Monopoles are magnets with just one charge (so positive or negative only).
We probably won't be using them here, as they likely aren't possible to make, but if they were possible there are some applications:
Taken from: https://www.frc.ri.cmu.edu/~hpm/project.archive/general.articles/1981/monpol.mss
----
Notes on Magnetic Monopole Applications
Hans P. Moravec
July 1979
Monopole technology - Magnetic monopoles are predicted by some
quantum field theories of atomic forces. Although they have not been
found yet, there is good reason for that since they would be very heavy
and therefore hard to make. If they could be made in quantity, there
would be a complete revolution in our technology. Efficient electric
motors, high density energy storage, high temperature superconductors,
ultra-strong fibers and armor plate, and high density matter, are just a
few of the many possibilities.
I derived the the supposed properties of monopolium from a very
small number of facts, which were published in the semi popular press
around the time the Berkeley group claimed to have found a monopole track
in their cosmic ray balloon:
Dirac's calculation that the magnetic quantum of charge is a
positive integer multiple of 137/2 times as mutually attractive as the
electric quantum.
The predictions of some gauge theories that monopoles exist and
the smallest weigh about 1000 protons (which puts them beyond the reach of
existing accelerators, but within Batavia running colliding beam, expected
in the middle to late 80's).
Analogy with conventional matter. There may be at least two non
mutually anihilating stable kinds of monopoles that could be used to build
monopole atoms. Because the monopole electron weighs at least 1000 protons
= 2,000,000 regular electrons, the diameter of a monopole atom should be
about 2 million times smaller than that of a conventional atom. Since the
monopole proton is also AT LEAST 1000 times as heavy as a regular proton,
a monopole atom weighs 1000 times as much. The combination of size and
mass makes monopolium 1000x(2,000,000)^3 = 10^22 times as dense as normal
matter.
The mutual interaction between a pair of atoms is inverse square
in their separation. Monopole atoms are 2 million times as close as
conventional atoms. The number of monopole atoms in a given cross
sectional area is (2,000,000)^2 times as high. Combined with increased
attraction due to the magnetic quantum being (68.5)^2 as strong as
electric, the tensile strength of monopolium is (2,000,000)^4x(68.5)^2 =
10^29 as high as normal.
The strength to weight ratio is thus about 10 million times as
high.
This reflects the fact that monopole chemistry is a energetic per
unit mass as nuclear fusion and fission of conventional matter.
The first quantum jump in a monopole electron orbital involves a
hard gamma ray. Thus at mild temperatures (anything less than a million
degrees, say), monopolium should be a potential superfluid,
superconductor, etc.
It should be possible to overlay structures of conventional matter
with a thin (very very thin) veneer of monopolium to protect them against
virtually everything except a projectile of monopolium moving at very
nearly the speed of light. (general products hulls!).
Superconducting monopole mirrors probably reflect everything up to
the the energy of proton-antiproton anihilation gamma rays.
The extreme density permits very small and very fast (about 10
million times as fast as conventional) monople integrated circuits and
computers. The RF frequencies involved would be in the gamma ray range.
Mixing electrically and magnetically conducting matter causes DC
transformers (two loops of wire threaded through a tiny monopole anulus).
An inductive storage battery, with nuclear energy density (a
superconducting monopole conductor plated on an ordinary wire).
The interactions in a single material containing both free
electric and magnetic charges (two dimensional currents, etc). sound like
they'd be full of possibilities, but I havn't cleared my thoughts on that.
Another possibility is a new kind of matter where there is no
nucleus, but where the orbits of monopoles and charged particles interlock
like links of a chain.
We probably won't be using them here, as they likely aren't possible to make, but if they were possible there are some applications:
Taken from: https://www.frc.ri.cmu.edu/~hpm/project.archive/general.articles/1981/monpol.mss
----
Notes on Magnetic Monopole Applications
Hans P. Moravec
July 1979
Monopole technology - Magnetic monopoles are predicted by some
quantum field theories of atomic forces. Although they have not been
found yet, there is good reason for that since they would be very heavy
and therefore hard to make. If they could be made in quantity, there
would be a complete revolution in our technology. Efficient electric
motors, high density energy storage, high temperature superconductors,
ultra-strong fibers and armor plate, and high density matter, are just a
few of the many possibilities.
I derived the the supposed properties of monopolium from a very
small number of facts, which were published in the semi popular press
around the time the Berkeley group claimed to have found a monopole track
in their cosmic ray balloon:
Dirac's calculation that the magnetic quantum of charge is a
positive integer multiple of 137/2 times as mutually attractive as the
electric quantum.
The predictions of some gauge theories that monopoles exist and
the smallest weigh about 1000 protons (which puts them beyond the reach of
existing accelerators, but within Batavia running colliding beam, expected
in the middle to late 80's).
Analogy with conventional matter. There may be at least two non
mutually anihilating stable kinds of monopoles that could be used to build
monopole atoms. Because the monopole electron weighs at least 1000 protons
= 2,000,000 regular electrons, the diameter of a monopole atom should be
about 2 million times smaller than that of a conventional atom. Since the
monopole proton is also AT LEAST 1000 times as heavy as a regular proton,
a monopole atom weighs 1000 times as much. The combination of size and
mass makes monopolium 1000x(2,000,000)^3 = 10^22 times as dense as normal
matter.
The mutual interaction between a pair of atoms is inverse square
in their separation. Monopole atoms are 2 million times as close as
conventional atoms. The number of monopole atoms in a given cross
sectional area is (2,000,000)^2 times as high. Combined with increased
attraction due to the magnetic quantum being (68.5)^2 as strong as
electric, the tensile strength of monopolium is (2,000,000)^4x(68.5)^2 =
10^29 as high as normal.
The strength to weight ratio is thus about 10 million times as
high.
This reflects the fact that monopole chemistry is a energetic per
unit mass as nuclear fusion and fission of conventional matter.
The first quantum jump in a monopole electron orbital involves a
hard gamma ray. Thus at mild temperatures (anything less than a million
degrees, say), monopolium should be a potential superfluid,
superconductor, etc.
It should be possible to overlay structures of conventional matter
with a thin (very very thin) veneer of monopolium to protect them against
virtually everything except a projectile of monopolium moving at very
nearly the speed of light. (general products hulls!).
Superconducting monopole mirrors probably reflect everything up to
the the energy of proton-antiproton anihilation gamma rays.
The extreme density permits very small and very fast (about 10
million times as fast as conventional) monople integrated circuits and
computers. The RF frequencies involved would be in the gamma ray range.
Mixing electrically and magnetically conducting matter causes DC
transformers (two loops of wire threaded through a tiny monopole anulus).
An inductive storage battery, with nuclear energy density (a
superconducting monopole conductor plated on an ordinary wire).
The interactions in a single material containing both free
electric and magnetic charges (two dimensional currents, etc). sound like
they'd be full of possibilities, but I havn't cleared my thoughts on that.
Another possibility is a new kind of matter where there is no
nucleus, but where the orbits of monopoles and charged particles interlock
like links of a chain.
