Publication | Open Access
Improving mobility of silicon metal-oxide–semiconductor devices for quantum dots by high vacuum activation annealing
11
Citations
45
References
2020
Year
EngineeringSilicon On InsulatorSingle Quantum DotSemiconductor DeviceSemiconductor NanostructuresSemiconductorsElectronic DevicesNanoelectronicsQuantum DotsCompound SemiconductorHigh Vacuum ActivationGas AnnealingSemiconductor TechnologyElectrical EngineeringPhysicsNanotechnologySemiconductor Device FabricationMicroelectronicsApplied PhysicsActivation AnnealingQuantum DevicesSilicon Metal-oxide–semiconductor Devices
To improve mobility of fabricated silicon metal-oxide-semiconductor (MOS) quantum devices, forming gas annealing is a common method used to mitigate the effects of disorder at the Si/SiO2 interface. However, the importance of activation annealing is usually ignored. Here, we show that a high vacuum environment for implantation activation is beneficial for improving mobility compared to nitrogen atmosphere. Low-temperature transport measurements of Hall bars show that peak mobility can be improved by a factor of two, reaching 1.5 m^2/(Vs) using high vacuum annealing during implantation activation. Moreover, the charge stability diagram of a single quantum dot is mapped, with no visible disturbance caused by disorder, suggesting possibility of fabricating high-quality quantum dots on commercial wafers. Our results may provide valuable insights into device optimization in silicon-based quantum computing.
| Year | Citations | |
|---|---|---|
Page 1
Page 1