Abstract
Electron and hole Bloch states in bilayer graphene exhibit topological orbital magnetic moments with opposite signs, which allows for tunable valley-polarization in an out-of-plane magnetic field. This property makes electron and hole quantum dots (QDs) in bilayer graphene interesting for valley and spin-valley qubits. Here, we show measurements of the electron–hole crossover in a bilayer graphene QD, demonstrating opposite signs of the magnetic moments associated with the Berry curvature. Using three layers of top gates, we independently control the tunneling barriers while tuning the occupation from the few-hole regime to the few-electron regime, crossing the displacement-field-controlled band gap. The band gap is around 25 meV, while the charging energies of the electron and hole dots are between 3 and 5 meV. The extracted valley g-factor is around 17 and leads to opposite valley polarization for electrons and holes at moderate B-fields. Our measurements agree well with tight-binding calculations for our device.
Highlights
Electron and hole Bloch states in bilayer graphene exhibit topological orbital magnetic moments with opposite signs, which allows for tunable valley-polarization in an out-of-plane magnetic field
In contrast to silicon, where the lifting of the valley degeneracy is set by the confining potential, the large valley g-factor in Bilayer graphene (BLG) offers control of the valley splitting and allows us to achieve full valley polarization as a function of magnetic field and quasiparticle index
This, together with the tunable band gap, makes BLG interesting for the implementation of spin-valley qubits based on electron and hole quantum dots (QDs)
Summary
Electron and hole Bloch states in bilayer graphene exhibit topological orbital magnetic moments with opposite signs, which allows for tunable valley-polarization in an out-of-plane magnetic field. This, together with the tunable band gap, makes BLG interesting for the implementation of spin-valley qubits based on electron and hole QDs. Quantum dots in single-layer and bilayer graphene have been investigated intensively in the past decade.
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