What question did this study set out to answer?

The research aims to explore the quantum Hall effect in strained germanium quantum wells during one-dimensional hole transport.

February 6, 2026Open Access

Conductance plateaus at quantum Hall integer filling factors in germanium quantum point contacts

Key Points

The research aims to explore the quantum Hall effect in strained germanium quantum wells during one-dimensional hole transport.
Fabricated quantum point contacts on low disorder strained germanium quantum wells
Conducted experiments under varying magnetic fields to observe transport characteristics
Analyzed conductance quantization at integer filling factors
Observed quantized conductance increasing in multiples of e2/h
Established a transition to integer quantum Hall states down to filling factor ν=1
Demonstrated the capability for exploring many-body states and quantum phase transitions

Abstract

Constricting transport through a one-dimensional quantum point contact in the quantum Hall regime enables gate-tunable selection of the edge modes propagating between voltage probe electrodes. Here, we investigate the quantum Hall effect in a quantum point contact fabricated on low disorder strained germanium quantum wells. For increasing magnetic field, we observe Zeeman spin-split 1D ballistic hole transport evolving to integer quantum Hall states, with well-defined quantized conductance increasing in multiples of e2/h down to the first integer filling factor ν=1. These results establish strained germanium as a viable platform for complex experiments probing many-body states and quantum phase transitions.

Conductance plateaus at quantum Hall integer filling factors in germanium quantum point contacts

Key Points

Abstract

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