Spectacular deorbit burn / fuel dump from the Landsat 9 Centaur upper stage observed

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Yesterday 27 September 2021 at 18:12 UT, Landsat 9 was launched from Vandenberg with a ULA Atlas V rocket. 

2h 58m after the launch, after 1.5 revolutions and while over the east coast of the United Kingdom, the Centaur upper stage performed its deorbit burn, lowering perigee such that half an orbit later it would reenter over a designated area in the Pacific Ocean at the end of the second revolution. Following the deorbit burn, there was a fuel blow-out.

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The deorbit burn and fuel blowout happened within minutes of shadow exit over NW Europe. When the resulting exhaust and fuel clouds came into sunlight, they caused a bright spectacle in the sky that was widely seen around 21:12 UT (23:12 CEST) from a.o. the Netherlands, the UK, Belgium, France and Scandinavia.

The event was anticipated: already before the launch, Cees Bassa had noted that the time of the burn coincided with a pass over NW Europe and alerted observers on the Satobs list. I then put out additional alerts on a.o. Twitter, and as a result, many people observed it. 

In addition, there were hundreds of unexpecting casual eyewitnesses, who often had no clue as to what they were seeing. One of the Dutch "UFO"-reporting sites got over 150 reports of a "UFO" in the northern sky as a result.

As seen from my hometown Leiden in the Netherlands, shadow exit would occur low in the northern sky, in Ursa Major. I had put up my camera opposite the historic Leiden Observatory in the center of Leiden, hoping to capture it over the telescope domes.

As it happened, the actual sky trajectory was slightly more eastwards in the sky than we had anticipated based on a pre-launch TLE estimate (my estimate placed in in the tail of the Big Dipper, while in reality it was in the bowl of the Big Dipper). Just enough to place it outside the FOV of my camera (and initially behind a tree). 

So when it became visible and I realized it was off the predictions, I quickly grabbed the tripod and repositioned it. This made me photographically miss the first 20 seconds or so of the event. Over slightly more than 1 minute, I managed to shoot 50 images of the exhaust and fuel clouds descending over the roof of one of the Observatory's auxilliary buildings.

I was lucky with the clouds too. Fields of cumulus were drifting across the sky, and the relevant part of the sky had been clouded out only minutes before the observation (the clouds leaving the scene are visible in the photographs and time-lapse below).

The event was downright spectacular: two v-shaped, comet-like clouds, one very bright and one fainter (see images) with the tips upward, moving down in the sky among the stars of Ursa Major. The brighter, trailing one of the two clouds was easily visible, and of negative magnitude (mag -4 perhaps, as a rough estimate). It's shape changed over time, with a shell-like structure moving away from the tip. Very spectacular!

The fainter cloud is probably rocket engine exhaust from the brief deorbit burn. The brighter cloud is a cloud of fuel particles, resulting from the blow-out (depressurization) of the Centaur's fuel tanks after the burn (this is a.o. done to avoid fuel remnants exploding). Both clouds are illuminated by the sun, which is why they are visible.

Here are some of the 50 images I shot

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In two consecutive of the 50 images, an object briefly becomes visible between the fuel and exhaust clouds (arrow): it is not clear what this exactly is, as one would not expect the Centaur itself in this position (rather, at the tip of the bright cloud).

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Below is a time-lapse movie I constructed from the 50 images. It is at 13 times the real speed: the series of images from which the movie was made spans slightly over 1 minute in time:

The event happened somewhere between ~550 and 685 km altitude, over the United Kingdom and North Sea. An exact altitude cannot be given at the moment: landsat 9 was delivered to a ~685 km orbit, but the rocket made additional manoeuvres, while releasing cubesats.

I have always wanted to see an event like this, and now finally have (my 51 degree North NW European location does not see this kind of events often). Still on my list: a real reentry.

(all the images shown here were made with a Canon EOS 80D camera and EF 2.0/35 mm lens, at 1-second exposure at ISO 2500).

What is NROL-47 and in what orbit will it be launched? [updated twice]

UPDATE 10 Jan 17:25 UT: The launch has been scrubbed due to high altitude winds, and moved one day to Jan 11. New start of launch window is given as 1 pm PST = 20:00 21:00 UT. This means the launch window is shifting, indicating a prefered orbital plane and launch probably right at the start of the launch window.

Update 12 Jan: The launch was again scrubbed yesterday, and is now slated for January 12, 21:00 UT . My remark about a  shifting launch window above was in error, I missed that the Maritime Broadcast Warning window opens somewhat before the actual launch window opens.

Final Update , 12 Jan: NROL-47 successfully lifted off from Vandenberg SLC-6  at 22:11 UT!

Final Update 14 Jan 2018: Amateur observers using radio have located NROL-47 in orbit. It is transmitting in the TOPAZ frequency, 2241.52 MHz. The orbit is still very preliminary but appears to point to ~1100 km orbital altitude and an orbital inclination of ~105-106 degrees. This would identify NROL-47 as a new TOPAZ, but in an orbital plane that differs from the previous four TOPAZ satellites. Due to bad weather at the observing sites of several of our active observers (I was clouded out yesterday evening myself for example), optical observations have not yet been reported.

Hot after the excitement and drama of the Zuma launch (see my previous post), a new classified launch is upcoming on Wednesday January 10, when ULA will launch NROL-47, a classified payload for the National Reconnaissance Office (NRO), on a Delta IV from Vandenberg SLC-6 in California.

From Maritime Broadcast Warnings, the launch window opens at 20:30 UT and closes at 01:26 UT. [edit 1] After a one-day delay due to weather conditions, the launch is now slated to be on the 11th of January with the launch window opening 21:00 UT. The shifting launch window time indicates a launch into a preferred orbital plane, and it is likely that launch will be right at the opening of the launch window. [end of edit 1] [edit 2] This launch was scrubbed as well, and launch is now slated for 12 January 21:00 UT [end of edit 2]

The launch is in Westward direction, into retrograde orbit. This has led some space news websites to assume that the NROL-47 payload is the 5th TOPAZ (FIA Radar) satellite.

But is it? I have some doubts.

If it is TOPAZ 5, then it is clearly a deviation from the previous four launches. The launch hazard zones from published Maritime Broadcast Warnings show that the launch azimuth is different - previous TOPAZ missions all launched into azimuth 220 degrees, but NROL-47 launches into azimuth 200 degrees, a 20 degree difference.

NROL-47 Launch hazard areas (red) compared to the areas of four TOPAZ (FIA Radar) launches
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This can be clearly seen on the map above, where the NROL-47 hazard zones are in red, and the hazard zones from the four TOPAZ in purple, green, light blue and dark blue. The azimuth and locations of the zones from the four TOPAZ launches are all quite similar, but those of NROL-47 stand out as different.

All the four TOPAZ satellites are in a 123.0 degree inclined retrograde orbit. The NROL-47 launch azimuth results in a retrograde orbit too, but with an orbital inclination of 108.6 degrees, not 123.0 degrees: a 14.4 degree difference.

The orbital altitude aimed for appears to be different too. The four TOPAZ satellites are in 1100 x 1110 km orbits. But the location of the Delta IV Upper Stage de-orbit zone (between South Africa and Antarctica), its shape and the opening time of the window (23:23 UT) points to the NROL-47 payload going into a 1500 km altitude orbit instead.[edit: from the first post-launch radio observations (see update in top of this post), the payload actually appears to be in a ~1100 km orbit, similar to previous TOPAZ: but indeed in a different orbital plane than the previous TOPAZ - end of edit]

estimated trajectory of NROL-47
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So if this is the 5th TOPAZ launching as NROL-47 on Wednesday, then it is going into a quite different orbit compared to the previous four TOPAZ: different in orbital inclination as well as in orbital altitude.

In theory, the Delta IV rocket could do a "dogleg" and (when launching at 20:30 UT) deliver the NROL-47 payload into the 123.0 degree inclined orbit close to the orbital plane of TOPAZ 1 (FIA Radar 1). A second manoeuvre near the south polar pass could then align the RAAN and bring it exactly into the orbital plane of TOPAZ 1.

But why do that, if previous TOPAZ launches simply launched directly into the 123.0 degree inclination orbit?

So in my view, the jury is still out regarding the identity of NROL-47. It could be a 5th TOPAZ but in a quite different orbit compared to the previous four (in itself possible: the Lacrosses also occupied two different orbital inclinations). It could also be something new. If something new, it likely will be a radar satellite (like TOPAZ), given the retrograde character of the orbit. [edit - from radio observations, it appears to be a TOPAZ, but in a different orbital p;lane than the earlier TOPAZ -end of edit]

orbital constellation of TOPAZ 1, 2, 3 and 4 in 123.0 degree inclined orbits
The orbits are spaced 90 degrees in RAAN
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The deliberate re-entry of the Upper Stage happens 1.5 revolutions (2h 55m) after launch.

Estimated search orbits, based on a 108.6 degree orbital inclination, are here. New elset estimates for the new launch date and time are here. South Africa will have two visible passes after launch.

An UPDATE on this post, with post-launch imagery of the payload in orbit, is here.