Quantized conductance in a CVD-grown nanoribbon with hidden Rashba effect

Abstract

Quantized conductance in quasi-one-dimensional systems not only provides a hallmark of ballistic transport, but also serves as a gateway for exploring quantum phenomena. Recently, a unique hidden Rashba effect attracts tremendous attention, which arises from the compensation of opposite spin polarizations of a Rashba bilayer in inversion symmetric crystals with dipole fields, such as bismuth oxyselenide (Bi2O2Se). However, investigating this effect utilizing conductance quantization is still challenging. Here we report the conductance quantization observed in a chemical vapor deposition (CVD)-grown high-mobility Bi2O2Se nanoribbon, where quantized conductance plateaus up to 44· 2e2/h (e is the elementary charge, h is the Planck constant, and the factor 2 results from spin degeneracy) are achieved at zero magnetic field. Due to the hidden Rashba effect, the quantized conductance remains in multiples of 2e2/h without Zeeman splitting even under magnetic field up to 12 T. Moreover, within a specific range of magnetic field, the plateau sequence exhibits the Pascal triangle series, namely (1,3,6,10,15… )· 2e2/h, reflecting the interplay of size quantization in two transverse directions. These observations are well captured by an effective hidden Rashba bilayer model. Our results demonstrate Bi2O2Se as a compelling platform for spintronics and the investigation of emergent phenomena.