If we ignore the jellium and mutual Coulomb repulsion between the electrons as a zeroth order approximation, we have an infinitely degenerate lowest Landau level (LLL) and with a filling factor of 1/n, we'd expect that all of the electrons would lie in the LLL. Turning on the interactions, we can make the approximation that all of the electrons lie in the LLL. If is the single particle wavefunction of the LLL state with the lowest orbital angular momenta, then the Laughlin ansatz for the multiparticle wavefunction is
and and are coordinates in the x–y plane. Here is the reduced Planck constant, is the electron charge, is the total number of particles, and is the magnetic field, which is perpendicular to the xy plane. The subscripts on z identify the particle. In order for the wavefunction to describe fermions, n must be an odd integer. This forces the wavefunction to be antisymmetric under particle interchange. The angular momentum for this state is .
Consider above: resultant is a trial wavefunction; it is not exact, but qualitatively, it reproduces many features of the exact solution and quantitatively, it has very high
overlaps with the exact ground state for small systems. Assuming Coulomb repulsion between any two electrons, that
ground state can be determined using exact diagonalisation[3] and the
overlaps have been calculated to be close to one. Moreover, with short-range interaction (Haldane pseudopotentials for set to zero),
Laughlin wavefunction becomes exact,[4]
i.e. .
The Laughlin wavefunction is the multiparticle wavefunction for quasiparticles. The expectation value of the interaction energy for a pair of quasiparticles is
where is a confluent hypergeometric function and is a Bessel function of the first kind. Here, is the distance between the centers of two current loops, is the magnitude of the electron charge, is the quantum version of the Larmor radius, and is the thickness of the electron gas in the direction of the magnetic field. The angular momenta of the two individual current loops are and where . The inverse screening length is given by (Gaussian units)
where is the cyclotron frequency, and is the area of the electron gas in the xy plane.
The interaction energy evaluates to:
To obtain this result we have made the change of integration variables
^Laughlin, R. B. (2 May 1983). "Anomalous Quantum Hall Effect: An Incompressible Quantum Fluid with Fractionally Charged Excitations". Physical Review Letters. 50 (18). American Physical Society (APS): 1395–1398. Bibcode:1983PhRvL..50.1395L. doi:10.1103/physrevlett.50.1395. ISSN0031-9007.
^Z. F. Ezewa (2008). Quantum Hall Effects, Second Edition. World Scientific. ISBN978-981-270-032-2. pp. 210-213
^Yoshioka, D. (2 May 1983). "Ground State of Two-Dimensional Electrons in Strong Magnetic Fields". Physical Review Letters. 50 (18). American Physical Society (APS): 1219. doi:10.1103/physrevlett.50.1219. ISSN0031-9007.
^Haldane, F.D.M.; E.H. Rezayi. "Finite-Size Studies of the Incompressible State of the Fractionally Quantized Hall Effect and its Excitations". Physical Review Letters. 54: 237. doi:10.1103/PhysRevLett.54.237.