Investigation of optical parameters of Ag–In–Se thin films deposited by e-beam technique

“…At higher energies, the increased slope of the Cu(In,Ga)Se2 control is attributed to the non-degenerate valence band splitting of chalcopyrite materials [9]. It is not known at this time whether the differences in curve shape and slope of the two samples can be attributed to changes in band splitting, due to crystal-field and spin-orbit splitting, a reduction in defects, a combination of both, or other effects.…”

“…The optical bandgap was determined from the transmission and reflection data using a standard analytical procedure [9]. The absorption coefficient (α) was determined using Equation (1): [10] …”

“…The bandgap was determined by plotting (αhν) 2 vs. hν and performing a linear fit of the data. This assumes that the fundamental optical transition is due to a direct allowed transition in all cases [9]. Sample curves are shown in Figure 2 for two x = 0.3 samples (w = 0 and 1).…”

Optical and quantum efficiency analysis of (Ag,Cu)(In,Ga)Se<inf>2</inf> absorber layers

“…At higher energies, the increased slope of the Cu(In,Ga)Se2 control is attributed to the non-degenerate valence band splitting of chalcopyrite materials [9]. It is not known at this time whether the differences in curve shape and slope of the two samples can be attributed to changes in band splitting, due to crystal-field and spin-orbit splitting, a reduction in defects, a combination of both, or other effects.…”

“…The optical bandgap was determined from the transmission and reflection data using a standard analytical procedure [9]. The absorption coefficient (α) was determined using Equation (1): [10] …”

“…The bandgap was determined by plotting (αhν) 2 vs. hν and performing a linear fit of the data. This assumes that the fundamental optical transition is due to a direct allowed transition in all cases [9]. Sample curves are shown in Figure 2 for two x = 0.3 samples (w = 0 and 1).…”

Optical and quantum efficiency analysis of (Ag,Cu)(In,Ga)Se<inf>2</inf> absorber layers

“…The absence of diffraction peak in the X-ray patterns (within the investigated 2θ range and in the limit of XRD device detection) confirms the expected amorphous nature. above the weak and free absorption regions (i.e., strong absorption region 500-750 nm) the maxima (respectively minima) of the interference fringes of the reflectance spectrum, occurs at the same wavelength positions of the corresponding one of the transmittance spectrum, that gives some sound indication about the optical homogeneity of the deposited thin films [19,20]. The optical properties of the deposited films may be represented by the refractive index, n, and extinction coefficient, k, which are the real and imaginary parts of the complex refractive index, N ¼ n À ik.…”

Structural characterization and optical properties of pulsed laser deposition of Se75Te25 and Se75Te17Ge8 amorphous thin films

“…A decrease in E g with increasing annealing temperature for SrTiO 3 thin films and AgInSe thin films were reported in Refs. [43,44], due to the increase in the energy widths of the band tail states, quantum-size effects and the existence of an amorphous phase. Therefore, it is believed that both the increase in crystallite size and the reduction in amorphous phase amount are responsible for the bandgap decreasing in the annealed CuIn 0 7 Ga 0 3 (Se 1−x Te x 2 films.…”

Optical and Structural Properties of Nanostructured CuIn<SUB>0.7</SUB>Ga<SUB>0.3</SUB>(Se<SUB>(1−<I>x</I>)</SUB>Te<SUB><I>x</I></SUB>)<SUB>2</SUB> Chalcopyrite Thin Films—Effect of Stoichiometry and Annealing