The photoluminescence (PL) properties of silicon-on-insulator (SOI) samples, modified by the Si+ self-ion-implantation (SII) into Si thin film followed by annealing, have been well investigated. The well-known W-line can also… Click to show full abstract
The photoluminescence (PL) properties of silicon-on-insulator (SOI) samples, modified by the Si+ self-ion-implantation (SII) into Si thin film followed by annealing, have been well investigated. The well-known W-line can also be observed in SII SOI samples, its emitting behavior and structural evolution have been discussed in this article. The parallel PL pattern trend and the similar changes of temperature-dependent intensity suggest that luminescence center of I1 and I2 peaks located in the near-infrared band originates from the same interstitial-clusters (InCs). The PL peak at 1.762 eV can be ascribed to the quantum confinement (QC) from small-sized Si nanocrystals. Based on the electron spin resonance (ESR) experiments and the variation of normalized PL intensities at different annealing temperature (TA), the neutral oxygen vacancy (NOV) [O3≡Si-Si≡O3] is proposed to be responsible for the blue emission of P2 and P3 peaks, whose intensity can be restrained by the existence of the paramagnetic E1' defects [O3≡Si+]. The density of E1' defect is found to reduce with the increase of annealing temperature (TA). Our results provide a useful method to identify the origin of luminescence centers and pave a way for the application of new type optical defects on silicon based light emitting devices (LEDs).
               
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