What Does 5 Tonnes of TNT Do to a Comet? | Deep Impact and Stardust

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If you’ve ever looked up at the night sky  and watched a comet streak by, you will know   of the wonder of watching one of these celestial  visitors. Often seen with awe or fear throughout   humanity’s history, these bright-tailed objects  in our skies were known as harbingers of change.   And yet, in the last 50 years, the  tables turned on these icy wanderers,   and it went from them coming to visit  us, to us being able to visit them.  Scientists had long wondered about the nature and  origins of comets. Where had they come from? How   were they formed? In 1986, the first probe was  launched to image Halley’s comet, and scientists   began to find answers. But to truly understand  comets, it would take more than photographs. A   more physical approach would be needed. Between  1999 and 2005, two probes were launched. Their   mission was to interact with comets in  ways that had never been attempted before.   One would bring collection equipment that would  allow it to scoop stardust right from the comet’s   icy tail, to help scientists analyse the chemical  makeup of these frosty harbingers. The second   would take a more forceful approach. Rather than  quietly collecting a smattering of space dust,   the second probe would crash head-first into the  surface of the comet itself, exploding with the   force of 5 tons of TNT, to see what could be  learned from the resulting crater and debris.   And yet, although these two missions  were to different comets, through chance   there was one comet that unexpectedly  brought them both together: Tempel 1.   I’m Alex McColgan, and you’re watching Astrum.  Join with me in today’s supercut as we explore   the explosive story of Tempel 1, and how  the Stardust and Deep Impact probes both   were needed to help discover what lay  at the heart of this space-borne nomad.   In the early 90’s, comets were still a bit of  an enigma. By 1999, 8 different spacecraft had   been launched to investigate comets in our solar  system, with 5 of them having flown by Halley’s   Comet in 1986. But beyond that, only 2 other  comets had been visited – Comet Giacobini-Zinner   in 1985, and Comet Grigg-Skjellerup in 1992. And  while some fascinating photos and dust samples had   been taken as close as 200km from some of these  incredible celestial bodies’ comas and tails,   comets still held many mysteries. What was their  internal structure like? What were they made   from? And how had they been formed in the first  place? In 1999, NASA scientists proposed a plan to   hopefully answer some of these questions. It would  be difficult to understand the internal structure   of comets by simply looking at their surface. To  know what was going on, scientists would need to   dig a little deeper. Their plan was to create a  crater in a comet using an impactor spacecraft,   which would collide with the comet at high  speeds. As they would know the mass of the   impactor and the speed it was travelling at, they  could calculate from the size of the impact crater   valuable information about the comet – whether its  surface was a loose aggregate of dust and ice, or   whether it had a hard, frozen shell, for instance.  The comet they wanted to target was a short period   comet called Tempel 1, which had a nucleus 8km  long and 5km wide. Scientists weren’t exactly   certain what would happen when the impactor hit –  perhaps the impactor would punch straight through,   like hitting a snow-drift, and not really create  a crater at all. There were many theories. But   scientists were eager to find out which was  correct. NASA approved the project, giving it a   budget of $330 million, and named it Deep Impact.  You might have thought that this was a reference   to the 1998 Hollywood film of the same name, but  apparently, the names for both the project and the   film had been come up with independently, around  the same time. Quite the remarkable coincidence   if so, as Deep Impact (the film) was about  scientists trying to blow up a meteor that was   on a collision course with the earth by flying a  spacecraft to it carrying nuclear warheads. There   certainly seem to be some similarities to the NASA  mission. Especially as NASA scientists worked on   the film. I don’t entirely buy NASA’s claim of a  coincidence. Although, fortunately for the Earth,   there were some differences between the film and  the mission too. Tempel 1’s orbit was nowhere near   the Earth’s, and given the small size of the  impactor compared to the comet, there was no   chance of knocking it off its current trajectory  by more than a centimetre or so. It would be more   like a fly hitting the front windscreen of a  large vehicle. Additionally, nukes would not   be necessary to create a crater on Tempel 1, or  any kind of explosives for that matter. The sheer   speed and kinetic force the impactor would have  when it collided with the comet’s surface would be   enough to create the crater, which some predicted  would be roughly 100m across and 30m deep.   With the mission going ahead, scientists began  work on the Deep Impact spacecraft. The spacecraft   was actually made with two parts. The payload, and  another larger mothership to carry it and record   the result of the impact. This second section was  called the Flyby. It weighed 601 kg, was 3m long,   and housed scientific devices, solar panels, a  debris shield, and two powerful cameras – the High   Resolution Imager (HRI) and the Medium Resolution  Imager (MRI). These would take photos of the comet   after the impact, as well as help with navigation.  The impactor itself was smaller, only 372 kg,   but it was still smart and housed a camera of  its own. This camera, the Impactor Targeting   Sensor (ITS), would take photos of Tempel 1 right  up until the moment of impact, streaming back the   information it collected to its parent Flyby,  which would then relay the images to Earth.   There was considerable public interest in the  mission, which NASA encouraged in 2003 by getting   members of the public to submit their names to be  recorded on a CD which was placed on the impactor.   Roughly 625,000 names were collected in this way,  to be carried directly to Tempel 1’s surface. On   top of that, NASA timed the impact to take place  on the 4th of July – American Independence day.   While this may have been because it was  one day before Tempel 1’s perihelion,   and its proximity to the sun may have produced  clearer images, I suspect that the more likely   reason for this date was that American scientists  liked the idea of a large cosmic firework.   Deep Impact launched on January 12th, 2005 on a  Delta II rocket. But then, a problem hit. Within   a day of leaving the Earth’s orbit, Deep Impact’s  onboard computers switched itself to safe mode,   which it would only do if there was a fault.  Something onboard was apparently overheating.   This gave scientists a bit of a scare, but  fortunately, the cause of the problem was   quickly found to be a minor programming issue.  Acceptable heat tolerances had been set too low,   so Deep Impact thought its thrusters were  overheating when in reality they were just fine.   Engineers corrected the issue, and Deep  Impact was able to properly begin its mission.   The spacecraft spent the next 6 months travelling  to its rendezvous point with Tempel 1. In that   time, it travelled 429 million km. It had  to course correct twice on the journey,   but this was actually impressive as it had  originally been planned for there to be 3   course corrections. One was so precise  that another was deemed unnecessary.   On April 25th, 2005, Deep Impact caught its  first glimpse of Comet Tempel 1. Of course,   NASA scientists couldn’t manually guide Deep  Impact as there was a several minute signal lag.   Deep Impact and Tempel 1 were now roughly 130  million km away from earth, more than twice the   closest distance between Earth and Mars. Deep  Impact’s smart on-board programming would have   to guide it in for the final leg of the journey.  On June 29th, the Impactor successfully released   from the Flyby, and positioned itself into the  comet’s flightpath to crash into it head on.   This was done for a few reasons. First, the front  of the comet was in sunlight, which would allow   for better pictures to be taken. Second, it would  allow a greater accumulated speed to be reached,   resulting in greater kinetic force. And on  July 4th, 2005, just one second out from the   anticipated arrival time, the impactor hit.  And what a magnificent spectacle it produced.   Scientists were thrilled that they had struck  so accurately. Deep Impact’s payload had been   travelling at 37,000 kmh, and had struck with a  force of 1.96×1010 joules of kinetic energy. This   produced the bright flash you see here, the energy  of which is roughly equivalent 5 tons of TNT. This   flash was much brighter than scientists expected.  It lit up the surface of Tempel 1. However,   ironically, the success of the first part of the  mission caused an unexpected negative side effect.   A large dust cloud was kicked up by the  impact, which obscured the Flyby’s view   of the impact crater. Dust outgassed from the  comet for the next 13 days, peaking 5 days in,   which made it hard to see the results of this  interstellar bullseye. Although it did offer   interesting insights into the internal pressures  going on inside the Comet. Around 5 million kg   of water and between 10 and 25 million kg of  dust were ejected from Tempel 1 in that time.   Fortunately, scientists were able to rely on other  eyes, at least to capture images of the explosion.   The collision had been observed through  numerous other telescopes on or around Earth,   including Hubble, Swift, and even  many amateur astronomer telescopes.   Still, this was a serious problem. Although  this outgassing was fascinating to record,   the primary purpose of the Deep Impact Mission was  to take photographs of the crater caused by Deep   Impact. Without images of the result, many of the  questions about Tempel 1 would remain unanswered,   like about its structure and composition. Like  a partially unwrapped gift, Tempel 1 had been   opened, but it had not yet been seen what  lay inside. Some other craft would be needed   to complete Deep Impact’s unfinished mission.  Fortunately, another craft capable of doing so   had already been launched, and, having completed  its own previous mission, was now drifting   serenely through space. It was about to receive  another task. It’s time we talked about Stardust.   Let’s go back to the late 1990’s, when  cometary science was even more patchy.   Although by this point we had sent 6 probes  up to visit these enigmatic celestial bodies,   not very much was known about their origins.  It was believed at the time that comets were   foreign visitors to our solar system, older  than the sun, having been formed from the   loose pre-solar grains of dust that orbit other  stars before drifting through space towards us,   only to be caught up in the sun’s gravitational  pull. It was believed that this theory could be   confirmed by travelling to one of these comets  and picking up some of this loose dust – or   “stardust” – that surrounds them in space. By  examining the isotopic composition, scientists   would be able to tell if it was unusual when  compared to the dust given off by our own star.   However, this was a challenging mission. As  is often the case, it came down to a question   of speed and energy. Comets travel through the  inner solar system at speeds reaching 160,000   kmph. While it was possible for a probe to try  to match that speed and come up alongside it,   this had to be done without needing too  much fuel, or the weight of the craft   would be too heavy and thus too expensive to  get into space in the first place. Initially,   Stardust had nothing to do with Tempel 1. For this  mission, scientists selected a comet known as Wild   2. They believed that they would be able to get  Stardust alongside Wild 2 at a relatively low   velocity. However, this velocity would still  be around 6.5km per second, or 23,400kmph.   As you can imagine, catching even particles  at that speed would be extremely challenging.   Although particles would likely not do too much  damage to Stardust, being too small to really   impact it, it would do irreparable harm to the  particles themselves. When an object crashes   at 23,400 kmph into a surface, the odds of it  keeping its original shape and structure are   incredibly small. Scientists would not learn  much about the structure of these particles if   they smashed those particles into pieces, not  to mention the warping effect all that kinetic   energy being suddenly converted into thermal  would have on the molecular bonds involved. So,   what was their solution? What was their mechanism  for catching objects travelling at those speeds?   Well, much like how an airbag softens the blow  for you if you are involved in a car crash,   scientists realised that they would need an airbag  of their own. Something that would not halt the   particle all at once, but would reduce its speed  over a longer distance, thus reducing the amount   of crushing deceleration involved. For this, they  found an incredible material that was basically   air. Solid air. They decided to use aerogel.  Aerogel is a fascinating substance that was   discovered in 1931 by Samuel Kistler when he made  a bet with fellow scientist Charles Learned about   jelly. As you have probably seen if you have  ever made it yourself, jelly is formed of two   parts. Firstly, a relatively solid structure that  acts kind of like a sponge, and secondly, water.   When you add water to solid cubes of dense  jelly, it absorbs the water and expands into   the wobbly substance we are all familiar  with. If you were to extract the water,   the solid part of jelly would normally contract  again. Kistler’s bet with Learned was to be the   first one to remove all of the liquid from  the jelly without making it shrink. In short,   to make a jelly that was entirely filled with air.  An air jelly. Without going into all the details,   Kistler won his bet, and at the same time invented  the first aerogel. Aerogel is a fascinating   substance, as it is usually over 99% air, and yet  has the structural strength to support bricks.   Nowadays it tends to be made from silica  composites, rather than jelly, but can be made   from a wide range of materials. It is incredibly  light, and is strangely enough an even better   insulator than regular air. And importantly for  Stardust, when particles hit it, it would offer   just the right amount of resistance to slow down  the particle without denaturing or destroying it.   The trails left behind in the aerogel would  also be useful for scientists to spot where   a particle had been captured. Stardust was fitted  with a tennis-racket sized aerogel collector tray   made up of 90 blocks of aerogel 3cm thick, with  over 1000 square centimetres of surface area,   which would be deployed from inside the main body  whenever sampling was to take place. Stardust   would also capture dust from the interstellar  medium, to allow comparisons and to learn more   about the dust in our own solar system. Once it  had collected these samples, it would store them   on a Sample Return Capsule, which would be fired  back towards the Earth for reentry and collection.   This SRC was 0.8x0.5m, weighed 45kg, and came  fitted with aeroshield, navigation recovery aids,   and a parachute. Also onboard Stardust was a  navigation camera, a cometary and interstellar   dust analyser, and a dust flux monitoring  system, among other scientific devices.   The probe launched on 7th February 1999, and spent  the next 5 years travelling through space, passing   the asteroid 5535 AnneFrank along the way, which  it took some photos of. But on 2nd January 2004,   it finally arrived at its target Comet Wild 2.  And what it found was immediately extraordinary.   Scientists had not expected much from  Wild 2. Some NASA scientists described   their expectation of it to be “a rather bland  object looking somewhat like a black potato”.   However, this is not what they found. Instead, the  surface of Wild 2 was covered with spiky pinnacles   hundreds of metres tall, cliffs, massive  holes jetting dust and gas out into space,   even on parts of the comet that were pointing  away from the Sun and thus were expected to   be less reactive. In short, the surface of the  comet was unexpectedly alive, and self-renewing.   Something else was just as notable for its  absence. Craters. Unlike almost every other   body in our solar system with surfaces exposed  to space, there were no craters on the surface of   Wild 2. This puts it in stark contrast to places  like Mars, or our own moon. Given the period of   time Wild 2 is thought to have existed, it surely  must have encountered other objects which impacted   with it. So where had these craters gone? It shows  that a comet’s surface can be either self-renewing   or active, reducing signs of visible craters  over short time frames, astronomically speaking.   And of course, during this flyby, Stardust had  its aerogel collector exposed, and it was rapidly   collecting dust samples. Just listen to the  frequency in which dust struck the spacecraft.   The samples were carefully stowed away, and upon  reaching the vicinity of Earth, Stardust ejected   the SRC. The angle of approach had to be just  right as it was travelling at tremendous speed.   If the approach angle was too low, it would just  skim off the atmosphere and fly back into space.   If the angle was too high, the heat would  disintegrate the capsule. So it was with   great relief that the DC-8 NASA airplane  monitoring the sky saw it approaching at   just the right second at just the right  angle. The SRC landed in the Utah desert,   where it was recovered, everything having  worked and deployed just as it was designed to.   And taking the samples back to the lab, scientists  learned another completely unexpected fact about   Comet Wild 2. It was not a visitor to our solar  system at all. Unlike what had previously been   believed, Comet Wild 2 had not originated from  another star. It had been born from our own.   By comparing the isotopic composition of the  particles Stardust collected with samples   from our own solar system, it was proven that  Comet Wild 2 originated from the solar system.   And contrary to what all the ice on its surface  might lead you to believe, the rock at its centre   was formed under white-hot conditions. Chondrules  and Calcium Aluminium Inclusions were both found   among the samples Stardust collected. These are  structures that only form under incredibly hot   conditions and can be found in other asteroids  between Mars and Jupiter. So, scientists had   to rethink their theory that comets formed in  cold conditions at the edge of solar systems,   even if they do spend some time there.  Both fire and ice go into making comets.   And thanks to the careful, delicate way  that the particles had been collected,   scientists were able to find one last,  surprising thing – the amino acid Glycine.   Amino acids are the building blocks that make up  proteins, that are vital for all living things.   Although this does not mean that there was  anything alive on Comet Wild 2, this does lend   weight to the idea that it was from comets such  as this, crashing into our Earth millions of years   ago, that life’s first building blocks found their  way to our planet. Which, I’m sure you will agree,   offers a tantalising glimpse into our own origins.  Given all these discoveries, you might have been   forgiven for thinking that Stardust’s work was  done. But NASA is always reluctant to waste   perfectly good spacecraft if they have more to  give, and Stardust still had fuel in the tank. And   so, when the question arose in 2006 of how NASA  would capture that close-up image of Tempel 1,   Stardust’s name was put forward. This would prove  to be an interesting opportunity. Stardust was   calculated to have enough fuel to make a 6-year  journey around the solar system to arrive at   Tempel 1. This would represent the first time a  comet was visited and then revisited years later,   providing an intriguing chance to see how  Tempel 1 had evolved over the intervening years.   Deep Impact only imaged about a 1/3rd of Tempel  1’s surface as it flew past, but even that   was enough to identify fascinating geological  features: layered terrains, smooth flows that   contrasted sharply with the rougher terrain around  them, crater-like vents and cliff faces. It would   be incredibly insightful to see how these had  changed in the time Tempel 1 had orbited around   the Sun. Stardust would even be able to take  images of things previously unseen, giving even   greater coverage of the rich geological history  of the comet. There were other advantages to using   Stardust. It would be significantly cheaper to use  equipment that had already been launched than to   develop and then launch something new. Stardust’s  shielding was even designed specifically with   cometary exploration in mind, which certainly  came in use, for reasons I’ll go into later.   It had all the camera equipment it needed to take  precise images. And so, Stardust was approved and   was given a new name to match its new assignment:  the Stardust New Exploration of Tempel 1 mission,   or Stardust NeXT. Of course, achieving this goal  wouldn’t be easy. Course corrections had to be   made years in advance, to conserve fuel and make  sure Stardust arrived when it was supposed to.   This made things complicated, given that Tempel  1 didn’t just remain static as it travelled – it   spins, once every 40 hours. So, it wasn’t just  a case of figuring out how to get Stardust to   meet up with Tempel 1. NASA had to make sure it  happened when Tempel 1’s impacted side was facing   the Sun and facing Stardust once Stardust flew  past. In effect, even though Tempel 1 was not   easy to see clearly, they had to calculate all the  spins that Tempel 1 would make a full year ahead,   to ensure the arrival time matched up.  With Stardust’s diminished fuel reserves,   there would be little room for error. Incredible  precision and excellent models would be required.   As such, NASA enlisted the help of dozens of  observatories around the globe. Tempel 1 was   little more than a tiny dot in the night sky  – thus it was impossible to track through its   surface features, which were indistinguishable at  that distance. However, its asymmetric shape meant   that its brightness fluctuated as it travelled,  dimming as a narrower profile was pointed our way,   then brightening as the wider profile rotated  into view, in regular intervals that allowed   a detailed model to be created with a high  degree of certainty. Scientists counted the   spins as Stardust travelled. One. Two. Three.  Knowing that if they missed a single count,   it would potentially mean the failure of the  primary mission objective. Their model needed   to be perfect. Stardust travelled for years  through space, engaging in one Earth gravity   assist and multiple laps around the Sun, before  timing its final manoeuvre a full year before it   would arrive at Tempel 1. The burn would alter its  arrival time by a small yet significant 8 hours.   Stardust was now locked in. A year later, as  it closed in on the comet, Stardust’s shields   began to detect sounds, as tiny particles began  clattering off it. Tempel 1 was still ejecting   dust and small rocks into space. Stardust was  hit dozens of times. Although these rocks were   tiny – only a millimetre at most - some of these  hits had enough force to go through the front of   Stardust; cutting through a graphite-cyanide  honeycomb sheet as thick as your finger.   Still, Stardust survived the barrage and on the  14th of February 2011, Stardust made its flyby.   It passed at a distance of 181 km, and took  122 images. I find it amusing that scientists   waited for another holiday for a Tempel  1 visit. They’d chosen independence day   for their initial impact. Here, on a less  violent visit, they chose Valentine’s day.   Scientists had to wait for hours for the images  from Stardust to arrive back. But when they did,   NASA saw that they’d managed another bullseye.  They’d correctly predicted the rotation of Tempel   1 to an accuracy of a single degree. Right  on Tempel 1’s surface was the crater that had   been left by Deep Impact’s payload. The mission  was a success. From the images Stardust took,   scientists were able to calculate that it was  approximately 150m across, so 50% larger than they   were predicting. From this they learned that the  surface of Tempel 1 was a very fluffy material,   made from more dust than was expected, and  finer in substance than a powdered snowbank.   The surface was incredibly porous. In fact,  they were able to estimate that 75% of the   comet was actually empty space, the whole thing  held loosely together by gravitational forces.   From analysis of the plume that had been ejected  from Tempel 1 after the impact, scientists were   able to identify several interesting material  components, including clays, silicates, sodium,   and even organic material. While not life itself,  these heavily carbon-rich materials may have been   carried to earth by comets in the past, providing  the vital materials that make up life here.   Not only that, but they were able  to see other changes that had taken   place on Tempel 1’s surface. 3 pits that had  formerly existed had merged to become one.   A cliff face had eroded back around 20-30  metres. This indicated that Tempel 1’s   surface was a dynamically changing place,  leading to interesting questions about   how these formations had formed in the first  place that scientists could now puzzle over.   So, Deep Impact’s mission finally had closure, and  had been a resounding success. But that was not   the end for Deep Impact. Following in Stardust’s  footsteps, Deep Impact’s Flyby was later given   a new mission, titled EPOXI (Extrasolar  Planet Observation and Deep Impact Extended   Investigation), which in 2007 saw it heading off  to investigate other comets, and taking hundreds   of thousands of photos, before ultimately dropping  out of contact in 2013. But by then, Deep Impact   had already done significant amounts to advance  our understanding of comets and our solar system.   What about Stardust? After its extended mission,  scientists saw there was still a little fuel left   in its tank. So, it ran with it. Firing it  for as long as it could, scientists checked   to see if their models of how much fuel  Stardust held matched up with the reality.   To its last breath, Stardust  kept doing science until the end.   When at last all its fuel was used up,  it sent one last transmission to Earth   to acknowledge that it was being turned off for  good. Now, it finally rests amongst the stars.   Comets are truly fascinating things, and  it was thanks to the incredible work of   the Stardust probe and the Deep Impact mission  that we were able to learn a great deal about   their inner composition and workings. While still  retaining their beauty, we have pierced through   their layers of enigma. We understand they are  not some foreign visitors, but originate here,   from our own solar system, and may even have led  to the blossoming of life itself on this planet.   And it was human ingenuity and precision that  allowed these discoveries to be made. So, the   next time you see a comet, with its beautiful tail  flaring out across space away from it, it will no   longer be quite so mysterious, or foreboding. They  may even be the reason you are here today. And all   it took to learn this was to catch the dust from  one, and to punch another really, really hard.
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Channel: Astrum
Views: 48,626
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Keywords: deep impact, nasa, stardust, comet, comets, tempel 1, wild 2, astrum, astrumspace, deep impact movie, comets asteroids and meteors, space, comets in space, crashing into a comet, what is a comet, space discoveries, how comets are formed, comet mission, space technology, comet landing, comet science, aerogel
Id: 0_TuSSfIeZ8
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Length: 30min 23sec (1823 seconds)
Published: Thu Jun 29 2023
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