The 0.8 Me V copper ( Cu) ion beam irradiation-induced effects on structural, morphological and optical properties of tin dioxide nanowires (SnO_(2)NWs) are investigated. The samples are irradiated at three different ...The 0.8 Me V copper ( Cu) ion beam irradiation-induced effects on structural, morphological and optical properties of tin dioxide nanowires (SnO_(2)NWs) are investigated. The samples are irradiated at three different doses 5 × 10^12 ions/cm^(2), 1 ×10^(13) ions/cm^(2) and 5 × 10^(13) ions/em^(2) at room temperature. The XRD analysis shows that the tetragonal phase of SnO_(2)NWs remains stable after Cu ion irradiation, but with increasing irradiation dose level the crystal size increases due to ion beam induced coalescence of NWs. The FTIR spectra of pristine SnO_(2)NWs exhibit the chemical composition of SnO_(2)while the Cn-O bond is also observed in the FTIR spectra after Cu ion beam irradiation. The presence of Cu impurity in SnO_(2)is further confirmed by calculating the stopping range of Cu ions by using TRM/SRIM code. Optical properties of SnO_(2)NWs are studied before and after Cu ion irradiation. Band gap analysis reveMs that the band gap of irradiated samples is found to decrease compared with the pristine sample. Therefore, ion beam irradiation is a promising technology for nanoengineering and band gap tailoring.展开更多
基金Supported by the Department of Physics,the University of AJKHigh Tech.Centralized Instrumentation Lab,the University of AJK,Pakistanthe Experimental Physics Division,and the National Center for Physics,Islamabad Pakistan
文摘The 0.8 Me V copper ( Cu) ion beam irradiation-induced effects on structural, morphological and optical properties of tin dioxide nanowires (SnO_(2)NWs) are investigated. The samples are irradiated at three different doses 5 × 10^12 ions/cm^(2), 1 ×10^(13) ions/cm^(2) and 5 × 10^(13) ions/em^(2) at room temperature. The XRD analysis shows that the tetragonal phase of SnO_(2)NWs remains stable after Cu ion irradiation, but with increasing irradiation dose level the crystal size increases due to ion beam induced coalescence of NWs. The FTIR spectra of pristine SnO_(2)NWs exhibit the chemical composition of SnO_(2)while the Cn-O bond is also observed in the FTIR spectra after Cu ion beam irradiation. The presence of Cu impurity in SnO_(2)is further confirmed by calculating the stopping range of Cu ions by using TRM/SRIM code. Optical properties of SnO_(2)NWs are studied before and after Cu ion irradiation. Band gap analysis reveMs that the band gap of irradiated samples is found to decrease compared with the pristine sample. Therefore, ion beam irradiation is a promising technology for nanoengineering and band gap tailoring.
