Researchers have achieved the creation of a new topological state of matter, known as The fractional quantum state Movement control and interaction of individual atoms in the ensemble of ultra -chief enzymes. An experiment , conducted by Philip Lunt from the University of Heidelberg and his colleagues, imitated the fundamental properties of electrons in such conditions, demonstrating the possibilities of cold atoms for modeling complex quantum effects.
Scientists used optical tweezers to capture a small number of lithium-6 atoms and allocated a couple of enzymes that are in a spin allendary state. Then, to simulate the action of the magnetic field, they used a laser beam with an orbital angular moment (Laigerra-Gauss bundle), which forced the atoms to rotate. The key element of the experiment was not only the rotation of atoms, but also their highly corrected movement around each other, necessary for the implementation of the state of Laflin.
The transition to the fractional quantum state of the Hall was achieved due to the exact settings of the interactions between atoms using the resonances of Feshbach . A state was created in which the movement of atoms is described by the wave function of Laflin for the so-called 1/