Ion Beam Induced Nanocrystallization

Introduction

  • It is well established that ion beam irradiation can stimulate the nucleation and grain growth in amorphous (a) silicon at relatively low temperatures . The silicon grain size distribution depends on the irradiation conditions such as ion dose and irradiation temperature.
  • In the case of silicon carbide (SiC), with its low atomic mobilities and high thermal crystallization temperature of 800°C, it has been shown that ion implantation can stimulate the recrystallization process as well.
  • Due to the lack of systematic investigations on the kinetics of ion-beam-induced- crystallization (IBIC) in a-SiC, in the present work, the dependence of the recrystallization process on the implantation parameters was studied .
In particular, the critical parameter range for the beginning of crystallization, and the kinetics of the process has to be clarified.
 

Experimental

  • Substrate (bulk)material :
    6H-SiC wafers (n type, (0001) orientation, Si surface )
  • Amorphization :
    by 2 MeV, 5x1016 Si+/cm-2 implantation at room temperature 1.8 µm thick amorphous surface layer
  • IBIC-implantation :
    300 keV (Al+,Si+) RP = (330,380) nm
    dose rate : 1.0x1013. . . 3.3x1013Al+/cm2/s
    dose range (3x1015 . . . 3x1017) Al+/cm2
    temperature range (300 . . . 700 ) °C

Morphology

 


 
 

  • Recrystallization takes place in the irradiated regions at 300?C, well below the SiC thermal recrystallization temperature of about 800?C.
  • No sign of crystallization appears in unimplanted amorphous regions up to implantation temperatures of 700?C.
 Ion irradiation strongly enhances the recrystallization process in SiC.
  • The morphology of the recrystallized material completely differs from that after thermal crystallization.
  • Randomly oriented grains of 3C-SiC with almost spherical shape and a narrow size distribution around mean diameters ranging from 5 to 20 nm have been formed, as proved by X-ray diffraction.
 
 

Kinetics

 
 
 
  • The recrystallization is completed within a very narrow time window. Either almost completely recrystallized or still amorphous layers were found. Therefore, the nucleation and growth process could not be observed directly.
  • From the extrapolation of the kinetics of the secondary grain growth to zero time the window of suitable parameters for the observation of nucleation and primary grain growth was esti- mated.
 
 A critical temperature (TC 300°C) and an incubation time (tI300s below 500°C) for the beginning of the recrystallization were found.
 
 
 
  • The shift of the boundary of the recrystallized layer indicates the existence of a threshold energy for the onset of the crystallization at about 5x1022 keV/cm3.
  • No correlation between the individual grain size and the damage energy profile was found in the investigated parameter range.
 

Conclusions

  • The recrystallization behavior of amorphous SiC layers under high dose implantation with Al and Si was investigated by XTEM and XRD measurements.
  • The results show that ion irradiation strongly enhances the recrystallization process in a-SiC already at 300 °C, well below the thermal recrystallization temperature of about 800 °C. Randomly oriented grains of 3C-SiC, with almost spherical shape and mean diameters ranging from 4 to 25 nm, were formed during implantation.
  • It was found that there is only a narrow time window for the observation of nucleation and primary growth. From the extrapolation of the kinetics of the secondary grain growth this time window was estimated.