Experimental and theoretical study of polarization-dependent optical transitions in InAs quantum dots at telecommunication-wavelengths (1300-1500 nm)

Abstract: The design of some optical devices such as semiconductor optical amplifiers for telecommunication applications requires polarization-insensitive optical emission at the long wavelengths (1300-1550 nm). Self-assembled InAs/GaAs quantum dots (QDs) typically exhibit ground state optical emission at wavelengths shorter than 1300 nm with highly polarization-sensitive characteristics, although this can be modified by using low growth rates, the incorporation of strainreducing capping layers or growth of closely-stac… Show more

“…5,23 Among these techniques, the exploitation of strain interactions between the quantum dot layers in multi-layer QD stacks have shown great potential to generate polarization-insensitive optical transitions at telecommunication wavelengths. 2,4,22,24,53 B. Aspect ratio of QDs increases above 0.3…”

“…Thus, a directional degree of polarization (DOP) should be measured (or calculated) to fully characterize the polarization response of quantum dot stacks. Previous theoretical and experimental studies have considered only a single value of DOP: either [110] The electronic structure of single and stacked InAs quantum dots (QDs) has been extensively studied in the last couple of decades for the design of optical devices [1][2][3][4][5][6][7][8] and devices suited to quantum information processing. [9][10][11][12] Recent efforts are focused to achieve isotropic polarization response of ground state optical intensity (GSOI) at telecommunication wavelengths (1300-1500 nm).…”

“…Several methods have been explored to reduce the value of DOP. These methods include (1) strain engineering by over-growing the InAs QDs with InGaAs quantum wells, also known as the strain reducing capping layers, 3 (2) inclusion of dilute impurities such as nitrogen "N," 19 antimony "Sb," 20 and phosphorous "P," 21 etc., (3) exploiting the strain interaction between the QDs in multi-layer QD stacks, 2,4,22 and (4) growing large stacks of QDs in the form of columnar QDs. 5,23 Among these techniques, the exploitation of strain interactions between the quantum dot layers in multi-layer QD stacks have shown great potential to generate polarization-insensitive optical transitions at telecommunication wavelengths.…”

“…[9][10][11][12] Recent efforts are focused to achieve isotropic polarization response of ground state optical intensity (GSOI) at telecommunication wavelengths (1300-1500 nm). 2,[4][5][6][7] The polarization response of QD samples is characterized in terms of degree of polarization:…”

In-plane polarization anisotropy of ground state optical intensity in InAs/GaAs quantum dots

“…5,23 Among these techniques, the exploitation of strain interactions between the quantum dot layers in multi-layer QD stacks have shown great potential to generate polarization-insensitive optical transitions at telecommunication wavelengths. 2,4,22,24,53 B. Aspect ratio of QDs increases above 0.3…”

“…Thus, a directional degree of polarization (DOP) should be measured (or calculated) to fully characterize the polarization response of quantum dot stacks. Previous theoretical and experimental studies have considered only a single value of DOP: either [110] The electronic structure of single and stacked InAs quantum dots (QDs) has been extensively studied in the last couple of decades for the design of optical devices [1][2][3][4][5][6][7][8] and devices suited to quantum information processing. [9][10][11][12] Recent efforts are focused to achieve isotropic polarization response of ground state optical intensity (GSOI) at telecommunication wavelengths (1300-1500 nm).…”

“…Several methods have been explored to reduce the value of DOP. These methods include (1) strain engineering by over-growing the InAs QDs with InGaAs quantum wells, also known as the strain reducing capping layers, 3 (2) inclusion of dilute impurities such as nitrogen "N," 19 antimony "Sb," 20 and phosphorous "P," 21 etc., (3) exploiting the strain interaction between the QDs in multi-layer QD stacks, 2,4,22 and (4) growing large stacks of QDs in the form of columnar QDs. 5,23 Among these techniques, the exploitation of strain interactions between the quantum dot layers in multi-layer QD stacks have shown great potential to generate polarization-insensitive optical transitions at telecommunication wavelengths.…”

“…[9][10][11][12] Recent efforts are focused to achieve isotropic polarization response of ground state optical intensity (GSOI) at telecommunication wavelengths (1300-1500 nm). 2,[4][5][6][7] The polarization response of QD samples is characterized in terms of degree of polarization:…”

In-plane polarization anisotropy of ground state optical intensity in InAs/GaAs quantum dots

“…Для объяснения этого эффекта можно предложить следующую модель. Расчеты [12] упругих напряжений и зонной структуры гетеросистемы с двумя слоями квантовых точек показывают, что слой InAs испытывает напряжения сжатия, а слой GaAs -растягивающие напряжения, в результате чего подзона легких дырок в GaAs поднимается по энергии выше подзоны тяжелых дырок GaAs, но все же остается ниже энергии подзоны тяжелых дырок в КТ InAs. Сильное электрическое поле увеличивает интеграл перекрытия волновых функций электронов в КТ InAs и легких дырок в GaAs.…”

Наногетероструктуры С Улучшенными Параметрами Для Быстродействующих И Высокоэффективных Плазмон-Поляритонных Светодиодов Шоттки

Size-dependent Electronic and Polarization Properties of Multi-Layer InAs Quantum Dot Molecules