Solar Orbiter blasts off on mission to reveal the sun's secrets
The US-European Solar Orbiter probe launched Sunday night from Florida on a voyage to deepen our understanding of the Sun and how it shapes the space weather that impacts technology back on Earth.
The mission, a collaboration between ESA (the European Space Agency) and NASA, successfully blasted off from the Kennedy Space Center in Cape Canaveral at 11:03 pm (0403 GMT Monday) and could last up to nine years or even beyond.
Scientists say the craft is expected to provide unprecedented insights into the Sun’s atmosphere, its winds and its magnetic fields, including how it shapes the heliosphere, the vast swath of space that encompasses our system.
By journeying out of the ecliptic plane—the belt of space roughly aligned with the Sun’s equator, through which the planets orbit—it will acquire the first-ever images of our star’s uncharted polar regions.
It’s official - we’re headed to the Sun! ☀️— NASA (@NASA) February 10, 2020
At 11:03pm ET on Sunday, Feb. 9, #SolarOrbiter, an international collaboration between @ESA and NASA, launched on its journey to study our closest star: https://t.co/5R6yR18x2S
Photo Credit: @ulalaunch pic.twitter.com/zSjBkzocJP
Drawing on gravity assists from Earth and Venus, Solar Orbiter will slingshot itself into a bird’s eye view of the Sun’s poles.
“I think it was picture perfect, suddenly you really feel like you’re connected to the entire solar system,” said Daniel Muller, ESA project scientist, shortly after the launch.
“You’re here on Earth and you’re launching something that will go close to the Sun.”
“We have one common goal and that is to get the good science out of this mission. I think we’re going to succeed,” added Holly Gilbert, director of NASA’s heliophysics science division.
Ten state-of-the-art instruments on board will record myriad observations to help scientists unlock clues about what drives solar winds and flares.
These emit billions of highly charged particles that impact the Earth, producing the spectacular Northern Lights. But they can also disrupt radar systems, radio networks and even, though rarely, render satellites useless.
The Flight Contol Team confirms the #SolarOrbiter has stabilised itself and is in 'Sun Pointing Phase' - everthing is nominal! pic.twitter.com/9seNpneDyf— ESA Operations (@esaoperations) February 10, 2020
The largest solar storm on record hit North America in September 1859, knocking out much of the continent’s telegraph network and bathing the skies in an aurora viewable as far away as the Caribbean.
“Society increasingly relies on what happens in space, and therefore we’re more dependent on what the Sun is doing,” said Etienne Pariat, a researcher at the CNRS observatory in Paris.
“Imagine if just half of our satellites were destroyed,” added Matthieu Berthomier, a researcher at the Paris-based Plasma Physics Laboratory. “It would be a disaster for mankind.”
Titanium heat shield
The probe’s closest approach will come every six months, when Solar Orbiter will be nearer to the Sun than Mercury, a mere 42 million kilometers (26 million miles) away.
With a custom-designed titanium heat shield, it is designed to withstand temperatures as high as 500 Celsius (930 Fahrenheit). Its heat-resistant structure is coated in a thin, black layer of calcium phosphate, a charcoal-like powder that is similar to pigments used in prehistoric cave paintings.
The shield will protect the instruments from extreme particle radiation emitted from solar explosions.
All but one of the spacecraft’s telescopes will peep out through holes in the heat shield that open and close in a carefully orchestrated dance, while other instruments will work behind the shadow of the shield.
Just like Earth, the Sun’s poles are extreme regions quite different from the rest of the body. It is covered in coronal holes, cooler stretches where fast-gushing solar wind originates.
Scientists believe this region could be key to understanding what drives its magnetic activity.
Every 11 years, the Sun’s poles flip: north becoming south and vice versa. Just before this event, solar activity increases, sending powerful bursts of solar material into space.
Solar Orbiter will observe the surface as it explodes and record measurements as the material goes by the spacecraft.
#SolarOrbiter - we hear you!— ESA Operations (@esaoperations) February 10, 2020
We have acquisition of signal. Our New Norica tracking station has locked on to #SolarOrbiter. Transmission coming in loud and clear.#AOS✅#LoudAndClear〰️#Estrack📡 pic.twitter.com/vLRmHBc113
The only spacecraft to previously fly over the Sun’s poles was another joint ESA/NASA venture, the Ulysses, launched in 1990. But it got no closer to the Sun than the Earth is.
“You can’t really get much closer than Solar Orbiter is going and still look at the Sun,” ESA’s Muller said.
The mission will be controlled from the European Space Operations Center in Darmstadt, Germany.
After launch, the team will conduct three months of testing to ensure systems are operating properly before turning on the in situ instruments.
The remote-sensing instruments will be activated on Solar Orbiter’s first approach of the Sun, in November 2021.
It will work in concert with NASA’s Parker Solar Probe, which launched in 2018 and will fly much closer to the Sun, passing through the star’s inner atmosphere to see how energy flows through its corona.
Daily newsletterReceive essential international news every morningSubscribe