Tag: solar system

Sun-Observing Spacecraft Sheds Light on the Solar Wind’s Origin

The solar wind is a ubiquitous feature of our solar system. This relentless high-speed flow of charged particles from the sun fills interplanetary space. On Earth, it triggers geomagnetic storms that can disrupt satellites and it causes the dazzling auroras — the northern and southern lights — at high latitudes.

But precisely how the sun generates the solar wind has remained unclear. New observations by the Solar Orbiter spacecraft may provide an answer.

Researchers on Thursday said the spacecraft has detected numerous relatively small jets of charged particles expelled intermittently from the corona — the sun’s outer atmosphere — at supersonic speeds for 20 to 100 seconds.

The jets emanate from structures on the corona called coronal holes where the sun’s magnetic field stretches into space rather than back into the star. They are called “picoflare jets” due to their relatively small size. They arise from areas a few hundred miles wide — tiny when compared to the immense scale of the sun, which has a diameter of 8,65,000 miles (1.4 million km).

“We suggest that these jets could actually be a major source of mass and energy to sustain the solar wind,” said solar physicist Lakshmi Pradeep Chitta of the Max Planck Institute for Solar System Research in Germany, lead author of the research published in the journal Science.

The solar wind consists of plasma — ionized gas, or gas in which the atoms lose their electrons — and is mostly ionized hydrogen.

“Unlike the wind on Earth that circulates the globe, solar wind is ejected outward into interplanetary space,” Chitta said.

“Earth and the other planets in the solar system whiz through the solar wind as they orbit around the sun. Earth’s magnetic field and atmosphere act as shields and protects life by blocking harmful particles and radiation from the sun. But the solar wind continuously propagates outward from the sun and inflates a plasma bubble called the heliosphere that encompasses the planets,” Chitta added.

The heliosphere extends out to about 100 to 120 times further than Earth’s distance to the sun.

The data for the study was obtained last year by one of the three telescopes on an instrument called the Extreme Ultraviolet Imager aboard the Solar Orbiter, a sun-observing probe built by the European Space Agency and the US space agency NASA that was launched in 2020. The Solar Orbiter was about 31 million miles (50 million km) from the sun at the time — about a third of the distance separating the sun and Earth.

“This finding is important as it sheds more light on the physical mechanism of the solar wind generation,” said solar physicist and study co-author Andrei Zhukov of the Royal Observatory of Belgium.

The solar wind’s existence was predicted by American physicist Eugene Parker in the 1950s and was verified in the 1960s.

“Still, the origin of the solar wind remains a longstanding puzzle in astrophysics,” Chitta said. “A key challenge is to identify the dominant physical process that powers the solar wind.”

The Solar Orbiter is discovering new details about the solar wind and is expected to obtain even better data in the coming years using additional instruments and viewing the sun from other angles.

Zhukov said stellar wind is a phenomenon common to most, if not all, stars, though the physical mechanism may differ among various types of stars.

“Our understanding of the sun is much more detailed than the understanding of other stars, due to its proximity and thus the possibility to make more detailed observations,” Zhukov added.

© Thomson Reuters 2023

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NASA’s Hubble Telescope Captures Collision of DART With Asteroid Dimorphos

National Aeronautics and Space Administration’s (NASA’s) Hubble Space Telescope captured a series of photos of asteroid Dimorphos when it was deliberately hit by a 1,200-pound NASA spacecraft called DART on September 26, 2022, according to their statement.

Hubble‘s time-lapse movie of the aftermath of DART’s collision reveals surprising and remarkable, hour-by-hour changes as dust and chunks of debris were flung into space, NASA said in their statement.

Smashing head on into the asteroid at 13,000 miles per hour, the DART impactor blasted over 1,000 tons of dust and rock off of the asteroid.

The Hubble movie offers invaluable new clues into how the debris was dispersed into a complex pattern in the days following the impact, NASA said.

This was over a volume of space much larger than could be recorded by the LICIACube cubesat, which flew past the binary asteroid minutes after DART’s impact, they said.

The primary objective of DART, which stands for Double Asteroid Redirection Test, was to test our ability to alter the asteroid’s trajectory as it orbits its larger companion asteroid, Didymos, the agency said.

Though neither Didymos nor Dimorphos poses any threat to Earth, data from the mission will help inform researchers how to potentially divert an asteroid’s path away from Earth, if ever necessary, the statement said.

The DART experiment also provided fresh insights into planetary collisions that may have been common in the early solar system.

“The DART impact happened in a binary asteroid system. We’ve never witnessed an object collide with an asteroid in a binary asteroid system before in real time, and it’s really surprising.

“I think it’s fantastic. Too much stuff is going on here. It’s going to take some time to figure out,” said Jian-Yang Li of the Planetary Science Institute in Tucson, Arizona.

The study, led by Li along with 63 other DART team members, was published on March 1 in the journal Nature.

The movie shows three overlapping stages of the impact aftermath: the formation of an ejecta cone, the spiral swirl of debris caught up along the asteroid’s orbit about its companion asteroid, and the tail swept behind the asteroid by the pressure of sunlight, resembling a windsock caught in a breeze, the statement said.

The statement described that the Hubble movie starts at 1.3 hours before impact.

In this view both Didymos and Dimorphos are within the central bright spot; even Hubble can’t resolve the two asteroids separately.

The thin, straight spikes projecting away from the center (and seen in later images) are artifacts of Hubble’s optics.

The first post-impact snapshot is 2 hours after the event.

Debris flies away from the asteroid, moving with a range of speeds faster than four miles per hour, fast enough to escape the asteroid’s gravitational pull, so it does not fall back onto the asteroid, the statement said.

The ejecta forms a largely hollow cone with long, stringy filaments.

At about 17 hours after the impact the debris pattern entered a second stage.

The dynamic interaction within the binary system starts to distort the cone shape of the ejecta pattern, the statement described.

The most prominent structures are rotating, pinwheel-shaped features. The pinwheel is tied to the gravitational pull of the companion asteroid, Didymos.

“This is really unique for this particular incident,” said Li. “When I first saw these images, I couldn’t believe these features. I thought maybe the image was smeared or something.” Hubble next captures the debris being swept back into a comet-like tail by the pressure of sunlight on the tiny dust particles, the statement said.

This stretches out into a debris train where the lightest particles travel the fastest and farthest from the asteroid. The mystery is compounded later when Hubble records the tail splitting in two for a few days, the statement said.

A multitude of other telescopes on Earth and in space, including NASA’s James Webb Space Telescope and Lucy spacecraft, also observed the DART impact and its outcomes.

This Hubble movie is part of a suite of new studies published in the journal Nature about the DART mission.

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Saturn’s Moon Enceladus Has “Almost All” Ingredients for Life to Survive: Study

The search for alien life just got more interesting as a team of scientists recently discovered new evidence suggesting that Saturn’s moon Enceladus has oceans that have all the basic requirements and materials needed for life to survive. According to a new study published in the Proceedings of the National Academy of Sciences (PNAS), researchers believe that the ocean of Enceladus is filled with dissolved phosphorus, which is an essential ingredient for life. 

“Enceladus is one of the prime targets in humanity’s search for life in our solar system,” said Southwest Research Institute’s Dr Christopher Glein, the co-author of the paper. 

“What we have learned is that the plume contains almost all the basic requirements of life as we know it. While the bioessential element phosphorus has yet to be identified directly, our team discovered evidence for its availability in the ocean beneath the moon’s icy crust,” he added. 

Running models with data on the ocean-seafloor system on Enceladus, the research team predicted that there should be as much or more phosphorus than in seawater on Earth. “What this means for astrobiology is that we can be more confident than before that the ocean of Enceladus is habitable,” Mr Glein added.  

The researchers noted that it was previously Enceladus might not have adequate levels of phosphorus to support life. However, with their new study, Mr Glein suggested that a new probe be sent to Enceladus in a bid to investigate the habitable ocean. 

“We need to get back to Enceladus to see if a habitable ocean is actually inhabited,” he said as per the study. 

Meanwhile, as per The Independent, Saturn is not the only planet that might have life in its vicinity. The presence of ammonia on Venus has also led some researchers to suggest that the planet could have alien life in its sulfuric atmosphere. They have said that while the planet itself is too hot to have life, there could be microscopic organisms in the clouds, producing ammonia to neutralise the acidity in the same way that animals on Earth do. 

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NASA Updates ‘Eye In The Solar System’ Website Lets Users Explore Outer Space From Home

American space agency NASA has updated its Eyes on the Solar System website, which allows space enthusiasts to explore the “universe beyond and the spacecraft exploring them”. Visitors can explore the planets, their moons, asteroids, comets and the spacecraft from 1950 to 2050. The website also allows them to simulate the landing of NASA’s spacecraft, including the Perseverance rover that was sent by the agency to explore the surface of Mars for signs of past life and examine the rock and soil samples on its surface.

The Eyes on the Solar System website will also help in keeping a tab on the Artemis I mission once it launches. The mission is set to lift off in late September and the update seems to coincide with that.

“Using real trajectory data you can recreate famous moments in solar system exploration, or preview exciting adventures yet to come. Fly with the Voyager spacecraft on their grand voyage, orbit Mars with MAVEN, fly by a comet with Deep Impact or Stardust, and observe our home planet alongside the spacecraft that keep track of Earth’s climate,” NASA said about the Eyes on the Solar System website.

The update was first spotted by HotHardware.

The Artemis I mission is expected to be launched between September 23 and September 27. The dates have been chosen to avoid a conflict with the DART (Double Asteroid Redirection Test), in which a probe is set to strike an asteroid on September 26.

The launch dates depend, however, on NASA receiving a special waiver to avoid having to retest batteries on an emergency flight system that is used to destroy the rocket if it strays from its designated range to a populated area.

If it does not receive the waiver, the rocket will have to be wheeled back to its assembly building, pushing the timeline back several weeks.

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Comet K2 Makes Closest Approach to Earth, but the Celestial Show Is Not Over Yet

The comet C/2017 K2 has offered a spectacular celestial show for stargazers and astronomers as it hurtled past Earth this week. In its closest approach to our planet, which was on July 14, the comet was about 270 million kilometres away. Now, while the comet may have crossed its closest point to Earth, the celestial show is not over yet. It is expected that the comet is now on its journey towards the Sun and may appear brighter when it gets closer to the star in December this year.

The comet named C/2017 K2 (PANSTARRS) or K2, was first spotted by the Panoramic Survey Telescope and Rapid Response System (PanSTARRS) in 2017 when it was in the outer reaches of the solar system. When the comet went past Earth this week, it could be seen through large amateur telescopes, as revealed by EarthSky. However, considering its distance from us, it did not offer a bright show despite its massive size.

But, as per another report, it is expected that we may still have a chance to catch a brighter glimpse of the comet later this year. The K2 comet is headed towards the Sun and will get closest to the star or the perihelion point in December. As it will near the Sun, the comet is likely to get heated up and become more brilliant. This might bring the comet in the range of even the average binoculars which you can use to observe it.

The perihelion is slated to happen on December 19 but there is still uncertainty if it will react the way as it is expected. It is not clear how the Sun’s heat will affect the comet and if it will even make it to the point. So far, the comet has been observed to grow brighter as it moves toward the inner solar system.

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Masaba Masaba Season 2 Trailer: Mother-Daughter Duo Struggle to Balance Hustle, Heart

Huawei, ZTE Gear Removal From US Telecom Network Will Need Additional $3 Billion, Says FCC



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Earth’s Formation Explained With the Help of New Theory Using Laboratory Experiments, Computer Simulations

Digging deeper through laboratory experiments and computer simulations, researchers at the Eidgenossische Technische Hochschule (ETH) Zurich have proposed a new theory on the formation of the Earth. In their study, researchers developed models to demonstrate how planets formed in our solar system and shed light on their composition.

“The prevailing theory in astrophysics and cosmochemistry is that the Earth formed from chondritic asteroids. These are relatively small, simple blocks of rock and metal that formed early on in the solar system,” said Paolo Sossi, Professor of Experimental Planetology at ETH Zurich and lead author of the study published in Nature Astronomy.

Highlighting the lapses in the theory, Sossi said none of the mixtures of any chondrites can explain the exact composition of the Earth.

Some have earlier proposed that collisions of objects, which resulted in the formation of the Earth, generated extreme heat due to which lighter elements vapourised and left the planet in its current composition.

But, according to Sossi, these theories don’t seem credible when one analyses the isotopic composition of our planet. The lead author underlined that isotopes of an element have the same number of protons but a different number of neutrons. Technically, isotopes with fewer neutrons are lighter and thus, should escape first. And, going by the heat vaporisation theory, there should be less number of light isotopes on Earth today, but this isn’t the case.

To get a clearer picture, the researchers created dynamic models and simulated the formation of planets. Sossi said that small grains grew gradually by accumulating more and more material through gravitational pull and became kilometre-sized planetesimals.

Planetesimals and chondrites are both small bodies of rock and metal, but planetesimals have received more heat that helps differentiate between its metallic core and rocky mantle. In addition, the planetesimals that are formed in different areas around the [Sun](https://gadgets360.com/tags/sun) and at different times can differ in composition, Sossi elucidated.

Researchers ran simulations and collided thousands of planetesimals with each other in the early solar system. They observed that a mixture of several different planetesimals could lead to Earth’s composition.

Now, researchers believe that they have a better model to explain the formation of the Earth and a reference to shed light on the formation of other rocky planets.

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Building Blocks of Life Discovered on Asteroid Located 200 Million Miles Away From Earth

Scientists have discovered the building ingredients of life on an asteroid in space for the first time. More than 20 amino acids have been identified on the space rock Ryugu, which is more than 200 million miles from Earth. Scientists studied materials taken from the asteroid by the Japan Aerospace Exploration Agency’s (JAXA) Hayabusa2 probe, which landed on Ryugu in 2018. The spacecraft retrieved 0.2 ounces (5.4 grams) of material from the asteroid’s surface and subsurface in 2019, stored it in an airtight container, and returned it to Earth. Ryugu is made up of several small boulders rather than a single huge boulder.

Ryugu is rich in carbon-rich organic stuff, much of which is thought to have come from the same nebula that gave birth to the Sun and the Solar System around 4.6 billion years ago. Water has also been found on the asteroid, according to previous sample research.

The pitch-black asteroid samples, which only reflect 2 to 3 percent of the light that touches them, have not been modified by interactions with Earth‘s environment, giving them a chemical makeup far closer to that of the early Solar System.

Geochemist Nicolas Dauphas, one of the three University of Chicago researchers who worked with the Japan-led team of scientists, said that they only had a few of these rocks to analyse earlier, and they were all meteorites that had been housed in museums for decades to centuries, changing their compositions. So, Dauphas added, it was remarkable to have immaculate samples from outer space because they are eyewitnesses from places of the solar system nobody has visited before.

Hiroshi Naraoka, a planetary scientist at Kyushu University and the leader of the team that looked for organic matter in the samples, said while outlining the findings at the Lunar and Planetary Science Conference in March that they found a variety of prebiotic chemical molecules in the samples, including proteinogenic amino acids, polycyclic aromatic hydrocarbons akin to terrestrial petroleum, and a variety of nitrogen compounds.

Sample analysis initially found 10 amino acid kinds, but the number has already risen to more than 20. Amino acids are the basic building blocks of all proteins and are required for life to exist on our planet.

The first collection of these findings, published in Science, reveals Ryugu’s makeup.

For now, the researchers are analysing Ryugu samples, and additional information about the asteroid’s makeup will be released soon.

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NASA’s James Webb Space Telescope Almost Set to Go for Solar System Exploration, Find Universe’s Deepest Secrets

Our wait seems to be nearing its end as NASA’s James Webb Space Telescope is in its final stages of completion before being launched to explore the solar system. The Webb team is undertaking the final stages of commissioning the essential instruments aboard the observatory. Technical operations have also begun to test these instruments. The team is running a final test to check how precisely the Webb telescope can find distant stars and galaxies and acquire their images and spectra. The observatory is also equipped to keep a check on satellites, asteroids, and comets in the solar system.

The task of the Webb telescope is to lock its observing tools on the objects that are swiftly moving against a background of stars of our Milky Way galaxy. In order to check the observatory’s capabilities to undertake such complex tasks, the team ran the first test to track a moving object and Webb succeeded in the test. Scientists, now, aim to test different objects, which will move at varying speeds, to test the precision of Webb’s instruments.

Heidi Hammel, Webb’s interdisciplinary scientist for solar system observations, shares, “Webb can detect the faint light of the earliest galaxies, but my team will be observing much closer to home. They will use Webb to unravel some of the mysteries that abound in our own solar system.”

But, isn’t Webb meant to observe the deepest corners of outer space? Do we really need such a powerful tool to study our solar system? The answers lie in a statement by Ms Hammel, “We planetary scientists use telescopes to complement our in situ missions (missions that we send to fly by, orbit, or land on objects). One example of this is how Hubble was used to find the post-Pluto target for the New Horizons mission, Arrokoth. We also use telescopes when we don’t have in situ missions planned — like for the distant ice giants Uranus and Neptune or to make measurements of large populations of objects, such as hundreds of asteroids or Kuiper Belt Objects (small ice worlds beyond the orbits of Neptune, including Pluto) since we can only send missions to just a few of these.”

“Our solar system has far more mysteries than my team had time to solve. Our programs will observe objects across the solar system,” said Hammel.

Her team is planning to observe the giant planets, Saturn‘s rings, the atmosphere of Mars and Kuiper Belt Objects, among other mysteries.

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Pluto’s Orbit Is Highly Chaotic, Radically Different From Other Planets: Study

Since Pluto – the dwarf planet – was discovered in 1930, it has generated considerable interest among astronomers, primarily over its highly eccentric and inclined orbit. New research claims that it is also subject to chaotic perturbance and changes over shorter timescales. At larger timescales, the orbit appears relatively stable. What it really means is that Pluto’s orbit is radically different from that of other planets. Most planets follow nearly circular orbits around the Sun close to its equator. However, Pluto follows a highly elliptical orbit.

Pluto’s orbit is inclined 17 degrees to the solar system’s ecliptic plane. Pluto takes 248 years to complete a single orbit around the Sun. It also means Pluto spends 20 years during each cycle orbiting closer to the Sun than Neptune

While these two planets cross paths, what keeps them from colliding with each other? Researchers say an orbital resonance condition known as a “mean motion resonance” keeps them from hitting each other. Pluto’s orbit has a stable 3:2 mean motion resonance with Neptune. For every two orbits that Pluto makes around the sun, Neptune makes three, preventing a collision between them.

The research has been carried out by Dr. Renu Malhotra, from the University of Arizona, and Takashi Ito, from the Chiba Institute of Technology. It has been published in the Proceedings of the National Academy of Sciences.

“We demonstrate that the orbital architecture of the giant planets lies within a narrow niche in which Pluto-like orbits are practically stable on gigayear timescales, whereas nearby are strongly chaotic orbits,” the researchers write in the paper.

They also say that their investigations have found that Jupiter has a largely stabilising influence whereas Uranus has a largely destabilising influence on Pluto’s orbit. Overall, Pluto’s orbit is rather surprisingly close to a zone of strong chaos, they add.

Pluto was discovered in 1930 by astronomer Clyde Tombaugh. It was visited for the first time on July 14, 2015, by the New Horizons mission by NASA.

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