The Perfect Couple In other words, how does one nuke an asteroid and make sure to obliterate it so thoroughly that the bits won't kill us like a shotgun blast? ? ? When scientists debate methods for blowing up asteroids, they speak in terms of “energy coupling”—how much of the explosive energy is transferred to the target, and the effect of that energy as it travels through the asteroid. And that’s why the composition of an asteroid can be crucial. Consider an asteroid whose orbit would place it on a collision course with Earth in ten years. At that distance, changing its velocity by just a centimeter per second (0.02 miles per hour) could nudge it enough to avert disaster. One way to do this would be a kinetic impactor—a high-speed spacecraft that would crash into the asteroid, delivering energy by dumping its momentum. But, here’s the catch: The larger the asteroid, the more massive the spacecraft would need to be to knock it off course. And there's a limit to how much mass we can launch to an asteroid. That’s when a nuclear weapon might be the better choice. A spacecraft could deliver a nuke that would explode near the asteroid, irradiating a large fraction of its surface with x-rays and neutrons. “Those heat up the surface of the asteroid to very high temperatures, vaporize it—and then the blow-off momentum from that vaporized material imparts a gentle change in velocity to the asteroid,” says Megan Syal, a researcher at the Lawrence Livermore National Laboratory in California who is working on planetary defense scenarios. But, Syal adds, the same blast wouldn’t affect all asteroids the same way. If the surface of the asteroid contains light elements such as water-enriched minerals or water ice, the x-rays and neutrons will penetrate more deeply than an asteroid whose surface is metallic. “It’s harder to couple energy as efficiently in those cases,” says Syal. Bombs Away The worst-case scenario might be if we discovered an asteroid only a couple of weeks away from slamming into us. Brent Barbee, a flight dynamics engineer at NASA’s Goddard Space Flight Center, believes he has the answer: an interplanetary ballistic missile. Barbee and Bong Wie, the founding director of the Asteroid Deflection Research Center at Iowa State University, conducted a three-year study on the feasibility of rapidly intercepting and nuking an incoming asteroid. In their scenario, we don’t have time to deflect the asteroid. Their proposed solution: a ready-to-launch spacecraft—the Hypervelocity Asteroid Intercept Vehicle (HAIV)—that would penetrate its surface. And, no, they didn’t get the idea from Bruce Willis and his intrepid band of space oil riggers in the film Armageddon. Previously published studies have examined the potential use of ground-penetrating nuclear weapons as bunker busters here on Earth. One such study estimated that an underground nuclear explosion would be at least 20 times more effective than a detonation very close to the surface. But the same research also revealed a technological hitch: The bomb’s fusing mechanism would be destroyed if its impact velocity were greater than 671 miles per hour (300 meters per second). And in a scenario with an asteroid less than a few years away, the weapon would have to travel much faster than that, from 22,000 to 67,000 miles per hour (10 to 30 kilometers per second) relative to the target asteroid. As a result, no detonation upon impact. Barbee and Wie worked around the problem by designing a two-piece spacecraft. The top craft, a kinetic interceptor, would smash into the asteroid to create a crater. The second craft, containing the nuclear explosive, would then enter that crater, detonating before hitting the bottom—Bruce Willis not required. Mounted atop an expendable rocket, the HAIV becomes a missile that its designers say—with as little as three weeks' warning—could intercept and destroy an asteroid as large as 140 meters in diameter, dispersing the fragments a safe distance from Earth. Barbee and Wie say that it would cost roughly $500 million to test-fly the HAIV (loaded with ballast as a stand-in for the nuclear device) and target an actual asteroid. To date, NASA has not funded it. Eyes in the Sky While these simulations allow us to plan ahead, they’re only as useful as the data we’d be able to gather about an incoming asteroid. Right now, for instance, we can use telescopes to study the composition of an asteroid by peering at the sunlight on its surface, where the wavelengths of reflected light vary based on the types of minerals present. To learn more, we’d need the celestial equivalent of “boots on the ground”—a space probe. “We would always prefer to be able to deploy a robotic precursor spacecraft to the asteroid,” says Barbee, “to go scan it with sensors, figure out what it's made of, and collect enough data to accurately determine its orbit.” Soon, we’ll have a preview of what such a mission would look like. In 2016, NASA plans to launch OSIRIS-REx, which will survey an asteroid named Bennu and then return to Earth, carrying a tiny sample of the asteroid with it. One reason that NASA chose Bennu for closer study is that there’s a chance it will collide with Earth sometime between 2175-2196 AD. (You’re welcome, 22nd century.) The spacecraft's measurements will also help astronomers more precisely predict the orbits of other near-Earth objects. (See this video to learn how sunlight can gradually change an asteroid's course.) Still, even if we dispatched a robotic scout to scrutinize an approaching asteroid, some uncertainties would remain, Syal notes. Given that asteroids are oddly shaped rocks that are constantly rotating, it could be difficult to deploy an impactor or nuke at the precise place where the topography and geological composition would yield an optimal explosion. Perhaps the greatest obstacle to sending a robot ahead, though, is time—as in, the lack of it. If the asteroid is a decade or less away from Earth, the highest priority is to deflect or destroy it as soon as possible. But, that could change if we launched a space-based telescope to catalog all near-Earth objects—an endeavor that Morrison says could be completed in as little as five years. Ideally, astronomers would be able to identify asteroids on a potential collision course with Earth. By tracking those, they could better predict the chances of impact and when. That could provide enough time to study the asteroid in more detail and develop an effective defense plan. And, if we could deflect an asteroid soon enough, it might negate the need for nukes altogether. A space telescope optimized for this task is currently under development at NASA’s Jet Propulsion Laboratory. It’s called NEOCam (Near-Earth Object Camera), and its motto is, “Finding asteroids before they find us.” If funded, NEOCam would cost $500 million to build and launch. That’s a bargain, when you consider the scope of what it could accomplish. An ounce of prevention is worth kilotons of cure.

cool design and info packed.

very nice images and info

Actually, the best thing that could happen is that the asteroid or meteor would actually strike the earth and end the issue of climate change, deliberate extinction of animals and plants that are vital to the ecology of the world. - Something akin to hitting the reset button and not saving the game. Fabulous discussion and narrative You have to admit that in Armageddon, they did show some of the smaller pieces of the big rock hitting the earth

Okay, your image looks like a very COOL 1980's video game!!! Excellent Work!!! Now after reading your commentary I don't want to go outside without wearing a hardhat!!! Very Cool Stuff!!!

Awesome info!!!... one watches these movies and sees all kinds of crazy ideas... when the most simple ones are the best!... best just to give it a little nudge! great work!!

Interesting and good work !!

WOW

That is the most interesting and awe inspiring read that I have had in years Magik.

Awesome info MU!!!!

Yes, life has always been hazardous. Once a reliable method to divert an asteroid or planetoid is found, it could also be used to have it hit the main city of the foe. Never underestimate the malice of madmen. For good or bad, we're yet far away from a reliable means.

Splendid done my friend!!!Bravissimo!:DDD.Hugsxx Whylma

interessant

Magik, je apprécié cette image étonnante. Je ne savais pas que les météores étaient une si grande menace, et vous nous avez appris beaucoup de choses. Merci d'avoir pris le temps de créer ces présentations éducatives. Les illustrations ont rendu plus facile à comprendre.

It's all part of being alive. Will I eat a smaller fish, or be eaten by a bigger one. We all die sometime, and getting smashed by an asteroid is as good a way as any. LOL

WOW, that is so amazing. xx

Impressive

É impressionante o sua narração sobre os asteróides,dá medo só de pensar que todos eles estão lá no espaço e podem vir em direção a terra,o que mais me preocupa é o que acontece aqui neste momento na terra o homem esta destruindo o planeta,o clima não é mais o mesmo,aqui no Brasil não tem mais inverno e nem primavera,nem outono,no verão o calor é insupórtável,não vai ser asteróides que irão destruir a terra ,e sim o próprio ser humano. AS cenas que você fez meu amigo são fantástica ,a sequencia é perfeita.++++++++++++++++5

I liked your drawings Réal and a kiloton of information included. I have been to the Meteor Crater in Arizona and stood on the viewing platform in awe of the hole that it left in the desert. I'll have to look around and see if I can find the photo I took!

Looking back at some of the decisions made, and/or information dismissed or ignored, if the asteroid was closer than 10 - 20 years, we'd be toast. The "decision makers" would be so busy arguing and stroking their egos, the thing would wipe the planet clean before any plan could be formulated, much less put into action. cool graphic, Real!