Magnetic Field Shocklessly Shoots
Pellets 20 Times Faster than Bullets
Source: Sandia National Laboratories ALBUQUERQUE, N.M. - A magnetic field that accelerates
pellets faster than anything except a nuclear explosion has been
developed experimentally at the Department of Energy's Sandia National
Laboratories.
The machine that generates the field has been jokingly dubbed "the
fastest gun in the West," but the description is an understatement.
"It's the fastest gun in the world," says Sandia
physicist Marcus Knudson, lead scientist on the project. The
propulsion speed of 20 km/sec - almost three times that necessary to
escape the gravitational pull of the Earth (about 7 km/sec) - would
send material from New York to Boston in half a minute, and from
Albuquerque to Santa Fe in a few seconds. A rifle bullet is typically
propelled at 1 km/sec.
The machine, Sandia's Z accelerator, currently propels
dime-sized pellets called flyer plates only a few hundred millimeters
to gain information on the effect of high-velocity impacts. The data
gained can be used to simulate the effect of flying space junk
impacting the metal skin of an orbiting observatory traveling in the
opposite direction. The data is expected to aid materials scientists
trying to balance lightness against strength for satellite and
observatory shells.
The technique also has potential as a hypervelocity
"kinetic kill" weapon that, emanating from a lighter, more mobile
source than the huge Z machine, still could strike disabling blows
through an adversary's heavy armor. These more mobile sources are
already in development. Perhaps most importantly, though least
dramatically, the technique is the fastest, most accurate, and
cheapest method to determine how materials will react under high
pressures and temperatures. These characteristics can then be
expressed in formulas called "equations of state" - equations that
tell researchers precisely how materials will react if basic
conditions like pressure and temperature are changed by specific
amounts.
While not a favorite topic for most people, accurate
knowledge of equations of state is essential for the U.S. to maintain
its nuclear weapons without physically testing them. The maintenance
program, called "science-based stockpile stewardship," uses the most
powerful computers in the world to predict the result of unimaginably
high temperatures and pressures upon materials. Accurate predictions
depend on accurate input about the characteristics of those
materials - that is, by a full knowledge of their equations of state.
Researchers currently are unable to determine these
material characteristics except by the less accurate, more expensive
methods of impacting test materials with laser beams, or at lower
energies with projectiles from gas-powered guns.
The propulsion technique works by applying the Z machine
's 20 million amps to produce an evolving magnetic field that expands
in approximately 200 nanoseconds to reach several million atmospheres
pressure. The relatively gentle acceleration produced by the field is
similar to that which might be experienced in a smoothly rising
high-speed elevator, rather than from the shock imparted by a firearm.
Accelerated to 13 km/sec, the plates are neither
distorted, melted, nor vaporized, as they would be if shot from a gun.
When the plate is accelerated to a speed about 20 times faster than a
bullet, or 20 km/sec, the more forceful acceleration needed to reach
higher velocity causes temperatures of 2,500 K to occur in the flyer
plate; this liquefies aluminum flyer plates.
Better understanding of launch configurations is
expected to eliminate this problem, though liquidation still is
superior to the worst alternative of vaporization - the result if
conventional acceleration could be used to reach these speeds. (No
power can be delivered from a vaporized pellet.) Characteristics of
copper and titanium plates are also being investigated.
The plates are accelerated in the vacuum chamber at the
core of Sandia's Z machine, the most powerful producer of electrical
discharge on Earth. Sandia scientists last year used Z's enormous
magnetic field to test materials by compressing them - a method called
isentropic compression.
In this even newer technique, staggering the firing of Z
's 36 lines eliminates the shock that melts the flyers at the higher
velocities. The resultant expansion of the powerful magnetic field is
used to propel small objects somewhat the way a surf boarder is
propelled who catches one of a succession of enormous waves.
A paper accepted by the Journal of Impact Engineering
describes techniques that accelerated the plates to 13 km/sec.
A paper to be submitted this spring to the Journal of
Applied Physics shows how improving the configuration of the loads
increased the speed of the flyer plates to 20 km/sec.
The work is funded primarily by DOE.
http://www.sandia.gov/media/NewsRel/NR2001/flyer.htm