Roundup: Parker Solar Probe Launch

Rocket flames
An awesome image of the Delta IV heavy launching from pad 37B. Credit: Aerojet Rocketdyne.

At 07:31 UTC on August the 12th 2018 the 10th ever Delta IV heavy vehicle launched the long awaited Parker Solar Probe from Cape Canaveral Space Launch Complex 37B. The Delta 4 Heavy launched PSP towards a heliocentric orbit. The mission aims to “touch the sun”, and to get as close to the sun as man has ever been. Getting as close as 3.9 million miles from the sun, that’s roughly 4% of the distance between the Earth and the Sun (roughly 93 million miles).

time lapse
A great timelapse of the Delta 4 heavy launching towards the sun. Credit: Marcus Cote.

The Parker Solar Probe was named after Dr Eugene Parker who discovered the solar winds in 1958. He was present at the launch at the Kennedy Space Centre, seeing the 685kg spacecraft lifted. The 7 year mission will make 24 elliptical orbits of the sun, and uses 7 flybys of Venus to drop the low point of the orbit. It will make the closest point of the orbit closer than any other man made object in heliocentric orbit. It will enter the sun’s “atmosphere”, a section known as the corona, the outermost part of the atmosphere. Protected by a 4.5 inch sunshield, it can withstand temperatures of 2500F (1377C). The aim is to understand how the sun can creates and evolves solar flares and solar winds. It is to understand how the highest energy particles that pass the Earth are formed. It is hoped that it will revolutionise our understanding of the sun, to help us develop and create technology here on Earth.

The rocket has three RS-68A boosters, with the outbound boosters cutting off at T+3 min 57 sec, the core then cut off a minute and a half later at T+5 min 36 sec. The Delta’s cryogenic first stage engine was RL10B-2, which began burning at T+5 min 55 sec, and stopped its first burn at T+10 min 37 sec. This burn entered the 3,044 kg load into a 168 km x 183 km x 28.38 deg parking orbit. The second burn started at T+22 min 25 sec, and ended at T+36 min 39 sec, accelerating it to C3 of 59 km2/sec2, roughly 5,300 m/s out of LEO. At this point the Probe was in solar orbit, the Star 4BV separated at T+37 min 9 sec, with it firing at T+37 min 29 sec. The burn ended a minute and a half later at T+38 min 58 sec, accelerating it to 8,750 m/s beyond LEO. The Parker Solar Probe separated four and a half minutes later. The orbits after this point become much more complicated to get to the prefered orbit touching the sun.

Engineers at the Johns Hopkins University Applied Physics Laboratory in Laurel, Maryland, work on NASA’s Parker Solar Probe spacecraft. Parker Solar Probe will be the first-ever mission to fly directly through the Sun’s atmosphere. Photo & Caption Credit: NASA / JHU-APL

The Delta 380 was the first Cape Canaveral Delta to use the upgraded “common avionics” system for its flight controller. The rocket was shipped to the Cape over a year ago, with it being assembled in the SLC 37 HIF. The rocket was then rolled out to the pad in April 2018, and there was a wet dress rehearsal on June 2 and 6th. The initial date for launch was the day before, august 11th but it was scrubbed at T-1 min 55 sec. Some of the best images of these launches are now taken by amateurs. I usually post a few of the images, but this launch was different as most of those who placed their cameras just a few hundred feet from the rocket got very damaged equipment.

Thank you for reading, take a look at my other posts if you are interested in space, electronics, or military history. If you are interested, follow me on Twitter to get updates on projects I am currently working on.

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Charon: The Man Who Gave His Wife a Moon

Charon Enhanced
An enhanced colour version of Charon taken by New horizons space probe. It is enhanced to show the differences in surface composition. Credit: NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute.

On June 22nd, 1978 James Christy was trying to refine the orbit of Pluto when he noticed something odd about the images. Going straight to Robert Harrington, his supervisor at the U.S. Naval Observatory in Flagstaff, Arizona, together they concluded that they had found what we now know as Pluto’s largest moon Charon. Discovered just 6 miles away from where pluto itself was found (Lowell Observatory), discovering Charon began a journey from Pluto being a dot on a telescope to its own planetary system. With some amazing images coming from a probe NASA sent there, we have a glimpse of the edge of our solar system. The best part of the story, Charon is named after Christy’s wife.

40 years after christy
40 years on, Christy shows the images he used to discover Charon, and now one of the New Horizons images is his PC wallpaper. Credit: NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute/Art Howard/GHSPi

In 1930, Clyde Tombaugh discovered Pluto, and although famous in itself, there was limited study on this dot in the far reaches of the solar system. So on the fateful day James Christy asked his supervisor Bob Harrington for something to do, Harrington pulled some telescope plates of Pluto from the Naval Observatory at Flagstaff to look over. Christy looked over them for some time under a microscope and noticed some inconsistencies with the images, with the asymmetry being different between them. In simple terms he noticed a bump on the side of Pluto that seemed to move over time. Although at first he thought he might be seeing things, when he took it to Harrington he agreed with the findings.

Jim Christy points
Jim Christy pointing to the photographic plate that he used to discover that Pluto has a moon. Credit: U.S. Naval Observatory

When  looking at other images of Pluto, the bump was constantly moving from one side to the other. Further examination showed the bump moved around Pluto at the same own rotational period, 6.39 days. There were two potential theories as to what it was, either Pluto had a mountain thousands of miles high (meaning Pluto was not very spherical) or it has a satellite in synchronous orbit. In the 48 years since Pluto’s discovery at Lovell Observatory in 1930, there had never been any evidence spotted that Pluto had a moon. The next steps included scouring the archives for more cases of an elongated looking Pluto.

The Charon images
The discovery at the US Naval Observatory, Flagstaff was seen as a time varying bulge on the image of Pluto. This is a negative version of the one Christy looked at. Credit: US Naval Observatory.

Christy measured the angle from the north where the strange elongation was. At the same time Robert Harrington calculated what the answer would be if the elongation was from a satellite. They then compared their results, and they were the same. To be sure they waited for the Observatories 61 inch telescope to make a final confirmation on the matter. On the 2nd of July 1978 new images showed an elongation exactly where they expected it to be. Five days later they announced the discovery to the world. Pluto’s first satellite had been discovered.

40 years difference
The difference of 40 years, top left is one of the images Christy used to discover Cahron, the big image is from New Horizons flyby. Credit: U.S. Naval Observatory; NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute

By astronomical tradition, the discoverer of an object gets the first chance to suggest a name for the object. The name does not have to be recognised by the International Astronomers Union. Christy wanted to name the moon after his wife, Charlene. To make it sound more scientific he took his nickname for her “Char” and added an “on”. The “on” was from his interest in atoms, and words like proton and neutron. He suggested the name on the June 24th, 1978. Colleagues at the observatory prefered the name Persephone, but Christy noticed that Charon was actually a real Greek mythological figure. Charon is the ferryman of the dead, associated with the god Hades. Creepily the Romans identified Hades with their god Pluto. The name was eventually adopted on January the 3rd 1986.

The greek Charon
The name Charon was partially adopted because it is the name of the ferrymen of the dead in greek mythology. this is a nineteenth century painting by Alexander Litovchenko

Charon is the largest moon of Pluto, and is about the size of Texas. It also makes Charon the largest moon relative to its parent planet at about 12% of the size. So big in fact that Charon and Pluto are seen as a double planet or binary planets. They have a common centre of gravity that is outside of either of them. It is believed that it was formed by some sort of giant impact, much like the Earth and the Moon. The sheer size and proximity to Pluto meant it was a good choice for a scientific mission to take a closer look at the system. The mission, New Horizons was launched in 2006, with a  primary mission to performa flyby study of the Pluto system.

New Horizons Artist
An artistic impression of what New Horizons looked like when it passed Pluto and Charon. Credit: NASA Goddard Media Studios.

Passing about 18,000 miles (29,000 km) away from Charon on the 24th of July 2015, New Horizons gave the world a brand new stunning view of the moon from up close. At its closest point it was 7,800 miles (12,500 km) from Pluto, mapping both the planet and the moon using its long range imaging cameras. It mapped them to a resolution of 25 mi (40 km). The way they entered the system and the speed they were going allowed them to map all sides of both bodies. They took multiple images with the close range camera to find any surface changes. They also characterised the atmosphere, using the on board ALICE experiment.

Best Charon Images
A mosaic of the best images taken by New Horizons of Charon, from a few different angles. Credit: NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute

The science gained by New Horizons has given astronomers a new look into the outer reaches of the solar system, and it is still planning to take more images of comets and asteroids it comes into contact with in 2019. The first close up images of Charon were revealed  to the world at the John Hopkins Applied Physics Lab in Maryland to a packet auditorium. Jim Christy, the discoverer of Charon and his wife who it was named after were there at the unveiling, were recognized by the crowd. He said “When you go from this little blur in which you don’t actually see anything, to the enormous detail New Horizons sent back,” Christy said, “it’s incredible.” That amount of change in just 40 years.