the main objectives of the mission will be to better understand what is made ​​inside hitherto unobserved, the giant planet.

European instruments on board

Juno, a mission of 1.1 billion launched August 5, 2011, and will map the gravitational and magnetic fields of Jupiter to determine the internal structure. The new instruments of the orbiter with several European, including French and Italian, will also measure the radiometric emission from the deep atmosphere of the planet, which will reveal its composition, its thermal structure and ionized environment.

"Today we do not know whether or not Jupiter has a central core," notes Tristan Guillot, director of research at the French National Centre for Scientific Research (CNTS) and member of the scientific team of the Juno mission stating the orbiter will help "measures 100 times more accurate."

Not only Juno should help uncover the truth behind Jupiter but also provide new clues about the conditions that existed in the early solar system when the giant planet was in training.

Risk to probe

The mission officials also emphasize the potential risks to Juno also approaching near the planet. They cite in particular the hydrogen layer - 90% of the atmosphere - that undergoes such pressure that it acts as a powerful electrical conductor.

Scientists believe this phenomenon combined with the rapid rotation of Jupiter - a Jovian day long is only ten Earth hours - generates a powerful magnetic field that surrounds the planet and can threaten the probe.

To protect against high radiation, Juno is equipped with a solid titanium armor that surrounds its electronic equipment and instruments, a trip computer and electric wiring. Weighing 172 kilos, this vault will reduce radiation exposure 800 times compared to the unprotected part.

Juno also has on board three Lego figurines made ​​of aluminum. They represent Jupiter, king of the gods in Roman mythology, Juno, his wife and his sister, and Galileo, the Italian scientist who discovered the four large moons of Jupiter.

There are more than twenty years, the Galileo mission NASA had used to study the moons of Jupiter which Europe has a water ocean beneath its thick ice where living organisms could exist.

Source:
http://areazone51ufos.blogspot.fr/2016/07/juno-londe-de-choc-lapproche-de-jupiter.html?utm_source=feedburner&utm_medium=email&utm_campaign=Feed:+AreaZone51Ufos+(Area+Zone+51+%26amp;+UFOs)