Optical and Structural Characterization of GaN Based Hybrid Structures and Nanorods

Abstract: GaN belongs to the group III nitrides and is today the material of choice for efficient blue light emission, enabling solid state white lighting by combining red, blue and green light emitting diodes (LED) or by having a blue LED illuminating a phosphor. By combining GaN quantum well (QW) structures with colloids, nanoparticles or polyfluorene films, LEDs may be fabricate at lower cost. Such hybrid structures are promising for future micro-light sources in full-color displays, sensors and imaging systems. In t… Show more

“…Similarly, GaN, a III–V compound semiconductor, is today the material of choice for high-efficiency blue light emission. By the combination of appropriate amounts of red, green, and blue lights, solid-state white lighting has been realized, and it is becoming one of the most promising next-generation lighting sources . After decades-long research and development, these traditional semiconductor materials have excellent performance, but it is undeniable that the optoelectronic conversion efficiency and material cost are also close to the limit under current material science and synthesis technology.…”

Metal Halide Semiconductors beyond Lead-Based Perovskites for Promising Optoelectronic Applications

“…Similarly, GaN, a III–V compound semiconductor, is today the material of choice for high-efficiency blue light emission. By the combination of appropriate amounts of red, green, and blue lights, solid-state white lighting has been realized, and it is becoming one of the most promising next-generation lighting sources . After decades-long research and development, these traditional semiconductor materials have excellent performance, but it is undeniable that the optoelectronic conversion efficiency and material cost are also close to the limit under current material science and synthesis technology.…”

Metal Halide Semiconductors beyond Lead-Based Perovskites for Promising Optoelectronic Applications

Surface functionalization of gallium nitride for biomedical implant applications