There is another advantage to using a really massive ballast. It allows use of a shorter cable. If we hang a big ballast weight out at, say 80,000 kilometers, there is no need to extend cable beyond that point. Another modest-sized asteroid, say a kilometer across, will do nicely for ballast. It will mass up to a billion tons.
We have not mentioned the source of energy to power the whole system. That could be provided by a solar power satellite, but will more likely be a fusion plant, sitting on the beanstalk at a geostationary orbit location. Superconducting cables run the length of the beanstalk, and can if appropriate provide power to the ground as well as running the motors on the space elevator itself. Since any energy used in the drive train to take mass up the beanstalk can be recovered by making the same mass do work as it comes down, a remarkably efficient system is possible. And by using the beanstalk as a slingshot, we have the energy-free launch system for payloads going to destinations anywhere in the solar system.
Any engineering structure has vulnerabilities, and the beanstalk is no exception. It easily withstands the buffeting of winds, since its cross-sectional area is minute compared with its strength; and the perturbing forces introduced by the attraction of the Sun and Moon are not enough to cause trouble, provided that resonance effects on the structure are avoided in its design. Accidental severing of the cable by impact with an incoming meteorite would certainly be catastrophic, but again the small cross-section of the cable makes that a most unlikely event.
In fact, by far the most likely cause of danger is a man-made problem: sabotage. A bomb exploding halfway up the beanstalk would create unimaginable havoc in both the upper and lower sections of the structure. All security measures will be designed to prevent this.
Alternative forms of beanstalk
There are two pacing items that decide when we can we build a beanstalk: the availability of strong enough materials, and a substantial off-Earth manufacturing capability. However, the first of these applies only to the “basic beanstalk” used in this novel. We now consider some interesting alternatives which remove the need for super-strong materials. We will term these alternatives the rotating beanstalk and the dynamic beanstalk.
The rotating, or non-synchronous, beanstalk was suggested in 1977, by Hans Moravec. It is a shorter stalk, non-tethered, that moves around the Earth in low orbit and dips its ends into the Earth’s atmosphere and back a few times a revolution. The easiest way to visualize this rotating structure is to imagine that it rolls around the Earth’s equator, touching down like the spoke of a wheel, vertically, with no movement relative to the surface.
Payloads are attached to the ends of the stalk at the moment of closest approach to the ground. But you have to be quick. The end of the stalk comes in at about 1.4 gees, then whips up and away again at the same acceleration.
The great virtue of the rotating beanstalk is that it can be made with less strong materials, and it would be possible to construct one today using graphite whiskers in the main cable. The taper factor is about ten. There is, of course, no need to have such a rotating stalk in orbit around the Earth. It could be sitting in free space, and as such it would serve as a “momentum bank.” It can provide momentum to spacecraft and thus forms a handy method for transferring materials around the solar system.
The dynamic beanstalk, which I think of an “Indian Rope Trick” for reasons I will give later, is an even nicer concept than the rotating beanstalk. It is not clear who first had the idea. Marvin Minsky, Robert Forward, and John McCarthy all seem to have had a hand in it, and I think I did the first analysis of its stability.
The dynamic beanstalk works as follows.
Consider a continuous stream of objects, such as steel bullets, launched up the center of a long, evacuated vertical tube. Suppose that the initial speed of these bullets is very high, faster than Earth’s escape velocity. This could be arranged using an electromagnetic accelerator at and below ground level. Suppose also that the tube is surrounded by the coils of a linear induction motor, so that there is electromagnetic coupling between the motor’s coils and moving objects within the tube.
Now, as the bullets ascend they are slowed by gravity; however, they can be given additional slowing by electromagnetic coupling. When this is done, the rising bullets transfer upward momentum to the surrounding coils.
At the top of the long tube (it can be any length, but let us say that it runs to geosynchronous altitude) the bullets are slowed and brought to a halt. Then they are moved over to another evacuated tube, parallel to the first one, and allowed to drop down toward the surface. As they fall they are accelerated downward by another set of coils surrounding the tube. Again, the result is an upward transfer of momentum to the coils. At the bottom, the bullets are slowed, caught, given a large upward velocity, and moved back into the original tube to be fired upward again. We thus have a continuous stream of bullets, ascending and descending in a closed loop.
If we arrange the initial velocity and the rate of slowing of the bullets correctly, the upward force contributed by the bullets at any height can be made to match the total downward gravitational force at that height. The whole structure stands in dynamic equilibrium, and it has no need for any super-strong materials.
Note the word “dynamic.” This type of beanstalk requires a continuous stream of bullets, with no time out for repair or maintenance. This is in contrast to our basic “static beanstalk,” which can stand on its own in stable equilibrium, without requiring dynamic elements, or the rotating beanstalk, which will also continue to operate without requiring an engine.
One advantage of a dynamic beanstalk is that it can be made of any length. A prototype could stretch upwards a few hundred kilometers, or even just a few hundred meters. In any case, seen from the outside there is no indication as to what is holding the structure up; hence the “Indian Rope Trick” label. Such a beanstalk would still be most useful if it went all the way to geosynchronous orbit, since at that height materials raised with the beanstalk can be left in position without requiring an additional boost to hold a stable orbit; but it doesn’t have to be made that way.
It is tempting to rule out the dynamic beanstalk on “environmental” grounds. What if the drive were to fail, and the whole thing come crashing down from space?
And yet we are quite used to systems that must keep working successfully, or suffer catastrophic failure. Two hundred years ago, our ancestors would have been appalled at the idea of hundreds of tons of metal hanging above their towns, operated by an engine that had to operate perfectly or the whole thing would fall. Given the technology of the day, they would have been right to be afraid.
Yet we live with such a situation every day. We have aircraft flying over us all the time, but we seldom think about the possibility that one will come crashing down on top of us. We have faith in today’s technology. Our grandchildren will have faith in a much greater technology, whose failure rates will be unimaginably lower than today. Machines and structures that are seldom inspected now will be under continuous computer supervision, including smart sensors in all their key components.
In that future environment, static beanstalks, rotating beanstalks, and dynamic beanstalks, or some later invention that supersedes all of them, will be both technologically feasible and socially acceptable. I think we are closer to a dynamic beanstalk, today, than we were to successful space flight in 1900.