Youtube is baffled by a video of a man in outer space without a spacesuit captured by the ISS camera. The ISS camera recorded a man without a spacesuit in outer space In space, a man without a spacesuit ISS
A video has appeared on the web that has baffled users. On the frames taken from the ISS in open space, you can see a man without a spacesuit. A mysterious head in a purple cap can be seen in the reflection on the glass element of part of the ISS.
It should be noted that the footage of an incomprehensible phenomenon was obtained while working in space on one of the cameras of the Dexter manipulator, and the broadcast was conducted on the official NASA channel. The manipulator is intkbbee part of the Canadarm system, which moves along the outer surface of the station, helping the astronauts.
Users immediately suggested that the space program is filmed not in space at all, but in pavilions. Some users noted in their comments to the video that they had previously seen the reflection of a person in the glass elements of the station.
YouTube VIDEO: ISS camera captures a man in space without a space suit
"Guys, in almost every live stream from us, it's the same thing! Periodically I watch them, and I specifically look into this glass. At least once, at least briefly, but this guy is on fire. Don't be lazy, turn it on, look carefully and 90% that there will be such a jamb . I have such a feeling that this uncle is a specialist there ... ", - user Pavel Martynovic wrote in his commentary on YouTube.
“This uncle will get his hat)))),” Alexey ironically.
"So this is Superman," Mark said.
However, the majority of Internet users still did not believe in the mysterious “man in the blue cap” and assume an amazing image in the lens of the manipulator by the play of light.
Representatives of NASA did not comment on the situation.
The north magnetic pole is moving towards Asia. The south magnetic pole is heading towards Australia. This is all part of a large-scale event - the reversal of the planet's poles.
The Earth's magnetic field protects life from harmful solar radiation by deflecting charged particles. It surrounds our planet like an invisible force field.
This field is constantly changing, as shown by numerous global magnetic reversals, where the north and south magnetic poles change places.
When turning around, the magnetic field will not be equal to zero, but will acquire a weaker and more complex form.
The power of this power shield that protects us from destructive cosmic radiation can drop to 10% of modern strength and the formation of magnetic poles at the equator or even the simultaneous existence of several north and south magnetic poles.
Geomagnetic reversals occur, on average, several times per million years. The interval between reversals is very uneven and can be up to tens of millions of years.
There are also temporary and incomplete reversals, known as events and excursions, in which the magnetic poles move away from geographic poles before returning back to their original locations.
The last complete upheaval, Bruns-Matuyama, occurred about 780,000 years ago. A temporary reversal, the Lachamp geomagnetic event, occurred about 41,000 years ago. It lasted less than 1000 years with the actual polarity reversal lasting about 250 years.
When the poles reverse, the magnetic field weakens its protective effect, allowing higher levels of radiation to reach the Earth's surface.
An increase in the number of charged particles reaching the Earth will lead to increased risks for satellites, aviation and ground-based electrical infrastructure.
Geomagnetic storms give us a faint idea of what we can expect with a weakened magnetic shield.
In 2003, the so-called Halloween storm caused local power outages in Sweden, required reorientation of flights to avoid outages and radiation risks, and disrupted satellites and communications systems.
This storm was minor compared to other storms of the recent past, such as the "Carrington Event" superstorm in 1859, which produced auroras all the way to the Caribbean.
The impact of a major storm on today's electronic infrastructure is not fully known. Of course, any time spent without electricity, heating, air conditioning, GPS, or the Internet will have serious repercussions; widespread shutdowns could result in economic losses measured in the tens of billions of dollars a day.
In terms of life on Earth and the direct impact of the reverse on our species, we cannot definitely predict what will happen because modern people did not exist during the last full reverse.
Several studies have attempted to link past reversals to mass extinctions—suggesting that some reversals and episodes of extended volcanism may be due to a common cause.
However, there is no evidence of any impending cataclysmic volcanism, and so we will probably have to contend with electromagnetic influence if the field will turn relatively soon.
We know that many animal species have some form of magnetoreception that allows them to sense the Earth's magnetic field.
They can use it to help with long-range navigation during migration. But it is not clear what impact such treatment might have on such species.
What is clear is that early humans did manage to survive the Lachamp event, and life itself experienced hundreds of complete revolutions, as evidenced by the geological record.
The Earth's magnetic field is generated in the liquid core of our planet by the slow churning of molten iron.
Like the atmosphere and the oceans, the way it moves is governed by the laws of physics. Therefore, we should be able to predict "core weather" by tracking this motion, just as we can predict real weather by looking at the atmosphere and the ocean.
The reversal of the poles can be compared to a certain type of storm at the core, where the dynamics - and the magnetic field - go awry (at least for a short time) before calming down again.
When Will the Next Reversal Occur?
We are “late” by a full reversal. The Earth's field is currently decreasing at a rate of 5% per century.
Thus, scientists have suggested that the field may change over the next 2000 years. But setting an exact date will be difficult.
The difficulty of predicting the weather beyond a few days is widely known, despite the fact that we live inside and directly observe the atmosphere.
However, predicting the Earth's core is a much more difficult prospect, mainly because it is buried under 3000 km rocks, so our observations are scarce and unclear.
However, we are not completely blind: we know the basic composition of the material inside the core and that it is liquid.
A global network of ground-based observatories and orbiting satellites also measures the change magnetic field, which gives us an idea of how the liquid core moves.
The recent discovery of the jet stream within the nucleus highlights our evolving ingenuity and growing ability to measure and infer core dynamics.
Combined with numerical models and laboratory experiments to study fluid dynamics in the planet's interior, our understanding is advancing rapidly.
The prospect that we can predict the Earth's core may not be too far off.
We are entering another solar cycle, which, according to astronomers, will be very weak. But since we are in the middle of a pole shift, the protection is weaker, and even a moderate geomagnetic storm will have consequences.
Be ready!
The north magnetic pole is moving towards Asia. The south magnetic pole is heading towards Australia. This is all part of a large-scale event - the reversal of the planet's poles.
The Earth's magnetic field protects life from harmful solar radiation by deflecting charged particles. It surrounds our planet like an invisible force field.
This field is constantly changing, as shown by numerous global magnetic reversals, where the north and south magnetic poles are reversed.
When turning around, the magnetic field will not be equal to zero, but will acquire a weaker and more complex form.
The power of this power shield that protects us from destructive cosmic radiation can drop to 10% of modern strength and the formation of magnetic poles at the equator or even the simultaneous existence of several north and south magnetic poles.
Geomagnetic reversals occur, on average, several times per million years. The interval between reversals is very uneven and can be up to tens of millions of years.
There are also temporary and incomplete reversals, known as events and excursions, in which the magnetic poles move away from geographic poles before returning back to their original locations.
The last complete upheaval, Bruns-Matuyama, occurred about 780,000 years ago. A temporary reversal, the Lachamp geomagnetic event, occurred about 41,000 years ago. It lasted less than 1000 years with the actual polarity reversal lasting about 250 years.
When the poles reverse, the magnetic field weakens its protective effect, allowing higher levels of radiation to reach the Earth's surface.
An increase in the number of charged particles reaching the Earth will lead to increased risks for satellites, aviation and ground-based electrical infrastructure.
Geomagnetic storms give us a faint idea of what we can expect with a weakened magnetic shield.
In 2003, the so-called Halloween storm caused local power outages in Sweden, required reorientation of flights to avoid outages and radiation risks, and disrupted satellites and communications systems.
This storm was minor compared to other storms of the recent past, such as the "Carrington Event" superstorm in 1859, which produced auroras all the way to the Caribbean.
The impact of a major storm on today's electronic infrastructure is not fully known. Of course, any time spent without electricity, heating, air conditioning, GPS, or the Internet will have serious repercussions; widespread shutdowns could result in economic losses measured in the tens of billions of dollars a day.
In terms of life on Earth and the direct impact of the reversal on our species, we cannot definitely predict what will happen since modern humans did not exist at the time of the last full reversal.
Several studies have attempted to link past reversals to mass extinctions—suggesting that some reversals and episodes of extended volcanism may be due to a common cause.
However, there is no evidence of any impending cataclysmic volcanism, and so we will likely have to contend with electromagnetic forcing if the field reverses relatively soon.
We know that many animal species have some form of magnetoreception that allows them to sense the Earth's magnetic field.
They can use it to help with long-range navigation during migration. But it is not clear what impact such treatment might have on such species.
What is clear is that early humans did manage to survive the Lachamp event, and life itself experienced hundreds of complete revolutions, as evidenced by the geological record.
The Earth's magnetic field is generated in the liquid core of our planet by the slow churning of molten iron.
Like the atmosphere and the oceans, the way it moves is governed by the laws of physics. Therefore, we should be able to predict "core weather" by tracking this motion, just as we can predict real weather by looking at the atmosphere and the ocean.
The pole reversal can be likened to a certain type of storm at the core, where the dynamics - and the magnetic field - go awry (at least for a short time) before settling down again.
When Will the Next Reversal Occur?
We are “late” by a full reversal. The Earth's field is currently decreasing at a rate of 5% per century.
Thus, scientists have suggested that the field may change over the next 2000 years. But setting an exact date will be difficult.
The difficulty of predicting the weather beyond a few days is widely known, despite the fact that we live inside and directly observe the atmosphere.
However, predicting the Earth's core is a much more difficult prospect, mainly because it is buried under 3,000 km of rock, so our observations are sparse and unclear.
However, we are not completely blind: we know the basic composition of the material inside the core and that it is liquid.
A global network of ground-based observatories and orbiting satellites also measures changes in the magnetic field, giving us insight into how the liquid core is moving.
The recent discovery of the jet stream within the nucleus highlights our evolving ingenuity and growing ability to measure and infer core dynamics.
Combined with numerical models and laboratory experiments to study fluid dynamics in the planet's interior, our understanding is advancing rapidly.
The prospect that we can predict the Earth's core may not be too far off.
We are entering another solar cycle, which, according to astronomers, will be very weak. But since we are in the middle of a pole shift, the protection is weaker, and even a moderate geomagnetic storm will have consequences.
Be ready!