Differential nonlinear photocarrier radiometry for characterizing ultra-low energy boron implantation in silicon

Understanding the surface recombination property of semiconductor materials is beneficial for improving the performance of optoelectronic devices. In this paper, differential photocarrier radiometry (PCR) is carried out to investigate the evolution of the surface recombination velocities of silicon wafers induced by laser irradiation. The PCR signal and the surface recombination velocities were found to be strongly dependent on the quality of the wafer surface and the duration of laser irradiation. The native oxide surface was more susceptible to laser irradiation than the Al2O3 passivated surface due to more surface defects being annealed. A surface-defect annealing model was used to explain the transient behavior of the PCR signal and the surface recombination velocity.

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Measuring the properties of colloidal PbS quantum dot thin films using differential photocarrier radiometry technology

Zhao,

Wang,

Gao

et al. 2024

AIP Advances

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Colloidal quantum dots have been widely applied in various optoelectronic devices such as solar cells, photodetectors, and light emitting diodes. The measurement of carrier dynamics not only allows the study of the passivation quality of quantum dot surfaces but also contributes to analyze the performance of related devices. In this study, by measuring and comparing the photocarrier radiometry signals of PbS quantum dot films on different substrates from the same batch, we investigated the carrier transport and trap properties in the material. First, based on the differences in surface recombination velocities of colloidal quantum dot films on different substrates, we established a theoretical model of differential photocarrier radiometry technique applicable to colloidal quantum dot films. We simulated and analyzed the effects of the carrier transport parameters, such as carrier lifetime, carrier hopping diffusivity, and surface recombination velocities, on the differential photocarrier radiometry signals. Finally, the photocarrier radiometry signals of PbS quantum dot films on K9 glass substrate and transparent indium tin oxide film coated glass substrate were experimentally measured, and the carrier transport parameters of the quantum dot films were also obtained through multiparameter fitting. The simulation and experimental results demonstrate that the differential photocarrier radiometry technique can be used for non-destructive measurement of the carrier transport and trap properties of colloidal quantum dot films without the adverse effects of instrument frequency response.

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Differential nonlinear photocarrier radiometry for characterizing ultra-low energy boron implantation in silicon

Cited by 3 publications

References 38 publications

Surface recombination property of silicon wafers determined accurately by self-normalized photocarrier radiometry

Surface recombination property of silicon wafers determined accurately by self-normalized photocarrier radiometry

Evolution of surface recombination property of silicon wafers during laser irradiation by differential photocarrier radiometry

Measuring the properties of colloidal PbS quantum dot thin films using differential photocarrier radiometry technology

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