We attempt to realize single-phase crystalline BaSi₂ thin films on glass substrate by utilizing poly-Si layers fabricated by Aluminum Induced Crystallization (AIC) for solar cell applications. Vacuum evaporation method was chosen to deposit BaSi₂ due to its simplicity and large deposition area. Since lumps of BaSi₂ with 99% purity were used as source material, the content of the vapor during evaporation process is time-dependent: initial vapor is Ba rich, while the latter is Si rich. In spite of this fact, our previous studies revealed that single phase BaSi₂ can be achieved on Si (111) substrates by solid-state reaction of Ba-rich layer with the Si substrate. In this study, poly-Si fabricated by AIC on glass substrate is employed as Si supply layers to form single-phase BaSi₂. Since AIC proceeds under nearly equilibrium conditions, p-type Al doping of Si can be expected. Thus upon deposition of BaSi₂, p-type BaSi₂ is also conceivable.
During AIC process, large grained Si layer with preferred orientation of (111) is achieved at annealing temperature of 475 ^oC. However, the grain size becomes smaller and (001)-oriented regions grow at higher temperatures. Upon BaSi₂ deposition, Raman spectra of the samples grown at substrate temperature of 400 ^oC and above show 5 characteristic peaks of BaSi₂ which represent [Si₄]⁴⁻ anions vibration modes in BaSi₂ phase. No other peaks were observed, which might indicates that the grown BaSi₂ is single phase. Moreover, the electrical properties of the grown BaSi₂ will be further investigated.
According to our results, BaSi₂ was successfully grown on poly-Si layer fabricated by AIC method. The absence of peaks other than BaSi₂ peaks on Raman spectra might indicates that the grown BaSi₂ is single phase.