Photoconductivity in AlxGa1—xN with Different Al Contents

“…Hence, the data strongly suggest that various N-related defects present in GaAsN are responsible for reducing the mobility. However, the relative magnitude of mobility reduction in our material is much less compared to those reported by other authors [15][16][17][18][19][20][21] on molecular beam epitaxy (MBE) grown GaAsN layers. This may be due to the fact that materials grown LPE are usually more homogeneous in nature as compared to those grown by other techniques.…”

“…Many interesting properties of the materials and their nanostructures have been studied and attempts have been made to understand them using theoretical models. The study of the electrical transport properties of the materials forms an integral part of the work, in view of the observed fact that nitrogen plays an important role in significantly restricting the electron mobility in single layers [15][16][17] and in modulation-doped heterostructures [18,19]. The observed mobility drop has been suggested to be due to materials inhomogeneity [15,16] or N-related scattering centers [17][18][19].…”

“…The study of the electrical transport properties of the materials forms an integral part of the work, in view of the observed fact that nitrogen plays an important role in significantly restricting the electron mobility in single layers [15][16][17] and in modulation-doped heterostructures [18,19]. The observed mobility drop has been suggested to be due to materials inhomogeneity [15,16] or N-related scattering centers [17][18][19]. Fay and O'Reilly presented a theoretical model to explain the mobility limited by nitrogen-related defects [20,21].…”

Hall mobility and electron trap density in GaAsN grown by liquid phase epitaxy

“…Hence, the data strongly suggest that various N-related defects present in GaAsN are responsible for reducing the mobility. However, the relative magnitude of mobility reduction in our material is much less compared to those reported by other authors [15][16][17][18][19][20][21] on molecular beam epitaxy (MBE) grown GaAsN layers. This may be due to the fact that materials grown LPE are usually more homogeneous in nature as compared to those grown by other techniques.…”

“…Many interesting properties of the materials and their nanostructures have been studied and attempts have been made to understand them using theoretical models. The study of the electrical transport properties of the materials forms an integral part of the work, in view of the observed fact that nitrogen plays an important role in significantly restricting the electron mobility in single layers [15][16][17] and in modulation-doped heterostructures [18,19]. The observed mobility drop has been suggested to be due to materials inhomogeneity [15,16] or N-related scattering centers [17][18][19].…”

“…The study of the electrical transport properties of the materials forms an integral part of the work, in view of the observed fact that nitrogen plays an important role in significantly restricting the electron mobility in single layers [15][16][17] and in modulation-doped heterostructures [18,19]. The observed mobility drop has been suggested to be due to materials inhomogeneity [15,16] or N-related scattering centers [17][18][19]. Fay and O'Reilly presented a theoretical model to explain the mobility limited by nitrogen-related defects [20,21].…”

Hall mobility and electron trap density in GaAsN grown by liquid phase epitaxy

“…The top Al 0.18 Ga 0.82 N (AlGaN) layer was 0.2 mm thick. Lateral Ohmic contacts, about 10 mm apart, were formed on the top of the AlGaN layer, with indium annealed at 380 C. The film was characterized by photoluminescence spectroscopy and Hall measurements as described earlier [3].…”

Photoconductivity Studies of Al0.18Ga0.82N/GaN Single Heterostructure

Density-of-states distribution in AlGaN obtained from transient photocurrent analysis