Tunable spin-orbit splitting in bilayer graphene/WSe$_2$ quantum devices

Abstract: Bilayer graphene (BLG)-based quantum devices represent a promising platform for emerging technologies such as quantum computing and spintronics. However, their intrinsically weak spin-orbit coupling (SOC) presents a challenge for spin and valley manipulation, as these applications operate more efficiently in the presence of strong SOC. Integrating BLG with transition metal dichalcogenides (TMDs) significantly enhances SOC via proximity effects. While this enhancement has been experimentally demonstrated in 2D-layered structures, 1D and 0D-nanostructures in BLG/TMD remain unrealized, with open questions regarding device quality, SOC strength, and tunability. In this work, we investigate quantum point contacts and quantum dots in two BLG/WSe$2$ heterostructures with different stacking orders. Across multiple devices, we demonstrate a reproducible enhancement of spin-orbit splitting ($\Delta\mathrm{SO}$) reaching values of up to $1.5\mathrm{meV}$ - more than one order of magnitude higher than in pristine bilayer graphene ($\Delta_\mathrm{SO}=40-80\mu\mathrm{eV}$). Furthermore, we show that the induced SOC can be tuned in situ from its maximum value to near-complete suppression by varying the perpendicular electric field, thereby controlling layer polarization. This enhancement and in situ tunability establish SOC as an efficient control mechanism for dynamic spin and valley manipulation.