Are Superconductors the Future?
by Jacob Eapen
Chapter 4
Superconductivity
What is superconductivity? Superconductivity is a phenomenon in which materials conduct electricity without any resistance.
Electrons
Electrons can detach itself from an atom and be
independent of itself. An atom can only be stable if it has the
same number of positive and negative charges. When an electron,
which has a negative charge, detaches from an atom, the atom
becomes unstable. Since there are more positive charges than
negative charges, the atom becomes positive. The positive atom is
now called an ion.
Lattices
If you would be able to look at a metal conductor with a very
powerful microscope you would be able to see framework in neat
patterns of ions. This is called a "lattice." In the
lattice, the ions are jiggling and the electrons are moving in
random directions. If you were to lower the temperature the
movement of the ions and electrons will begin to slow down.
Resistance
If you were to apply pressure to a metal conductor of electricity
the electrons would move in the direction pushed. The electrons
will eventually hit the ions; making the electrons ricochet off
of the ions.
When the electrons collide with the ions it creates heat. Heat is something we do not want in transferring electricity. Energy is wasted by the collision of electrons. This is called electrical resistance.
The Discovery of Superconductivity
To reduce energy lost we can lower the temperature because as the
temperature is lowered the atoms and electrons slow down,
reducing the chance of the electrons hitting the atoms.
In April 1911, Heike Kamerlingh Onnes was experimenting with the resistance of mercury at temperatures close to absolute zero. He noticed that not only did the electrical resistance begin to lessen, but at 4.15K mercury had lost all resistance. The temperature at which materials become superconductive is called the critical temperature. Common elements are classified as type I superconductors.
The table below shows the critical temperatures of some type I superconductors.
| Element | Critical Temperature (K) |
| Mercury | 4.153 |
| Lead | 7.193 |
| Aluminum | 1.196 |
| Tin | 3.722 |
| Tungsten | 0.015 |
| Zinc | 0.85 |
| Titanium | 0.39 |
Critical Magnetic Field
Kamerlingh Onnes discovered that when elements are put in a
magnetic field the critical temperature lowers. When a magnetic
field is increased to a certain value, or critical magnetic
field, superconductivity completely goes away. The critical
magnetic field of mercury is 0.041 Teslas and the critical
magnetic field of lead is 0.08 Teslas. (A Tesla is a unit if
measurement to measure the strength of magnetic fields). For
comparison, the magnetic critical field of the Earth is 0.00005
Teslas.
This discovery discouraged scientists because it is impossible to avoid magnetic fields. If a magnetic field is strong enough it can destroy a material’s superconductive state. This is called the critical current.
Type II Superconductors
The 1950s and 1960s was a time when scientists searched for
superconductors with higher critical temperatures. A new group of
superconductors were found which had the element Niobium in it.
Superconductors that have more than one element in it is called
intermetallic superconductors. Intermetallic superconductors are
classified as type II superconductors.
The list below tells the critical temperature of some type II superconductors.
| Element | Critical Temperature (K) |
| Nb3Sn | 18.0 |
| Nb3Al | 18.7 |
| KNb3Ge | 23.2 |
| NbTi | 10.0 |
| Nb3Ga | 20.0 |
The Meissner Effect
In 1933 Walther Hans Meissner and Robert Ochsefeld discovered
that when type I superconductors are lowered below their critical
temperature all interior magnetic fields are gone. The expulsion
of all magnetic fields from the interior to the exterior of the
superconductor is called the Meissner effect. An example
of the Meissner effect is the demonstration in which a magnet is
repelled by a superconductor.
The BCS Theory
In 1957 John Bardeen, Leon Cooper, and John Robert Schrieffer
explained why superconductivity loses all resistance, known as
the BCS theory. For their findings they shared the Nobel
Prize in physics in 1972.
The BCS theory states that single electrons do not carry an electric current, but paired electrons do. These pairs are called Cooper pairs.
How can two negative electrons attract to each other? The reason is because when an electron collides with a positive atom it deforms it resulting with a small concentration of positive charge on the electron. Eventually an electron with some positive charge on it is attracted to another electron, forming a Cooper pair. The Cooper pairs flow around impurities and imperfections in the lattice. This results in no electrical resistance.
Copyright © 1998 Jacob Eapen. All Rights Reserved.