Russian Chelyabinsk Meteor largest since 1908 Tunguska event

When these things explode with hundreds of kilotons of energy, what provides the explosive energy?

Some properties of chondrites
http://meteorites.wustl.edu/id/density.htm
The estimated size was 17 meters diameter. It was likely not a perfect sphere, so round down to 8 meter radius. That gives a volume of 2000 cubic meters. Average chondrite density of 3.5 tonnes per cubic meter gives about 7000 tonnes. They may have other data showing the density on the high side, or guessing from the calculated energy release of the shockwave on windows, along with videos of the track, etc.
The NASA estimate says the size was 7000 to 10000 tonnes.
A 1 kilogram object at 18000 meters per second has about 162 Megajoules of KE. So, 7 million kilograms has 1134 million megajoules.
http://www.unitconversion.org/energy/megajoules-to-kilotons-conversion.html
Using this converter gives 271 kilotons equivalent. The Hiroshima blast was about 12 kilotons, so the Chelyabinsk energy was about 22 Hiroshimas.
But, the meteor energy was dispersed over 30 seconds before it shattered, so its hard to guess how much energy was in the final shock wave, compared to the Hiroshima shock wave. The Hiroshima blast was IIRC around 3000 feet above the city. The Chelyabinsk shockwave originated at a much higher altitude.

artday, e=mv^2, so for the high velocity to be reduced to zero, that prodigious kinetic energy is converted to heat.

Thanks Paul, scratch that thought. 😉 I briefly searching for something to say yes or no and couldn’t seem to find the details. Well, that was truly some coincidence then.

Mr. Artday: conversion of kinetic to thermal energy

I had a meteorite pass me while driving south on I-35 one night. It looked like a ball of fire with a tail of sparks traveling level to the ground and came past me like I was a spectator at the Indy 500, before it went out in a blaze of glory.
I didn’t run off the road, or anything.

Man putting all that extra CO2 into the atmosphere has increased the gravitational field of the earth. The science is settled.
I bet 97% of Huffington Post readers would actually believe that.
————————————————————————————
Correction to my previous post.
97% of Huffington Post readers WILL actually believe that.
You heard it here first.

@Ossqss
>Hummmm, so going from 49′ to 55′, takes us from 7k to 10k tons,
It went up after homogenisation of the data.

cui bono says:
February 18, 2013 at 7:42 pm
“…What is important is that the story reflects the mindset of a scientific community struggling to reconcile observation with entrenched belief. …”
For what it is worth , I remember hearing a story in similiar vein , the gist of which is that the french national science academy had organised a conference whose theme was approximately ” No way stones can fall from heavens” .i.e the general consensus adhered to by the majority of the scholars at that time. While it was going on a meteorite event over Paris happened during the same time, and fist sized pebble falling from the heaven punctured the roof of an auditorium ( happiliy no one was hurt ) where an esteemed professor was just putting the finishing lines of his conclusive proof that such occurence were impossible.
I of course do not know weather this one is a myth or has some strands of reality infused in it, but it stuck somwhere in the back of my mind, as an example of a funny example of how counterargument to the dominating consensus might happen to be driven home.

Poor Chelyabinsk 🙁
That area is home to the Mayak facility that bred plutonium for the Soviet Union. There were so many accidents there that it has more radioactive contamination and more health consequences than Chernobyl. It is the place Gary Powers was attempting to surveil before his U2 was shot from the sky.
The plant is still active. The most recent known accident was in 2008.

michaeljmcfadden, check here maybe: en.wikipedia.org/wiki/List_of_science-fiction_films_of_the_1950s, might see a familiar title?
Regarding us missing meteors, there was a window between the Tunguska blast and the point when the nations of the world began listening for nuclear bomb detonations where it could have been missed, but it’s not a large window.
The only thing that I can think of was the signal detected over south africa by monitoring stations/satellites/a plane (I think)… yup: http://en.wikipedia.org/wiki/Vela_Incident
Glad someone else corrected 30,000 km/s, that’s WAY beyond solar escape velocity, something like that would fall under the heading of “weapon of mass destruction” and be pretty difficult to explain as anything but a deliberately accelerated and launched weapon.
the actual speed being 17~ km/s is much more sensible.
Also: meteor means it is in the atmosphere, meteorite means you found a piece of it on the ground.

@michaeljmcfadden: This Island Earth.

MattN says:
February 18, 2013 at 5:28 pm
The largest 2 chunks of space debris in the last 100 years hits Russia. What are the chances?

The largest 2 known. 20 could have come down in the Pacific, or Antarctica, or the North Pole and no one would have known.

Ahh! FOUND IT! 🙂 “This Island Earth” — an excellent 1950s genre sci-fi movie!
http://en.wikipedia.org/wiki/This_Island_Earth

EBH says:
February 18, 2013 at 7:48 pm
So there would be a huge crater somewhere, right?

No, there may or may not be a huge crater. Prelimanry reports say this was a stony meteor. There are three general types of meteors in space: stony, metallic (usually iron-nickel), andd mixed stony and iron-nickel/metallic. The stony types tend to explode into a myriad of fragments while still in the upper reaches of the atmosphere. When the meteors plunge into the Earth’s atmosphere, they are usually moving at tremendously high speeds. At such high speeds the impact with the atmosphere 70 to 20 miles above the Earth is like running into a steel armor wall. The impact and friction vaporizes the material at the foreside of the object as the kinetic energy at the rearside of the object is trying to force its way through the object to its frontside. This sudden shockwave through the meteorite can compress, heat, and stress the near zero cold material inside to the point where it must fracture and explode into a showeer of pieces. Stony meteors/meteorites have the least internal strength and are most prone to such fracturing., while some iron-nickel meteors/meteorites can survive in large enough chunks to punch a crater into the ground. The stony object is like a high explosive shell hitting the armor of a tank and fragmenting at the surface, whereas an armor piercing shell with a hard metallic sabot melts and pierces through the tank armor to strike the interior.

mr.artday says:
February 18, 2013 at 7:50 pm
When these things explode with hundreds of kilotons of energy, what provides the explosive energy?

Take an object with a mass of about 10,000 tons, accelerate it to a high velocity by imparting large amounts of kinetic energy, decelerate the object to less than 10 percent of its high velocity in only a number of seconds in time, watch the forend decelerate faster than the rearend, observie the internal compression disrupt the internal molecular bonds of the object and resultant heating, add the heat from the friction with the atmosphere and vaporization of the foreend material, and you get an object fracturing and vaporizing with a force commensurate with the kinetic energy applied against the resisting forces in the atmosphere and the object.

Wow! Well, we’ve certainly determined ONE thing for sure! There are a lot of 1950s movie sci-fi fans among WUWT readership! :> I’ve got hundreds of them recorded on VHS tapes in my living room (VHS is something the younger kiddies may not know about… it’s sorta like biblical scrolls and cave paintings. Nothing to fret about. Go back to your iPhones…)
– MJM
P.S. Matt, thanks for the dartboard note! Heh, I *knew* “cardboard” wasn’t quite right but my sleep-deprived brain refused to pop the cork!

william Abbott says:
February 18, 2013 at 5:06 pm
Uninhabited oceans cover most of the earth’s surface. I estimate these events, large meteor strikes, are more frequent than being estimated. We generally know nothing about them, but we should assume they are at least three times more frequent than observed.

Meteorites and bolides of this size put out light brighter than the Sun in their brief flash through the atmosphere. This flash of light can be much brighter than the nuclear detonations the military satellites are monitoring for on the Earth’s surface. There was another substantial meteorite and bolide fall over Africa in recent years, and the satellites captured images of the event from above in space. You can see the image/s on Youtube.

Doug Huffman says:
February 18, 2013 at 5:42 pm

All of the impact rate calculations are liable to go up in smoke when the Solar System encounters a region of interstellar space littered with a dense field or band of asteroids not orbiting the Sun.
before anyone objects to their existence, it should be noted that it is not impossibel for the late heavy Bombardment and the formation of the Soalr system to have been associated with just such events.

A 55 ft meteorite (not ter mention a fly by asteroid at the same time?)
‘We would expect an event of this magnitude will occur every 100 years
on average.’ says NASA Paul CHodas. Yes if yer livin’ in a gaussian
Mediocristan. ) ref Nassim Taleb ‘The Black Swan.’

OssQss says:
February 18, 2013 at 7:29 pm
Please see: http://english.pravda.ru/society/anomal/20-07-2012/121694-tunguska_meteorite-0/
Quote: “Researchers from Bologna led by a specialist in marine geology Luca Gasperini ran into another “crater” in 2007. The Italians drew attention to the taiga Lake Cheko that lies eight kilometers north-west of the alleged epicenter of the explosion. The location of the reservoir coincides with the flight path of a giant body that later without good grounds became known as the Tunguska meteorite. It is interesting that Lake Cheko is not observed on any map made before 1929, and according to the testimony of local residents, prior to the crash in 1908 it simply did not exist.
Under The project “Tunguska 99,” Gasperini and his colleagues conducted a study of the lake on the ground. First of all, they were struck by its nearly hemispherical form. It was also found that the bottom of the reservoir has the shape of a cone, and its maximum depth is about 50 meters. This may indicate that something huge had struck the tunnel at this point and sank into the ground. Indeed, the ground penetrating radar recorded a large object at a depth of 10 meters below the bottom of the lake.
The Italian scientists suggest that the “culprit” was a fragment of an exploded cosmic body. The weight of the “fragment” is about 1,5 × 10(high)6 kilograms.” – Unquote.
Where’s a will, there’s a way – and where’s a meteorite, there’s a crater (well: almost always, at least…)

Any asteroids that size that hit earth at or near perpendicular would in all probability go completely undetected. Any radar trace would only remain for a few seconds and would probably be put down to a UFO and ignored. If 50 perpendicular impacts happened each century, only one or two would by chance be near populations. A huge asteroid hitting the deep ocean would not trigger a tsunami, but it would trigger short wavelength, high amplitude “rogue” waves that coudl travel a fair old distance. The spin of the Earth would make perpendicular impacts rare for smaller objects one would assume, but huge objects certainly coudl retain their trajectory…. so I reckon these are more common than we think….

H.R. (off fishing in Florida) says:
I can’t say that you are wrong, but there are an awful lot of installations scattered around the world by certain missile-paranoid nations looking for large, fast moving objects.
But they are presumably looking for missiles and re-entry vehicles. Meteors may be well outside the parameters of trajectory and radar cross section such systems would be looking for.
Even though an exploding meteor can easily be comparable with that of a nuclear weapon in terms of energy AFAIK it does not have the characteristic “double flash”.

MattN says:
The largest 2 chunks of space debris in the last 100 years hits Russia. What are the chances?
The Russian Federation covers something like 160 degrees of longitude. It’s also the largest country on the planet as measured by land area. The next largest (Canada) is about 60% the area and covers only about 90 degrees of longitude. An alternative second largest would be Antarctica, which is about 80% the area of Russia and covers all 360 degrees of longitude but is mostly located near the pole.

Tunguska not meteor but Alignment Mercury-Venus-Earth-Neptune
http://tallbloke.wordpress.com/2011/12/02/michele-casati-volcanicity-earthquake-geomagnetism-and-the-heliosphere/comment-page-1/#comment-10225
http://tallbloke.wordpress.com/2011/12/02/michele-casati-volcanicity-earthquake-geomagnetism-and-the-heliosphere/comment-page-1/#comment-10270
meteorite not ….
change atmospheric circulation
generate geomagnetic storm
generate St. Elmo’s fire

Charles Gerard Nelson says:
You know I’m always tickled when somebody throws up a graph of ‘Global temperature’ since 1890 or some such. Up at this end of the timescale NASA GISS Hadcrut, Uncle Tom Cobbly and all; equipped with their satellites and calibrated digital thermometers happily deviate from each other by .08 of a degree…but hey in 1890 when there was probably less than a dozen thermometers in the entire Southern Hemisphere and none at the poles…well the ‘scientists’ know for certain sure that the GLOBAL temp was 1.2 degrees cooler than today…
as they say in England ‘do me a favour’!
Even “Pull the other one, its got bells on”. Or a euphemism for “urine extraction”.

NASA is a big barrel, GISS is the rotten apple.

Good old atmosphere, what would we do without you? As noted we are in a very sleepy area of our galaxy, one of the only reasons we are here and likely the human race will be long dead and forgotten before we cross paths with anything that could come close the the Late Heavy Bombardment. But it is nice to know we got our 1 in 100 years hit out of the way without much drama.

Looks like this one was 1/6 to 1/60th the expolsive power of Tunguska. It’ll be interesting to find out just how high and far away from Chelyabinsk this metor was. A Tunguska size blast over the city likely would have flattened a sizeable portion of it.

Which science fiction movie of the 1950s or late 1940s has a scene early in the film where scientists at a remote astronomical observatory (South Africa perhaps) use a speical instrument to view a planet in a distant solar system, the planet is seen to have prehistoric type dinosaurs, and they come to think they are looking backwardzs in time and actually seeing the Earth as it existed in the Age of the Dinosaurs? The movie was probably a black & white film. Also, this was a movie and it definitely was not the Outer Limits episode where the scientist creates a miniature Earth in the laboratory which goes through a vastly accelerated rate of development with evil consequences.

Rhys Jaggar says:
February 18, 2013 at 11:04 pm
Sooner or later this will get put down to ‘galaxy warming’
lol
Careful…next thing the watermelons and the AGW’ers will be characterizing Hydrogen
as a galactic greenhouse gas and, if it weren’t for H, the universe would be at absolute zero….
then they’ll label all Hydrogen derivatives and molecular structures as pollutants, and ban
them….put a hydrogen tax on everything and try to shut down the sun….always thought
they wanted to move us all back to the dark ages….

A friend was listening to Larry Niven and Jerry Pournelle’s “Lucifer’s Hammer” audio book. I was only half listening but it sounded like a pretty good yarn – comet hits earth and messes us up pretty bad. It just got over when I read the first reports. Made me nervous! Like many others, I suspected a “fellow traveller” to 2012DA14 (apparently not) and wondered if there were others (aparently not). No causal link suggested to listening to the book – just another coincidence…

One wire seems to have given the Cuba reports some credence: http://bigstory.ap.org/article/cuba-too-reports-powerful-meteorite-explosion
However, various reports said it had been observed Tu, We, Th, or Friday 15Feb.

Exeter is apparently alive and well, and living in Seattle:
Exeter     Exeter?

as Pull my finger says, This Island Earth was used in the Mystery Science Theatre 3000.
With marvellous sardonic comments from the two robots watching it with the human. Absolutely wonderful.
In Fred Hoyle’s The Black Cloud, which I read as a child, there is an interesting discussion between Alexandrov, the (appropriately) Russian scientist and some of the others, when Alexandrov points out that the only reliable check in science is prediction. You can make all sorts of correlations after an event but if they’re not made beforehand, they are not significant. A lesson that seems to have been forgotten with the emphasis on peer review these days.

Ruskies, get out & find those pieces! Meteorites on frozen lakes/snow are some of the easiest to find, while the ice/snow lasts. And they’re valuable. Meteorite Men from the Science Channel, book your flight now!

Ha, the Cuba episode was probably one of those big old 1950s Chevies they love backfiring.

Leonard Weinstein says:
February 19, 2013 at 5:57 am
Werner Brozek says:
The energy in very large explosions such as nuclear explosions is given in tons or kilotons or megatons equivalent explosive, where 1 ton=4.2E9 Joules. This is a common practice, and is even listed in the ISU. I agree most common practices (including using English rather than metric units in America and much of the world) should be replaced by scientific practices, but we are not going to get that soon.

It is a scientific practice, just poorly explained. They settled on that method of measuring large explosions because the energy release of TNT (which is the reference explosive) was highly uniform and well studied at the time nuclear weapons were being developed, and it was a standard that was easily replicated in the field to calibrate instruments.
As in most new fields of study, one of the on going difficulties is the development of a measurement standard which is both practical and repeatable. Once a practical field reference is found, it then gets adopted as a reference standard until higher precision means allow a more precise measurement standard to be developed (see evolution of the definition of the time base second or the length reference meter).
In this case due to military studies they had a huge amount of reference information both on the chemical energy release of a common easily manufactured explosive which had been in use for a long time but they also had weapons damage effects references from all their conventional weapons studies to help them scale the effects up to the sizes of expected nuclear weapons yields. They also needed to work backwards from predicted explosive yield to the expected physical damage intended at the target to calculate expected weapons effects for a given energy yield. In short they were trying to define how much explosive energy needed to be released in a single point weapon to cause a certain amount of damage over a large area to militarily significant targets. Due to cube square effects you get diminishing returns as the yield goes up as most of the energy is expended moving air around in high in the atmosphere not at ground level where you want the damage effects to occur. In this case height of burst becomes very important because there is a critical altitude of burst that maximizes surface damage due to how the shock wave interacts with the ground and at that altitude create a reinforced shock wave “mach front” at ground level.
In the case of a meteor such as Chelyabinsk the altitude which it undergoes breakup and maximum energy release rate will significantly modify the maximum air blast at ground level under the ground track. If it breaks up too high or too low, the maximum damage area will be smaller than if it breaks up at the ideal altitude to transfer its air blast energy to ground structures.
With regards to the definition of the kiloton energy reference:
The following is a quote from the book “The Effects of Nuclear Weapons” by Glastone 1977 (the same info is in the earlier 1962 edition) Page 13 chapter one. Which was considered the “bible” of weapons effects in the west for many years as it was the first publicly available unclassified document derived directly from nuclear weapons effects tests the U.S. Government conducted for nuclear weapons development.

“1.45 Only part of the fission energy is immediately available in a nuclear explosion; this includes the kinetic energy of the fission fragments, most of the energy of the instantaneous gamma rays, which is converted into other forms of energy within the exploding weapon, and also most of the neutron kinetic energy, but only a small fraction of the decay energy of the fission products. There is some compensation from the energy released in reactions in which neutrons are captured by the weapon debris, and so it is usually accepted that about 180 MeV of energy is immediately available per fission. There are 6.02 x 10^23 nuclei in 235 grams of Uranium-235 (or 239 grams of plutonium-239), and by making use of familiar conversion factors (cf. 1.43) the results quoted in table 1.45 may be obtained for the energy (and other) equivalents of 1 kiloton of TNT. The calculations are based on an accepted, although somewhat arbitrary, figure of 10^12 calories of energy released by this amount of TNT. (foot note 3)”
Footnote 3) The Majority of the experimental and theoretical values of the explosive energy released by TNT range from 900 to 1,100 calories per gram. At one time there was some uncertainty as to whether the term “kiloton” of TNT referred to a short kiloton (2×10^6 pounds), a metric kiloton (2.205 x 10^6 pounds) or a long kiloton 2.24 x 10^6 pounds.
In order to avoid ambiguity, it was agreed that the term “kiloton” would refer to the release of 10^12 calories of explosive energy. This is equivalent to 1 short kiloton of TNT if the energy release is 1,102 calories per gram or to 1 long kiloton if the energy is 984 calories per gram of TNT.

10^12 calories = 4.184 x 10^9 Joules which rounds to the cited 4.2 E9 Joules in your comment.
Keep in mind that at the time this standard was derived advanced calculations for weapons were still being done on mechanical calculators that took days to work out calculations that can easily be solved on a cheap pocket electronic calculator today. The largest electronic computers of the day still occupied entire rooms and were being used to refine ballistic tables for artillery shells.
Larry

A comparison of orbits: 2012DA14 and Chelyabinsk.
Wikipedia commons image, image enhanced from a Nasa Blog. View perpendicular to ecliptic.
http://en.wikipedia.org/wiki/File:Orbit_of_2012_DA14_and_Chelyabinsk_meteor_2.jpg
NASA website of Near Earth Orbit object closest approaches. Dynamic table by date. 2012DA14 already scrolled off.
About 1 per day on average, miss distance usually more than 30 Lunar Distances.
http://neo.jpl.nasa.gov/neo/close.html
NASA Near Earth Orbital Object Orbital Parameters.
Sort by MOID (minimum orbital intersection Distance) 2012DA14 is #22 in the list.
http://neo.jpl.nasa.gov/cgi-bin/neo_elem?type=NEA;hmax=all;sort=moid;sdir=ASC;max_rows=20;action=Display%20Table;show=1&from=20

Gail Combs says:
February 19, 2013 at 7:07 am

Russia’s TU-95 Bear strategic reconnaisance bombers were intercepted by U.S. fighter aircraft as they entered U.S. airspace while flying in a circle around the Hawaiian Islands during their military exercise. This occurred the other day, IIRC about the time of the meteorite fall perhaps.

The next scary one… we know about… doesn’t come close until 2880, but is big enough that it could seriously disrupt life on earth. The odds are 1 in 300 of it hitting earth if it goes in one projected path, the other projected path has it missing by millions miles. Called 1950 something, was reacquired briefly in 2000 before disappearing again. Anyway, warn your Great*30 grandchildren.

mjk says:
February 18, 2013 at 6:40 pm
So we now accept the analysis of the NASA scientists do we. How ironic.
Mjk

Observations as opposed to Hansenesque advocacy, multiple arrested biased adjustments? You decide.

An ICBM would not have much effect.
Put a basketball in a pool, put a firecracker on the side as close to the water line as you can get it, set it off… how far did the ball move?
Nuclear weapons are far more impressive when you’re the size of a person compared to when you’re the size of a house or even larger, particularly when said house is hurtling through a near-vacuum at 10~20 km/s.
A large portion of the damage from a nuclear weapon is due to the presence of an atmosphere, remove the effects of the massive blast of air and you get a very diffuse particle beam. This is why the Casaba-Howitzer devices were looked at for Orion type propulsion, focusing the energy from a nuclear detonation into a jet would be far more effective than just setting them off next to the plate.
The most effective currently plausible technology which could prevent an impact with sufficient warning is to scale up something like the Dawn probe. Have it fly near the object and maintain a position relative to it, such that the tug of gravity from the probe is enough to change the course of the object.
It doesn’t take a large input if you get to it early enough, hence the value of early warning systems.

Pull My Finger says:
February 19, 2013 at 10:37 am
The next scary one…

Talk about scary, try this meteorite story. Russians searching for meteorite fragments beware.
.My Lucky Meteor – Joe Dirt (1/8) Movie CLIP (2001) HD .

Hardly a lack of thinking in general, just the lack of correlation between effectiveness at getting elected and concern for anything besides getting elected.
Putting a solar powered rocket on an asteroid isn’t necessary.
If you have that much solar collection surface there, just focus it into a beam and heat the asteroid material direction.
If you don’t, just put a machine with shovels/buckets and begin tossing hunks of asteroid into space.

Sorry, the URL got truncated. when pasted. Here it is again….

“Completely unrelated event” is pushing coincidence a tad too far. Entry vector meaningless, it probably separated quite a while ago, drifted to different track.

I seem to vaguely recall some studies of catastrophic meteorites, that they tend to come in bunches, both on large time scales, but also on millennial time scales. Something to do with gravitational cycles that disturb the Oort cloud, or the asteroid belts as well. This is a very small sample, but the coincidence of two of these things coming so close on a single day does give me some pause as to whether or not we might be entering into a period with more frequent meteorite events.
Anyone know more about such theories/observations?

“nearly 500 kilotons of energy
Especially since we are not dealing with E = mc^2, energy should be expressed in joules and not mass. ”
Answer: 500 kilotons of DYNAMITE equivalent, or at about 20,000 BTU per lbm, that would be 500,000,000*2 or one billion lbm *20,000 BTU each Lbm, or 20 Trillion BTU. That’s a lot, but since a coal plant burns about 10 million lbm/day of coal this is a 1/2 years worth of coal burning.
“A question: How much larger will the UAH anomaly be for February be due to this input?”
Answer to that, considering the SUN’s input is equivalent to about 10,000,000 of said coal plants, we have a MINISCULE rise in atm temp due to this event.

BTW, I’m not trolling – I really can’t understand it, and would be grateful if someone can let me know what it’s all about.

The answer is really pretty simple, early reports are almost always wrong, often catastrophically wrong. This is one of the biggest problems in emergency management in the early hours of an emergency to sort out the early reports and make sense of often mutually exclusive information or conflicting information. You are usually dealing with reports from unsophisticated observers, many of which have built in biases that make them jump to conclusions about what they are seeing. Even sophisticated observers called on by the media to make off the cuff comments on a breaking story often due to the lack of time to double check information, or comments based on faulty initial information occasionally make some really bone headed mistakes. Since the media is usually scientifically and mathematically ignorant they fail at their basic obligation to fact check such early observations and in the rush to get “the scoop” put out blatantly bad info.
The 18,000 mph number makes sense when you realize that that is the required speed for low earth orbit, ( 7.8 km/s or 17 448 mph the media often rounds this up to 18,000 mph in their tv coverage) and either due to lack of understanding or a poorly considered off the cuff remark that speed might have been blurted out by someone not aware that objects in near earth orbit can have approach speeds far higher than that, especially if they come from deep space like a comet. Average impact speeds for meteorites typically is in the 10-70 km/second range ( 22,370 – to 156,585 mph). For objects orbiting the sun, maximum impact speed would be about 72 km/sec (161,060 mph) but could be even higher if the object was not gravitationally bound to the sun and came in from deep space.
http://impact.ese.ic.ac.uk/ImpactEffects/
One observation regarding diverting an impending impact is I have always been puzzled that every solution always seems to be focused on a single means of avoiding impact, when there are actually several different strategies which could be used in combination. To avoid impact you simply have to arrange it so that the near earth object and the earth do not occupy the same space at the same time. You can do that by changing the velocity of the near earth object, but that is a vector quantity composed of both a speed vector and a direction vector. You can either speed it up or slow it down, or you can give it a lateral motion to change its direction. You also can ablate away some of its mass which will change its orbital path around the sun if the ablated mass has escape velocity to get clear of the near earth object.
Each object will have a minimum energy strategy to avoid collision. In one case the minimum energy solution might be to slow it down. In another the minimum energy solution might be to speed it up or tweak it sideways.
The deep impact mission shows we can rendezvous with an asteroid and arrange for it to “run over” a slower moving object with today’s technology.
One idea I never see advanced is to use a strategy like the Deep impact mission, and position a space craft so it could distribute a plume of sand like particles, or even multiple very small “smart impactors” ahead of the object, and let it run over and impact the thousands of small particles or smart impact module. Each individual impact would be too weak to break up the object and create the multiple body problem or divert it much, but the combined effect (like a car driving through a hail storm) would both transfer energy and ablate mass from the object. Like the gravity tug idea, it would be a way to slow the object and change its orbital elements by changing its mass. The optimum strategy might be to use multiple missions in succession each applying a small change in the objects velocity. Some sort of manageable impact scheme like this would allow you to slow the objects speed of motion with out changing its direction vector significantly, and would work even if the object was spinning as the small dust particles or smart impact modules would always impact on the forward face of the object determined by its orbital motion. Then with a gravity tug you could pull it to one side to augment the change caused by changing its orbital speed.
Maybe we should think about a multifaceted attack rather than any single strategy. It would also give us a more fail safe solution.
The impacting objects could take many forms, inert material, pellets of CO2, small spinning disks of light material, even high energy materials like small pellets of explosive materials where you would get benefit from both the chemical energy of the impactor and its kinetic energy of motion. Which would be more effective multiple impacts from small pellets of explosive materials, tens of thousands of small sand like particles squirted out in a stream along the orbital path or one or more spinning disks of plastic that would simultaneously vaporize across the entire front of the object as it impacted the asteroid. Perhaps a series of smart impactors each guiding a balloon filled with a gas or explosive gas mixture.
Bottom line is how do you transfer the most momentum to the object without breaking it up due to a violent impact. Would you get more bang for your buck by letting it run into a hail storm of BB’s which each would form thousands of craters and eject material from the surface or let it run into a large gas filled balloon (or even several such balloons) and change its velocity by the over pressure across the front face as it slams into the gas bag.
Larry

Thank you to all who responded to “500 kilotons of energy“. My physics students would never have gotten away with that sort of thing!

Mechanics of moving an asteroid like 2012DA14 away from an Earth collision.
An asteroid tractor (Tug) uses the mutual gravitation between the Tug and the asteroid as the tractor force. The trick is that the rocket exhaust needs to be in two or three thrusters pointing past the asteroid rather than at the asteroid. All that is necessary is that the Tug is close enough to the gravitationally weak asteroid so that the gravitational pull is enough force to do the job.
So how big does this Tug need to be? How much propellant is needed to move a 130,000 ton asteroid to miss the Earth? 1 ton? 10 tons? 100 tons? 1000 tons?
If you have 20 years, all you need is 0.1 ton. 100 kg! What is more, we can do it with off-the-shelf hardware. It can be done with a “Dawn”-like space probe with three small tri-pod ion thrusters instead of one thruster on the centerline — and lots of time. I’m amazed how little mass is necessary.
The goal is to apply a force F to move the asteroid mass m1 one Earth Radius R in a time span of T years.
R = Earth Radius: 6378000 m
Time of force = T = 20 years (thrusting time).
Time of force = T = 6.31E+08 sec
Acceleration to move R in T = a = 3.20E-11 m/sec^2 __ (from R = 0.5*a*T^2)
Mass of 2012DA14 = m1 = 1.30E+08 kg
F = ma = 4.16E-03 N = kg-m/sec2 __ About 0.001 pound force.
(a big mass * a puny acceleration = feather weight force)
How big does the Tug need be to have at least that gravitational force?
Gravitational constant = G = 6.67E-11 N-m2/kg2
Radius of 2012DA14 = r1 = 15 m __ (actual dimensions 20 m wide x 40 m long)
Tug Standoff = r1b = 45 m __ (3 times radius so that jets point over the rim)
F from accel due to gravity = G*m1*m2/r^2
If F = 0.00416 N = kg-m/sec2
minimum mass of tug at r1b = F*r1b^2/(G*m1) = m2 = 972.0 kg __(less than Dawn)
So a one ton tug 45 m from the center of a 130,000 asteroid has a can pull at 0.00416 N. If it tugs for 20 years, that’s enough for a miss.
This is a tiny force, so an Ion drive, like the Dawn and Deep Space 1 probes is ideal for minimum propellant needs.
g = 9.81 9.81 m/s²
ion Drive Specific Impulse = Isp = 3000 sec ( 4000 sec is possible)
Ion thruster exhaust velocity = Ve = 29430 m/sec
Fthrust = Isp * mdot * g = Ve * mdot
Fthrust = 0.00416 N = kg-m/sec2 (required thrust for the job above)
Propellant rate = Fthrust/ Ve = mdot = 1.41E-07 kg/sec or 0.141 milligram/sec.
Propellant mass = mdot * T = mf = 89.3 kg
Delta-V of asteroid = a*T = deltaVa = 2.02E-02 m/sec = 20 mm/sec after 20 years of tug.
Time is your friend. The amount of fuel needed goes as m1/T^2.
Check math:
Change momentum of propellant = Ve*mf = 2.63E+06 kg-m/sec
Change momentum of Asteroid = deltaVa*m1 = 2.63E+06 kg-m/sec
Thrust of Dawn: 0.09000 N 20x what is needed
mass of Dawn (full) 1240 kg ( 640 kg is propellant.)
power of Dawn 1300 W