Rhoades
Duke University Trinity College of Arts & Sciences
ASTEROID IMPACT: ANALYZING WHAT IT TAKES TO DETECT AND
PREVENT A COSMIC ASSUALT
Levi Rhoades
Math 89s: Mathematics of the Universe
Professor Hubert Bray
3-20-2016
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Introduction
Even though Bruce Willis does exist in society. The suave, courageous, and
intuitive version of Bruce Willis who is able to deflect massive asteroids away from planet
Earth is unfortunately still nonexistent. Space object collision is a topic that has recently
resurfaced in the public view because of the 2013 meteor which exploded at a height of
around 30 kilometers over Chelyabinsk, Russia injuring 1,500 people and causing
millions in property damage. NASA is currently allocated around 0.4% of the United
State’s total budget and only 0.05% of this funding is dedicated to the NEO (near earth
object) program which tracks and plans for asteroid collisions (Powell). A student at Duke
University, JJ Liao, examined in his previous paper the cost efficiency of properly funding
an asteroid defense program and concluded it would cost between 50 and 100 million
dollars a year (JJ). This passages to the topic of the genuine likeliness of a global
Armageddon by NEO, and since Bruce Willis can’t save the world; what precautions have
human’s taken as a species to prepare for, protect against, and deflect any asteroids or
comets that could potentially collide with Earth? This essay will focus on the detection
and responses to an extinction type space object colliding with the planet that are funded
by the United State’s government while providing special consideration to a novice but
procedural overview of the impact of orbital mechanics when addressing this problem.
Detection
The first step to saving mankind would be to detect the celestial satellite set to
impact. Uncovering these rocks as early as technologically possible is a key component to
survival because of both composition and response. The current method for finding and
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tracking asteroids includes the WISE (Wide-field Infrared Explorer) which emits infrared
bands at four different wavelengths to perform an all sky astronomical survey. The WISE
system has helped to discover tens of thousands of new asteroids as well as new star
clusters, but researchers still estimate that it has only discovered 2% of the NEO
population of interest (Near). In addition to the WISE system, the Canadian Space Agency
launched NEOSat (near earth object surveillance satellite) in 2013 which can hunt for
more hidden NEOs in space. However, a more simple and effective way to detect new
asteroids is available to anyone with a telescope. Backyard amateur observations of
objects in anomalous motion returned about 80 new NEO’s during the month of March,
2014. On average observations through a telescope with the human eye return about 500
more NEOs a year according to private researchers at space.com.
Detecting composition would help better prepare scientists and politicians to
appropriating defense mechanisms for the entity. Asteroids fall under three types: C
(carbonaceous), S (silicaceous), M (metallic). C-type accounts for 75% of all observable
asteroids and is dark in color and dominantly found on the outer rim of asteroid belts. S
and M type asteroids are less common and dominate the inner regions of belts, however
all types can vary in size, speed and color. Specifically, if the asteroid is classified as size
“planetismal” (less than a 100 meters in diameter) then it is likely a collection of loose
rubble bound together by gravity and formed by debris after collisions with other
asteroids. If the asteroid is larger, then it is classified as a “protoplanet” which has a
spherical and solid outline usually with a chemically differentiated interior (Shoemaker).
These composition distinctions bear weight when considering how to best diminish the
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threat of impact because a collection of smaller asteroid rubble cannot be effectively
destroyed or deflected by impact mechanisms such as a HAIV (hyperactivity asteroid
intercept vehicle) or nuclear blast (Near). In addition, metallic comets require more force
to change velocity than carbon based rocks.
Nuclear Explosive Device
The responses to asteroid collision are what fuel the scripts of blockbuster films,
and captures the minds of daydreamers everywhere. There are dozens of theories on how
to deflect or destroy an asteroid, however this paper will only focus on those considered
and funded by the United State’s government. Using a nuclear detonation to vaporize or
change the course of the objects orbit to avoid hitting Earth is the most funded approach.
In 1967 students at the Massachusetts Institute of Technology calculated the nuclear
megatonnage needed to divert a 1.4 km wide asteroid off of a collision course with Earth
given 18 months notice in a project nicknamed Icarus. It was concluded that multiple
rockets loaded with 100 megatons of nuclear energy would be needed to change the
velocity of the rocket enough to miss colliding with the surface (Shoemaker). However
Dr. Wie of Iowa State University examined the same simulation and concluded that using
a HAIV was the only method to deliver a force strong enough to divert course. The HAIV
would increase speed gradually as it moved towards the asteroid until it preformed a
kinetic impaction in which a large crater would form exposing more vulnerable center of
the asteroid composed of soft x-rays and neutrons. Then the rockets would be fired to
strike this crater and disable the threat. Dr. Wie expressed his confidence in this method in
2014, “For example, according to their computer models, with a warning time of 30 days
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a 1,000-foot-wide (300 m) asteroid would be neutralized by using a single HAIV, with
less than 0.1 percent of the destroyed object's mass potentially striking Earth” (Planetary).
See image:
Furthering the nuclear method is the standoff approach which is particularly
effective against smaller asteroids which are composed of loose rock pieces held together
by gravity. A head on nuclear explosion would likely scatter some rocks into
unpredictable orbits and not contact enough surface area of the larger rocks to have a
palpable impact on their trajectory. However detonating a bomb at a 20 meter or greater
stand off height would circumvent the splitting of already fractured material (Preparing).
However because the standoff method uses less force it would need to be employed very
prematurely in the progress of the asteroid or would require a greater multitude of blasts
for a rock with a short travel period.
Currently the nuclear warhead B53 is the only publically known weapon possessed
by the United States with a great enough energy yield to be effective against an asteroid of
size protoplanet or greater. The Comprehensive Nuclear-Test Ban treaty of 1996 also bans
the use of all nuclear weapons. However, it is likely that these prohibitions would be
temporarily uplifted if a large scale collision was inevitable and could cause a significant
loss of life.
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Kinetic Impact/Gravity Tractor
Another option for redirecting the celestial body includes using a large unmanned
space craft to change an orbit through impact or explosive deflection. In the kinetic impact
model, an object with extremely high mass and low brittleness would be sent onto a
collision course with the asteroid attempting to rebound it from its current course. A
NASA analyst in 2007 stated why he believes that kinetic impactions are the future of
asteroid protection, “Non-nuclear kinetic impactors are the most mature approach and
could be used in some deflection/mitigation scenarios, especially for NEOs that consist of
a single small, solid body” (Lincoln). The European Space Agency is currently running
simulations for a 2020 mission which would see two aircraft (AISA, and Don Quijote)
perform the first asteroid deflection although funding is limited. One of the limitations of
the kinetic impact model is the cost efficiency because the spacecraft requires enormous
amounts of size and fuel and cannot be recovered after the mission.
The asteroid gravity tractor is the final U.S. research-funded response although it is
by far the most expensive and immature program of all defense systems. Essentially a
rocket with an extremely heavy mass would locate and begin to orbit the asteroid, and
because these two bodies are mutually attracted to each other due to gravity the rocket
could begin to counteract this force by flying away from the asteroid and pushing with the
rocket’s ion thrusters. Over a long period of time, researchers estimate years, the asteroid
would accelerate towards the spaceship diverting its course from an Earth impact.
See image:
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The Future of Development/Orbital Mechanics
In a case study by Dr. Izzo, Dr. Yam, and Dr. Olympio of the ESA they analyzed
the orbital mechanics required to properly deflect an asteroid named Epcoch headed
towards collision in the year 2030. The following equation shows variables accounted for
during the shift of the asteroid Epcoch which was set to a collision with earth following its
current orbit:
∆r = 3a µ vast,te (te − t0)(vast,t0 · ∆V)
In this model ∆r is the deflection distance, ∆V is the change in velocity, a is acceleration
and te is the time Epcoch is experiencing relative to the time the Earth is experiencing
Epcoch. The change in deflection ∆r is vested primarily in the amount of force applied to
the object (Lu). In spite of this asteroids sometimes fly as groups of smaller rubble and are
prone to fracture, so these calculations can only be attributed to ideal conditions. Another
factor that researchers are considering on the impact of deflection is the color of the
asteroid. Asteroids of lighter colors such as type S or M will over time emit more and
more photons than a similar type C rock. These photons, while small carry some
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momentum and overtime can affect the orbit of the asteroid. This is another instance of
detection being so important to the process of defense.
The future of asteroid defense advances can best be attributed to the vision of
former astronaut Ed Lu. Dr. Lu is the founder of the B612 foundation and has donated 50
million dollars towards asteroid detection research in the fiscal year of 2016. This figure is
on par with what my colleague J.J. Liao estimated was required for defense and is also 10
times more than NASA was spending on the same project in 2010 (JJ, Powell). B612
hopes to launch a new infrared telescope into space named Sentinel which could detect
objects as small as 30 meters across. This improvement in detection is due to Dr. Lu’s
distrust in nuclear deflection or obliteration. Dr. Lu argues that detecting a collision
headed celestial rock years in advance would afford mankind with the luxury of trying
several different more stable and gradual approaches such as a tractor beam or the gradual
thrust method. He is also voiced his concerns on twitter that an asteroid heading for earth
could become weaponized through the strategic deflection or collapsing of the rock so as
to target impacts in specific countries.
See image:
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Conclusion:
Asteroid defense and exploration is a topic that should be taken seriously and
regarded with a moderate sense of urgency. Although no human has been killed by an
asteroid or its impact in the last 1000 years, the blast above Chelyabinsk proved once
again to the public that we do not have the solar system mapped out completely, and that
many NEO’s have slipped through the cracks of documentation because of insignificant
funding and muted necessity (Powell). The current primary methods of defense include
nuclear strikes, kinetic impaction, and gravity tractors all of which are untested and
relatively juvenile in their production. As space exploration develops in the rest of the 21st
century, asteroids both in mining and defense will become an integral tool in the
development of the knowledge of the cosmos. When considering man-made interaction
with an asteroid it is important to consider its size, type, and color as well as document its
acceleration, time in space, and velocity to consider the applied force of its movement.
Asteroids are are region of space like many others that mankind is still very in the dark
about. However, since so many are flying so close it might not be a bad idea to go learn
something about them considering Bruce Willis may not be around that much longer.
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Works Cited
"Lincoln Near-Earth Asteroid Research (LINEAR)". National Aeronautics and Space
Administration. 23 October 2007.
Lu, Edward T.; Love, Stanley G. (2005). "Gravitational Tractor For Towing Asteroids".
Nature 438: 177–178.
"NASA Releases Near-Earth Object Search Report". National Aeronautics and Space
Administration. Retrieved 2007-10-23.
Near-Earth Object Survey and Deflection Analysis of Alternatives Report to Congress March
2007
Planetary Defense Conference 2007, Wahington D.C. Head-On Impact Deflection of NEAs: A
Case Study for 99942 Apophis. Bernd Dachwald, Ralph Kahle, Bong Wie, Published in
2007.pg 3
Powell, Corey S. How to Deflect a Killer Asteroid: Researchers Come Up With Contingency
Plans That Could Help Our Planet Dodge A Cosmic Bullet, Discover website, September
18, 2013 (subscription required), and in print as "How to Dodge a Cosmic Bullet",
October 2013. Retrieved July 15, 2014.
"Preparing for an Asteroid Strike." European Space Agency. N.p., n.d. Web. 28 Mar. 2016.
Shoemaker, E.M., 1995, Report of the Near-Earth Objects Survey Working Group, NASA Office
of Space Science, Solar System Exploration Office