Spin Polarization Curve of Fractional Quantum Hall States with Filling Factor Smaller than 2

Sasaki, Shosuke

doi:10.1155/2013/489519

Cited by 2 publications

(1 citation statement)

References 52 publications

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“…On the other hand the Landau orbitals are partially occupied by up-spins. (Note: In the previous papers [15]- [19] we have already examined the case of a weak magnetic field. In the case both down-and up-spin-electrons partially occupy the lowest Landau orbitals.…”

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confidence: 99%

Fractional Quantum Hall States for Filling Factors 2/3 < <i>ν</i> < 2

Sasaki¹

2015

JMP

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Fractional quantum Hall effect (FQHE) is investigated by employing normal electrons and the fundamental Hamiltonian without any quasi particle. There are various kinds of electron configurations in the Landau orbitals. Therein only one configuration has the minimum energy for the sum of the Landau energy, classical Coulomb energy and Zeeman energy at any fractional filling factor. When the strong magnetic field is applied to be upward, the Zeeman energy of down-spin is lower than that of up-spin for electrons. So, all the Landau orbitals in the lowest level are occupied by the electrons with down-spin in a strong magnetic field at 1 2 < < ν KeywordsFractional Quantum Hall Effect, 2D Electron System, Quantum Theory

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confidence: 99%

Fractional Quantum Hall States for Filling Factors 2/3 < <i>ν</i> < 2

Sasaki¹

2015

JMP

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Relation between FQHE Plateau Width and Valley Energy

Sasaki¹

2015

JMP

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We have investigated the Fractional Quantum Hall Effect (FQHE) on the fundamental Hamiltonian with the Coulomb interactions between normal electrons without any quasi particle. The electron pairs placed in the Landau orbitals can transfer to many empty orbitals. The number of the quantum transitions decreases discontinuously when the filling factor ν deviates from the specific fractional number of ν0. The discontinuous decreasing produces the energy valley at the specific filling factors ν0 = 2/3, 4/5, 3/5, 4/7, 3/7, 2/5, 1/3 and so on. The diagonal elements of the total Hamiltonian and the number of the quantum transitions give the total energy of the FQH states. The energy per electron has the discontinuous spectrum depending on the filling factor ν. We obtain the function form of the energy per electron in the quantum Hall system. Then the theoretical Hall resistance curve is calculated near several filling factors. Therein the quantum Hall plateaus are derived from the energy valleys. The depths of the energy valleys are compared with the widths of the quantum Hall plateaus appearing in the experimental data of the Hall resistance. Our theoretical results are in good agreement with the experimental results.

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Spin Polarization Curve of Fractional Quantum Hall States with Filling Factor Smaller than 2

Cited by 2 publications

References 52 publications

Fractional Quantum Hall States for Filling Factors 2/3 < <i>ν</i> < 2

Fractional Quantum Hall States for Filling Factors 2/3 < <i>ν</i> < 2

Relation between FQHE Plateau Width and Valley Energy

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Spin Polarization Curve of Fractional Quantum Hall States with Filling Factor Smaller than 2

Cited by 2 publications

References 52 publications

Fractional Quantum Hall States for Filling Factors 2/3 &lt; &lt;i&gt;ν&lt;/i&gt; &lt; 2

Fractional Quantum Hall States for Filling Factors 2/3 &lt; &lt;i&gt;ν&lt;/i&gt; &lt; 2

Relation between FQHE Plateau Width and Valley Energy

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Fractional Quantum Hall States for Filling Factors 2/3 < <i>ν</i> < 2

Fractional Quantum Hall States for Filling Factors 2/3 < <i>ν</i> < 2