The Mystery Of High Temperature Superconductivity
Understanding High Temperature Superconductivity.
So much of the energy that we generate is lost to inefficiencies and resistance in the wires or conductors through which the electrons travel. It doesnt mater if the electricity is made from coal,natural gas, wind,nuclear or solar technologies when it comes to transport losses.
Transport losses are those losses associated with the difficultly of electron movement.
If we could somehow engineer a material that perfectly allows electrons to travel through it we would reduce these transport losses to zero. If we could do it while the material is at room temperature it would extend our generation resources by a wide margin.
This scenario that we described is what is known as room temperature superconductivity.Research for now is mostly focused around high temperature superconductivity.
Superconductivity with a high critical temperature (high Tc) continues to present a theoretical mystery. While this phenomenon is experimentally well established, no scientist has managed to explain its mechanism. In the late 90’s, the British physicist Anthony Leggett proposed a scenario based on the Coulomb energy. Today, researchers at the University of Geneva (UNIGE), Switzerland, in collaboration with Leggett and his group, committed to test this scenario. Their findings challenge Leggett’s conjecture, opening new avenues for the explanation of high Tc superconductivity.
These results are available in the journal Physical Review X.
Superconductivity is at the heart of intensive research in physics, in particular because of its remarkable electronic properties, such as the absence of electrical resistance. Its properties make it an indispensable element for applications in medicine, as well as in transportation and energy storage.
In the late 90’s, Prof. Leggett of the University of Illinois presented a scenario for high Tc superconductivity in the cuprates, materials consisting primarily of copper and oxygen. In his scenario, the transition of the material into the superconducting state is a direct consequence of a decrease of that part of the Coulomb energy which is associated with long wavelengths and midinfrared frequencies. It remained to be tested experimentally; optical spectroscopy proves to be a suitable technique for probing this part of the Coulomb energy.
The team of Dirk van der Marel, professor at the Department of physics of quantum matter of UNIGE Faculty of Science, has addressed this issue and the many challenges associated to it. ‘We have set up an experimental device and a protocol for measuring the long range Coulomb energy. By varying the temperature and the light frequency applied to several superconducting samples, we observed the subtle influence of superconductivity on the Coulomb energy’, explains Dirk van der Marel.
The importance of chemical doping
Based on cuprate superconductors, UNIGE physicists have observed that the behavior of the Coulomb energy at the superconducting transition depends on the doping -i.e. the lack (or excess) of electrons: for some values of the doping it decreases, but for others it stagnates or even increases. Changes in temperature of the Coulomb energy appear linked to the doping of the sample: ‘there is a critical doping below which the observed behaviour is opposite to Leggett’s scenario’, says the physicist.
These experimental advances still do not explain high Tc superconductivity in the cuprates, however, they permit to make progress in the understanding and to adapt existing theories having foundations in common with Leggett’s scenario. They can be extended to the measurement of the Coulomb energy in other superconducting materials, to other phenomena such as magnetism, to other methods, and provide directions for the development of experiments which will further advance the understanding of superconductivity and other quantum phenomena.
If you want to learn more about superconductivity we have included a university lecture on the subject.