A simple sheet of graphene has noteworthy properties due to a quantum phenomenon in its electron structure called Dirac cones. The system becomes even more interesting if it comprises two superimposed graphene sheets, and one is very slightly turned in its own plane so that the holes in the two carbon lattices no longer completely coincide. For specific angles of twist, the bilayer graphene system displays exotic properties such as superconductivity.

A new study conducted by Brazilian physicist Aline Ramires with Jose Lado, a Spanish-born researcher at the Swiss Federal Institute of Technology (ETH Zurich), shows that the application of an electrical field to such a system produces an effect identical to that of an extremely intense magnetic field applied to two aligned graphene sheets.

An article on the study has recently been published in Physical Review Letters. It is also available on the arXiv pre-publishing platform.

“I performed the analysis, and it was computationally verified by Lado,” Ramires said. “It enables graphene’s electronic properties to be controlled by means of electrical fields, generating artificial but effective magnetic fields with far greater magnitudes than those of the real magnetic fields that can be applied.”

The two graphene sheets must be close enough together for the electronic orbitals of one to interact with the electronic orbitals of the other, she explained. This means a separation as close as approximately one angstrom (10-10 meter or 0.1 nanometer), which is the distance between two carbon atoms in graphene.

Another requirement is a small angle of twist for each sheet compared to the other—less than one degree. Although entirely theoretical, the study has clear technological potential, as it shows that a versatile material such as graphene can be manipulated in hitherto unexplored regimes.

“The artificial magnetic fields proposed previously were based on the application of forces to deform the material. Our proposal enables the generation of these fields to be controlled with much greater precision. This could have practical applications,” Ramires said.

The exotic states of matter induced by artificial magnetic fields are associated with the appearance of “pseudo-Landau levels” in graphene sheets. Landau levels—named after the Soviet physicist and mathematician Lev Landau (1908-1968), Nobel Laureate in Physics in 1962—are a quantum phenomenon whereby in the presence of a magnetic field, electrically charged particles can only occupy orbits with discrete energy values. The number of electrons in each Landau level is directly proportional to the magnitude of the applied magnetic field.

“These states are well-located in space; when particles interact at these levels, the interactions are much more intense than usual. The formation of pseudo-Landau levels explains why artificial magnetic fields make exotic properties such as superconductivity or spin liquids appear in the material,” Ramires said.

More information:
Aline Ramires et al, Electrically Tunable Gauge Fields in Tiny-Angle Twisted Bilayer Graphene, Physical Review Letters (2018). DOI: 10.1103/PhysRevLett.121.146801

A simple sheet of graphene has noteworthy properties due to a quantum phenomenon in its electron structure called Dirac cones. The system becomes even more interesting if it comprises two superimposed graphene sheets, and one is very slightly turned in its own plane so that the holes in the two carbon lattices no longer completely coincide. For specific angles of twist, the bilayer graphene system displays exotic properties such as superconductivity.

A new study conducted by Brazilian physicist Aline Ramires with Jose Lado, a Spanish-born researcher at the Swiss Federal Institute of Technology (ETH Zurich), shows that the application of an electrical field to such a system produces an effect identical to that of an extremely intense magnetic field applied to two aligned graphene sheets.

An article on the study has recently been published in Physical Review Letters. It is also available on the arXiv pre-publishing platform.

“I performed the analysis, and it was computationally verified by Lado,” Ramires said. “It enables graphene’s electronic properties to be controlled by means of electrical fields, generating artificial but effective magnetic fields with far greater magnitudes than those of the real magnetic fields that can be applied.”

The two graphene sheets must be close enough together for the electronic orbitals of one to interact with the electronic orbitals of the other, she explained. This means a separation as close as approximately one angstrom (10-10 meter or 0.1 nanometer), which is the distance between two carbon atoms in graphene.

Another requirement is a small angle of twist for each sheet compared to the other—less than one degree. Although entirely theoretical, the study has clear technological potential, as it shows that a versatile material such as graphene can be manipulated in hitherto unexplored regimes.

“The artificial magnetic fields proposed previously were based on the application of forces to deform the material. Our proposal enables the generation of these fields to be controlled with much greater precision. This could have practical applications,” Ramires said.

The exotic states of matter induced by artificial magnetic fields are associated with the appearance of “pseudo-Landau levels” in graphene sheets. Landau levels—named after the Soviet physicist and mathematician Lev Landau (1908-1968), Nobel Laureate in Physics in 1962—are a quantum phenomenon whereby in the presence of a magnetic field, electrically charged particles can only occupy orbits with discrete energy values. The number of electrons in each Landau level is directly proportional to the magnitude of the applied magnetic field.

“These states are well-located in space; when particles interact at these levels, the interactions are much more intense than usual. The formation of pseudo-Landau levels explains why artificial magnetic fields make exotic properties such as superconductivity or spin liquids appear in the material,” Ramires said.

More information:
Aline Ramires et al, Electrically Tunable Gauge Fields in Tiny-Angle Twisted Bilayer Graphene, Physical Review Letters (2018). DOI: 10.1103/PhysRevLett.121.146801