Tracking the energies of one-dimensional subband edges in quantum point contacts using dc conductance measurements

TL;DR

This paper presents a comprehensive framework for using dc conductance measurements in quantum point contacts to directly map 1D subband energies, revealing new insights into spin-split subband behavior and population dynamics.

Contribution

It introduces a general method for analyzing dc conductance data to accurately track subband edge energies, enhancing understanding of spin-split subband physics in quantum point contacts.

Findings

The 2-down subband edge closely follows the source chemical potential during initial population.

The 2-up subband populates rapidly as it approaches the drain potential.

The spin-gap may stop opening or close as the 2-up subband continues to populate.

Abstract

The semiconductor quantum point contact has long been a focal point for studies of one-dimensional electron transport. Their electrical properties are typically studied using ac conductance methods, but recent work has shown that the dc conductance can be used to obtain additional information, with a density-dependent Land\'{e} effective g-factor recently reported [T.-M. Chen et al, Phys. Rev. B 79, 081301 (2009)]. We discuss previous dc conductance measurements of quantum point contacts, demonstrating how valuable additional information can be extracted from the data. We provide a comprehensive and general framework for dc conductance measurements that provides a path to improving the accuracy of existing data and obtaining useful additional data. A key aspect is that dc conductance measurements can be used to map the energy of the 1D subband edges directly, giving new insight into the physics that takes place as the spin-split 1D subbands populate. Through a re-analysis of the data obtained by Chen et al, we obtain two findings. The first is that the 2-down subband edge closely tracks the source chemical potential when it first begins populating before dropping more rapidly in energy. The second is that the 2-up subband populates more rapidly as the subband edge approaches the drain potential. This second finding suggests that the spin-gap may stop opening, or even begin to close again, as the 2-up subband continues populating, consistent with recent theoretical calculations and experimental studies.