Comparative investigation into key optoelectronic characteristics of semipolar InGaN blue laser diodes: A strategy to mitigate quantum-confine stark effect

“…In the recent years, InGaN has become probably the most intensively studied among all the material systems used for QW lasers. Although InGaN can emit effectively light in red, green, blue and ultraviolet, recently most InGaN applications focused on the blue [1][2][3][4][5][6] and green [5][6][7][8] spectral ranges (some of them [5][6] can operate, with composition and structure variations, both in blue and green spectra) and also some in the deep violet [9]. In this paper we present simulations of the main characteristics of an InGaN QW laser that operates in the blue spectrum, at the wavelength of 462 nm.…”

Characteristics of an In0.02Ga0.98N QW laser at a 462 nm wavelength

“…In the recent years, InGaN has become probably the most intensively studied among all the material systems used for QW lasers. Although InGaN can emit effectively light in red, green, blue and ultraviolet, recently most InGaN applications focused on the blue [1][2][3][4][5][6] and green [5][6][7][8] spectral ranges (some of them [5][6] can operate, with composition and structure variations, both in blue and green spectra) and also some in the deep violet [9]. In this paper we present simulations of the main characteristics of an InGaN QW laser that operates in the blue spectrum, at the wavelength of 462 nm.…”

Characteristics of an In0.02Ga0.98N QW laser at a 462 nm wavelength

Recent progress of indium-bearing group-III nitrides and devices: a review

Comparative investigation into polarization field-dependent internal quantum efficiency of semipolar InGaN green light-emitting diodes: A strategy to mitigate green gap phenomenon