CALCULATIONS OF INTERDIFFUSION AND THE QUANTUM-CONFINED STARK-EFFECT IN GAAS-GAALAS QUANTUM-WELLS

被引：3

作者：

SEIDEL, W

VOISIN, P

机构：

[1] Lab. de Phys. de la Matiere Condensee, Ecole Normale Superieure, Paris

来源：

SEMICONDUCTOR SCIENCE AND TECHNOLOGY | 1993年 / 8卷 / 10期

关键词：

D O I：

10.1088/0268-1242/8/10/017

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

The partial intermixing of well and barrier materials offers unique opportunities to shift locally the bandgap of quantum well (QW) structures. In combination with the quantum confined Stark effect it can be used for many applications in integrated optoelectronics. Here we investigate theoretically the optical and electro-optical properties of partially intermixed GaAs-GaAlAs QW structures. We calculate the dependences of energy shifts and absorption spectra as a function of the well width, the interdiffusion length and the applied electric field. We show in particular that large blue shifting by interdiffusion and efficient electro-optical modulation can be achieved only for a narrow range of ow widths.

引用

页码：1885 / 1888

页数：4

共 50 条

[21] QUANTUM-CONFINED STARK-EFFECT IN INGAAS INP QUANTUM-WELLS GROWN BY ORGANOMETALLIC VAPOR-PHASE EPITAXY
BARJOSEPH, I
KLINGSHIRN, C
MILLER, DAB
CHEMLA, DS
KOREN, U
MILLER, BI
APPLIED PHYSICS LETTERS, 1987, 50 (15) : 1010 - 1012
[22] QUANTUM-CONFINED START EFFECT IN INGAP/GAAS MULTIPLE QUANTUM-WELLS
PATRIZI, GA
WU, DG
HAFICH, MJ
LEE, HY
SILVESTRE, P
ROBINSON, GY
JOURNAL OF ELECTRONIC MATERIALS, 1990, 19 (07) : 12 - 12
[23] CONTROLLABLE ENHANCEMENT OF EXCITONIC SPONTANEOUS EMISSION BY QUANTUM CONFINED STARK-EFFECT IN GAAS QUANTUM-WELLS EMBEDDED IN QUANTUM MICROCAVITIES
OCHI, N
SHIOTANI, T
YAMANISHI, M
HONDA, Y
SUEMUNE, I
APPLIED PHYSICS LETTERS, 1991, 58 (24) : 2735 - 2737
[24] COMPARISON OF THE QUANTUM-CONFINED STARK-EFFECT FOR (100)A-ORIENTED AND (311)A-ORIENTED GAAS/ALGAAS QUANTUM-WELLS USING ELECTROREFLECTANCE SPECTROSCOPY
GOLDHAHN, R
SHOKHOVETS, S
GOBSCH, G
NAKOV, V
HENINI, M
HILL, G
SUPERLATTICES AND MICROSTRUCTURES, 1995, 17 (04) : 401 - 405
[25] NON-ZONE-FOLDED TRANSITION-ENERGY CALCULATIONS FOR QUANTUM-CONFINED STARK-EFFECT IN SI1-XGEX/SI QUANTUM-WELLS
CHOWDHURY, AA
JUNG, KH
KWONG, DL
MAZIAR, CM
JOURNAL OF APPLIED PHYSICS, 1991, 70 (07) : 3946 - 3948
[26] QUANTUM-CONFINED STARK-EFFECT IN INGAAS/INP MULTIPLE QUANTUM-WELLS GROWN BY SOLID SOURCE MOLECULAR-BEAM EPITAXY
CLAXTON, PA
HOPKINSON, M
KOVAC, J
HILL, G
PATE, MA
DAVID, JPR
JOURNAL OF CRYSTAL GROWTH, 1991, 111 (1-4) : 1080 - 1083
[27] STARK-EFFECT IN GAINAS/GAINASP QUANTUM-WELLS
MARIE, X
BARRAU, J
BROUSSEAU, B
AMAND, T
BROUSSEAU, M
LAURET, N
STARCK, C
PERALES, A
SUPERLATTICES AND MICROSTRUCTURES, 1991, 10 (01) : 95 - 98
[28] QUANTUM-CONFINED STARK-EFFECT MODULATORS AT 1.06-MU-M ON GAAS
FAN, C
SHIH, DW
HANSEN, MW
ESENER, SC
WIEDER, HH
IEEE PHOTONICS TECHNOLOGY LETTERS, 1993, 5 (12) : 1383 - 1385
[29] OPTICAL STARK-EFFECT IN GAAS QUANTUM WELLS
MYSYROWICZ, A
HULIN, D
JOURNAL DE PHYSIQUE, 1988, 49 (C-2): : 175 - 177
[30] EFFECT OF ELECTRON PHONON COUPLING ON THE QUANTUM-CONFINED STARK-EFFECT
XU, W
XI, XL
KAN, C
SOLID STATE COMMUNICATIONS, 1988, 65 (01) : 83 - 85

← 1 2 3 4 5 →