But the mission team expects it to come back online soon.

One of the instruments on NASA's Parker Solar Probe powered down unexpectedly last weekend, but don't panic — the mission team expects it to come back online soon.

The sun-studying spacecraft switched off its Energetic Particle Instrument-Hi (EPI-Hi) on Feb. 12, while a software patch was being uploaded to it, NASA officials explained in a brief Parker Solar Probe update on Friday (Feb. 17).

"An anomaly review board determined the instrument was turned on prematurely before the new patch was completely loaded," the update states(opens in new tab).

"The instrument will remain off for several weeks as the geometry between the probe, the sun and solar radio frequency interference will prevent a good uplink," it continues. "The EPI-Hi is expected to return to normal operations after this blackout period, before the spacecraft begins its 15th close encounter with the sun on March 12."

The Parker Solar Probe remains healthy overall, NASA officials added in the update.

The Parker Solar Probe launched atop a Delta IV Heavy rocket in August 2018 on a $1.5 billion mission to study the sun like never before. 

Mission scientists aim to solve several solar mysteries, chief among them why the sun's outer atmosphere, or corona, is so much hotter than its surface and how the solar wind — the stream of charged particles flowing constantly from the sun — reaches its incredible velocities.

The Parker Solar Probe gathers most of its data during daring super-close flybys of the sun, which expose the spacecraft to sizzling temperatures and accelerate it to tremendous speeds. (Solar gravity is a powerful thing.)

These flybys occur roughly once every five months. The next one, the 15th of the mission to date, will peak on March 17(opens in new tab), when the probe zooms just 5.3 million miles (8.5 million kilometers) above the sun's surface. 

As its name suggests, EPI-Hi is designed to measure high-energy solar particles. It's one of two particle detectors, along with EPI-Lo, that make up the spacecraft's Integrated Science Investigation of the Sun instrument. 

The Parker Solar Probe is equipped with three other instrument suites as well — the Fields Experiment, the Wide-field Imager for Solar Probe (WISPR) and the Solar Wind Electrons Alphas and Protons investigation, or SWEAP.

Quelle: SC

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Update: 9.06.2023

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Parker Solar Probe flies into the fast solar wind and finds its source

Artist’s concept of the Parker Solar Probe spacecraft approaching the sun. Launched in 2018, the probe is increasing our ability to forecast major space-weather events that impact life on Earth. (Image credit: NASA)

NASA’s Parker Solar Probe has flown close enough to the sun to detect the fine structure of the solar wind close to where it is generated at the sun’s surface, revealing details that are lost as the wind exits the corona as a uniform blast of charged particles.

It’s like seeing jets of water emanating from a showerhead through the blast of water hitting you in the face.

In a paper to be published this week in the journal Nature, a team of scientists led by Stuart D. Bale, a professor of physics at the University of California, Berkeley, and James Drake of the University of Maryland-College Park, report that the Parker Solar Probe has detected streams of high-energy particles that match the supergranulation flows within coronal holes, which suggests that these are the regions where the so-called “fast” solar wind originates.

Coronal holes are areas where magnetic field lines emerge from the surface without looping back inward, thus forming open field lines that expand outward and fill most of space around the sun. These holes are usually at the poles during the sun’s quiet periods, so the fast solar wind they generate doesn’t hit Earth. But when the sun becomes active every 11 years as its magnetic field flips, these holes appear all over the surface, generating bursts of solar wind aimed directly at Earth.

Understanding how and where the solar wind originates will help predict solar storms that, while producing beautiful auroras on Earth, can also wreak havoc with satellites and the electrical grid.

“Winds carry lots of information from the sun to Earth, so understanding the mechanism behind the sun’s wind is important for practical reasons on Earth,” Drake said. “That’s going to affect our ability to understand how the sun releases energy and drives geomagnetic storms, which are a threat to our communication networks.”

Based on the team’s analysis, the coronal holes are like showerheads, with roughly evenly spaced jets emerging from bright spots where magnetic field lines funnel into and out of the surface of the sun. The scientists argue that when oppositely directed magnetic fields pass one another in these funnels, which can be 18,000 miles across, the fields often break and reconnect, slinging charged particles out of the sun.

“The photosphere is covered by convection cells, like in a boiling pot of water, and the larger scale convection flow is called supergranulation,” Bale said. “Where these supergranulation cells meet and go downward, they drag the magnetic field in their path into this downward kind of funnel. The magnetic field becomes very intensified there because it’s just jammed. It’s kind of a scoop of magnetic field going down into a drain. And the spatial separation of those little drains, those funnels, is what we’re seeing now with solar probe data.”

Based on the presence of some extremely high-energy particles that the Parker Solar Probe has detected — particles traveling 10 to 100 times faster than the solar wind average — the researchers conclude that the wind could only be made by this process, which is called magnetic reconnection. The probe was launched in 2018 primarily to resolve two conflicting explanations for the origin of the high-energy particles that comprise the solar wind: magnetic reconnection or acceleration by plasma or Alfvén waves.

“The big conclusion is that it’s magnetic reconnection within these funnel structures that’s providing the energy source of the fast solar wind,” Bale said. “It doesn’t just come from everywhere in a coronal hole, it’s substructured within coronal holes to these supergranulation cells. It comes from these little bundles of magnetic energy that are associated with the convection flows. Our results, we think, are strong evidence that it’s reconnection that’s doing that.”

The funnel structures likely correspond to the bright jetlets that can be seen from Earth within coronal holes, as reported recently by Nour Raouafi, a co-author of the study and the Parker Solar Probe project scientist at the Applied Physics Laboratory at Johns Hopkins University. APL, located in Laurel, Maryland, designed, built, manages and operates the spacecraft.

“Solving the mystery of the solar wind has been a six-decade dream of many generations of scientists,” said Raouafi. “Now, we are grasping at the physical phenomenon that drives the solar wind at its source — the corona.”

Plunging into the sun

By the time the solar wind reaches Earth, 93 million miles from the sun, it has evolved into a homogeneous, turbulent flow of roiling magnetic fields intertwined with charged particles that interact with Earth’s own magnetic field and dump electrical energy into the upper atmosphere. This excites atoms, producing colorful auroras at the poles, but has effects that trickle down into Earth’s atmosphere. Predicting the most intense winds, called solar storms, and their near-Earth consequences is one mission of NASA’s Living With a Star program, which funded Parker.

The probe was designed to determine what this turbulent wind looks like where it’s generated near the sun’s surface, or photosphere, and how the wind’s charged particles — protons, electrons and heavier ions, primarily helium nuclei — are accelerated to escape the sun’s gravity.

To do this, Parker had to get closer than 25 to 30 solar radii, that is, closer than about 13 million miles.

“Once you get below that altitude, 25 or 30 solar radii or so, there’s a lot less evolution of the solar wind, and it’s more structured — you see more of the imprints of what was on the sun,” Bale said.

In 2021, Parker’s instruments recorded magnetic field switchbacks in the Alfvén waves that seemed to be associated with the regions where the solar wind is generated. By the time the probe reached about 12 solar radii from the surface of the sun — 5.2 million miles — the data were clear that the probe was passing through jets of material, rather than mere turbulence. Bale, Drake and their colleagues traced these jets back to the supergranulation cells in the photosphere, where magnetic fields bunch up and funnel into the sun.

But were the charged particles being accelerated in these funnels by magnetic reconnection, which would slingshot particles outward, or by waves of hot plasma — ionized particles and magnetic field — streaming out of the sun, as if they’re surfing a wave?

The fact that Parker detected extremely high-energy particles in these jets — tens to hundreds of kiloelectron volts (keV), versus a few keV for most solar wind particles — told Bale that it has to be magnetic reconnection that accelerates the particles and generates the Alfvén waves, which likely give the particles an extra boost.

“Our interpretation is that these jets of reconnection outflow excite Alfvén waves as they propagate out,” Bale said. “That’s an observation that’s well known from Earth’s magnetotail, as well, where you have similar kind of processes. I don’t understand how wave damping can produce these hot particles up to hundreds of keV, whereas it comes naturally out of the reconnection process. And we see it in our simulations, too. ”

The Parker Solar Probe won’t be able to get any closer to the sun than about 8.8 solar radii above the surface — about 4 million miles — without frying its instruments. Bale expects to solidify the team’s conclusions with data from that altitude, though the sun is now entering solar maximum, when activity becomes much more chaotic and may obscure the processes the scientists are trying to view.

“There was some consternation at the beginning of the solar probe mission that we’re going to launch this thing right into the quietest, most dull part of the solar cycle,” Bale said. “But I think without that, we would never have understood this. It would have been just too messy. I think we’re lucky that we launched it in the solar minimum.”

Quelle: Berkeley UNIVERSITY OF CALIFORNIA

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Update: 15.06.2023

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PARKER SOLAR PROBE DETECTS SOURCE OF SOLAR WIND

The Sun flings charged particles and accompanying magnetic fields into the solar system, but how? NASA’s Parker Solar Probe dives in to find out.

The dark area across the top of the sun in this image is a coronal hole, a region on the Sun where the magnetic field is open to interplanetary space. (The hole appears dark in this ultraviolet image because the plasma is sparse and thus cooler.) Plasma in these regions accelerates into a fast solar wind, but how this happens has remained an open question.
NASA / SDO

The solar wind — the flow of charged particles, or plasma, from the Sun — radiates out over all the bodies in the solar system, forming a vast, Sun-centered bubble in the dark void of space. It’s essential to life on Earth, but it also stirs up geomagnetic storms that produce power cuts, aurorae, and other earthly disturbances. The mechanism by which the solar wind arises is still not fully understood, so a team of researchers led by Stuart Bale (University of California, Berkeley) set out to tackle the quandary.

The team, whose findings are published in Nature, drew on data collected by NASA’s Parker Solar Probe. Since it launched in 2018, Parker has been circling the Sun in a series of gradually shrinking orbits that are bringing it closer to the solar surface than any previous human-made object.

Indeed, Parker has even dipped into the Sun’s atmosphere, or corona, flying as close as 5.3 million miles to the Sun’s visible surface, or photosphere, which is covered in boiling “bubbles” called granules as well as larger-scale patterns called supergranules.

On the Sun's visible surface, or photosphere, heating plasma rises in the bright, convective “bubbles” (granules) then cools and falls into the dark lanes between the granules.
Image Credit: NSF/AURA/NSO Image Processing: Friedrich Wöger(NSO), Catherine Fischer (NSO)

Supergranules are similar to granules but on much larger scales (about 35,000 km across). They're best seen in measurements of the "Doppler shift" where light from material moving toward us is shifted to the blue while light from material moving away from us is shifted to the red. These bulk, boiling-type motions occur over the entire Sun and hold the key to understanding the fast solar wind.
NASA Marshall Space Flight Center / D. Hathaway

Parker was deployed to answer what accelerates the plasma and accompanying magnetic fields that launch off the photosphere and into the corona. This solar wind travels at different speeds, fast and slow. While both speeds of wind are linked to magnetism in the Sun’s atmosphere, each has its own source. There’s a broad consensus that the fast solar wind originates in coronal holes, regions where the Sun’s magnetic field lines are effectively “open,” extending far into interplanetary space before looping back in.

Over a coronal hole (here, the dark region near the center of the image) are open to interplanetary space, allowing accelerated to flow fast and furious, at speeds up to 800 km/s (2 million mph).
SDO/ AIA / Veronig A. & Temmer M. (University of Graz, Austria)

But what happens in these open fields to drive the solar wind? There are two competing theories. It could be either magnetic waves known as Alfvén waves, which pass through plasma, or magnetic reconnection. Both processes are known to take place on the Sun.

The researchers analyzed a range of measurements taken by Parker in November 2021, during its 10th perihelion, when it passed close to the Sun. The probe measured the solar wind’s plasma density and energy, as well as its magnetic field strength. The team combined these data with surface magnetic field measurements from the Solar Dynamics Observatory, a separate surveyor that launched in 2010.

The team saw that Parker was buffeted during its encounter by microstreams — short, jet-like bursts of high-speed solar wind. With the help of computer simulations, the team established that these microstreams are likely driven by reconnection.

According to the reconnection hypothesis, plasma is accelerated off the surface of the Sun by magnetic reconnection within the coronal holes, specifically in the regions between the supergranules.

“Where these supergranulation cells meet and go downward, they drag the magnetic field in their path into this downward kind of funnel,” Bale says. “The magnetic field becomes very intensified there because it's just jammed.”

This diagram shows the reorganization of magnetic fields by a process called magnetic reconnection. Here, two opposing magnetic field lines meet (A), connecting at the point where they would cross (B), and then sending a burst of particles accelerating outward accompanied by an S-shape twist in the magnetic field (C). Parker sees the S-shape twist as a magnetic switchback.
Gregg Dinderman / S&T; source: Justin Kasper / Levi Hutmacher / University of Michigan Engineering

As the funnels pull in neighboring magnetic fields, the fields reconnect, releasing magnetic energy. Microstreams of sped-up plasma are spewed out into space, along with associated sudden changes in magnetic field direction known as switchbacks. These bursts of solar wind are what hit the spacecraft. 

The researchers showed this by linking the bursts and switchbacks to their footprints in two coronal holes. They also estimated the rate at which magnetic energy was released in the reconnection events and found that it was equivalent to that required to power the fast solar wind flows. In addition, they measured unusually high-energy particles in the jets, which point to the involvement of magnetic reconnection.

As the Parker Solar Probe flies over a coronal hole (shown here in white on the Sun's surface), it encounters switchback magnetic fields as well as small, speedy bursts of solar wind.
University of California, Berkeley; spacecraft image: NASA / Johns Hopkins APL

Alfvén waves, under this interpretation, are an effect of reconnection. As jets of reconnection-accelerated plasma gush out of the coronal holes, they may produce Alfvén waves. These waves may in turn boost the solar wind, but they are not the primary driver of it.

Michael Hahn (Columbia University), who wasn’t involved in the study, finds the evidence “convincing”. But understanding precisely how reconnecting magnetic fields heat and accelerate plasma remains an open question, he points out.

“The authors favor an explanation that the reconnection directly heats the plasma close to the Sun,” Hahn says. But he explains that another option mentioned in the study, indirect transfer of energy, is also possible. First, the energy goes into magnetic waves in the plasma or into turbulence, and only later, farther away from the Sun, does that energy transfer to the plasma.

The myriad of energy-generating processes taking place in the corona makes it complex to identify which are the most significant, Hahn adds. This complexity presents a challenge for solar physicists to overcome.

By broadening the evidence base and bolstering the case for magnetic reconnection fueling the fast solar wind, the Nature study opens up future avenues of inquiry, such as an investigation into how much of the energy generated by reconnection is transferred into turbulence. It also paves the way for improved prediction of geomagnetic storms. Far from being the end of the matter, it represents but the latest development in an ongoing discussion.

Quelle: Sky&Telescope

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Update: 12.08.2023

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NASA's Parker Solar Probe to make closest flyby of Venus on Aug. 21