Your search keyword '"electron-beam-induced current"' showing total 42 results

1. Analysis of Nanowire pn-Junction with Combined Current–Voltage, Electron-Beam-Induced Current, Cathodoluminescence, and Electron Holography Characterization.

Author

Anttu, Nicklas, Fiordaliso, Elisabetta Maria, Garcia, José Cano, Vescovi, Giuliano, and Lindgren, David

Subjects

ELECTRON holography, CATHODOLUMINESCENCE, NANOWIRES, OPTOELECTRONIC devices, DOPING agents (Chemistry)

Abstract

We present the characterization of a pn-junction GaAs nanowire. For the characterization, current–voltage, electron-beam-induced current, cathodoluminescence, and electron holography measurements are used. We show that by combining information from these four methods, in combination with drift-diffusion modelling, we obtain a detailed picture of how the nanowire pn-junction is configured and how the recombination lifetime varies axially in the nanowire. We find (i) a constant doping concentration and 600 ps recombination lifetime in the n segment at the top part of the nanowire; (ii) a 200–300 nm long gradient in the p doping next to the pn-junction; and (iii) a strong gradient in the recombination lifetime on the p side, with 600 ps lifetime at the pn-junction, which drops to 10 ps at the bottom of the p segment closest to the substrate. We recommend such complementary characterization with multiple methods for nanowire-based optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

2. Experimental and theoretical EBIC analysis for grain boundary and CdS/Cu (In, Ga)Se2 heterointerface in Cu (In, Ga)Se2 solar cells.

Author

Fukuda, Ryotaro, Nishimura, Takahito, and Yamada, Akira

Subjects

SOLAR cells, COPPER, CRYSTAL grain boundaries, CONDUCTION bands, VALENCE bands, GRAIN

Abstract

The behavior of carriers for an electron‐beam‐induced current (EBIC) evaluation is experimentally and theoretically analyzed for the polycrystalline Cu (In, Ga)Se2 (CIGS) thin‐film solar cells. The experimental EBIC signal in‐depth profiles of the CIGS layers show four features: peaks at grain boundaries (GBs), narrowed peaks near the surface, shifted peaks near the surface, and double peaks at the GBs and surface. Operating principles for CIGS solar cell devices under electron–hole pair excitation are systematically revealed utilizing a two‐dimensional theoretical EBIC simulation: (i) The EBIC peaks at the GBs are caused by a high hole barrier, including a valence band offset (ΔEV) and a band bending at the GBs; (ii) narrowing of EBIC peaks near the surface is caused by high defect densities at the GBs, grading of a conduction band minimum, and grading of acceptor concentration (Na) along with the CIGS depth direction; (iii) a shift in EBIC peaks near the surface is caused by high donor‐like defect densities at the surface; (iv) double peaks at the GBs and surface are caused by a thick surface layer (SL) with the ΔEV and the hole barrier at GBs. These findings of the EBIC analysis will help to comprehensively understand the complex polycrystalline CIGS carrier transport mechanism in realizing the highest‐efficiency CIGS solar cells. [ABSTRACT FROM AUTHOR]

Published

2023

3. Analysis of Nanowire pn-Junction with Combined Current–Voltage, Electron-Beam-Induced Current, Cathodoluminescence, and Electron Holography Characterization

Author

Nicklas Anttu, Elisabetta Maria Fiordaliso, José Cano Garcia, Giuliano Vescovi, and David Lindgren

Subjects

III–V semiconductor nanowire, electron-beam-induced current, cathodoluminescence, current–voltage characterization, electron holography, drift-diffusion modelling, Mechanical engineering and machinery, TJ1-1570

Abstract

We present the characterization of a pn-junction GaAs nanowire. For the characterization, current–voltage, electron-beam-induced current, cathodoluminescence, and electron holography measurements are used. We show that by combining information from these four methods, in combination with drift-diffusion modelling, we obtain a detailed picture of how the nanowire pn-junction is configured and how the recombination lifetime varies axially in the nanowire. We find (i) a constant doping concentration and 600 ps recombination lifetime in the n segment at the top part of the nanowire; (ii) a 200–300 nm long gradient in the p doping next to the pn-junction; and (iii) a strong gradient in the recombination lifetime on the p side, with 600 ps lifetime at the pn-junction, which drops to 10 ps at the bottom of the p segment closest to the substrate. We recommend such complementary characterization with multiple methods for nanowire-based optoelectronic devices.

Published

2024

4. EBIC Imaging of Conductive Paths Formed in Graphene Oxide as a Result of Resistive Switching.

Author

Yakimov, Eugene B., Koveshnikov, Sergei, and Kononenko, Oleg

Subjects

METAL insulator semiconductors, ELECTRON beams

Abstract

The electron-beam-induced current (EBIC) method is utilized in this work to visualize conductive channels formed in graphene oxide as a result of resistive switching. Using metal–insulator–semiconductor (MIS) structures, an increase in the electron beam induced current by a few orders of magnitude as compared with the EBIC signal in metal–insulator–metal (MIM) structures is achieved. The mechanism of the EBIC image formation related to the conductive channels is explained by the separation and collection of the e-beam generated excess carriers by rectifying barrier nanocontacts formed at the graphene oxide/Si interface during resistive switching. It is shown that the collection efficiency of the formed nanocontacts decreases with the beam energy, in agreement with the theoretical predictions for the Schottky-like nanocontacts. An important advantage of the EBIC method is demonstrated in its ability to monitor the generation and elimination of high density conductive channels even when the current–voltage measurements cannot detect and separate these processes. EBIC study of the dynamics of the conductive channel formation can help better understand the underlying physical mechanisms of their generation. [ABSTRACT FROM AUTHOR]

Published

2023

5. Influence of the Structural Parameters of Triple Junctions of Special Grain Boundaries on Their Recombination Activity.

Author

Chueshova, A. G., Pescherova, S. M., Pavlova, L. A., Nepomnyashchikh, A. I., Ludina, E. A., Yakimov, E. B., Feklisova, O. V., and Fedina, L. I.

Abstract

The geometric parameters of the grain boundaries that make up triple joints and their possible combinations are studied by electron backscatter diffraction using Channel HKL5 software. It is shown experimentally that, in addition to the previously studied and fairly widespread triple joints of special grain boundaries, there are other varieties of them. It is found that at these triple junctions, in particular, the geometric combination rule is violated, which may indirectly indicate the recombination activity of special boundaries. [ABSTRACT FROM AUTHOR]

Published

2021

6. Electron‐Beam‐Induced Current and Deep‐Level Transient Spectroscopy Study of Dislocation Trails in Au‐Doped Si.

Author

Feklisova, Olga V., Orlov, Valery I., and Yakimov, Eugene B.

Subjects

*SCHOTTKY barrier, *SPECTROMETRY, *POINT defects, *MATERIAL plasticity, *GOLD

Abstract

The properties of extended defects introduced by plastic deformation at 600 °C in n‐Si co‐doped with gold are studied by the electron‐beam‐induced current (EBIC) and deep‐level transient spectroscopy (DLTS) methods. It is shown that intrinsic point defects generated by moving dislocations stimulate the gold redistribution. As a result, regions depleted with gold are formed near dense dislocation rows. It is shown that dislocation trails decorated with gold are charged, which is a reason for the formation of bright EBIC contrast outside the Schottky barrier. [ABSTRACT FROM AUTHOR]

Published

2021

7. EBIC Imaging of Conductive Paths Formed in Graphene Oxide as a Result of Resistive Switching

Author

Eugene B. Yakimov, Sergei Koveshnikov, and Oleg Kononenko

Subjects

electron-beam-induced current, graphene oxide, metal–insulator–semiconductor structure, resistive switching, rectifying nanocontact, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The electron-beam-induced current (EBIC) method is utilized in this work to visualize conductive channels formed in graphene oxide as a result of resistive switching. Using metal–insulator–semiconductor (MIS) structures, an increase in the electron beam induced current by a few orders of magnitude as compared with the EBIC signal in metal–insulator–metal (MIM) structures is achieved. The mechanism of the EBIC image formation related to the conductive channels is explained by the separation and collection of the e-beam generated excess carriers by rectifying barrier nanocontacts formed at the graphene oxide/Si interface during resistive switching. It is shown that the collection efficiency of the formed nanocontacts decreases with the beam energy, in agreement with the theoretical predictions for the Schottky-like nanocontacts. An important advantage of the EBIC method is demonstrated in its ability to monitor the generation and elimination of high density conductive channels even when the current–voltage measurements cannot detect and separate these processes. EBIC study of the dynamics of the conductive channel formation can help better understand the underlying physical mechanisms of their generation.

Published

2023

8. High Spatial Resolution Ion Imaging by Focused Electron-Beam Excitation with Nanometric Thin Sensor Substrate

Author

Kiyohisa Nii, Wataru Inami, and Yoshimasa Kawata

Subjects

light-addressable potentiometric sensor, high spatial resolution, electron-beam-induced current, thin sensor substrate, chemical imaging system, electron-beam addressable potentiometric sensor, Chemical technology, TP1-1185

Abstract

We developed a high spatially-resolved ion-imaging system using focused electron beam excitation. In this system, we designed a nanometric thin sensor substrate to improve spatial resolution. The principle of pH measurement is similar to that of a light-addressable potentiometric sensor (LAPS), however, here the focused electron beam is used as an excitation carrier instead of light. A Nernstian-like pH response with a pH sensitivity of 53.83 mV/pH and linearity of 96.15% was obtained. The spatial resolution of the imaging system was evaluated by applying a photoresist to the sensing surface of the ion-sensor substrate. A spatial resolution of 216 nm was obtained. We achieved a substantially higher spatial resolution than that reported in the LAPS systems.

Published

2022

9. Electrostatic potential fluctuations and light‐soaking effects in Cu(In,Ga)Se2 solar cells.

Author

Nikolaeva, Aleksandra, Krause, Maximilian, Schäfer, Norbert, Witte, Wolfram, Hariskos, Dimitrios, Kodalle, Tim, Kaufmann, Christian A., Barreau, Nicolas, and Abou‐Ras, Daniel

Subjects

ELECTRIC potential, SOLAR cells, SILICON solar cells, ELECTRON diffusion, POINT defects, BUFFER layers, OPEN-circuit voltage, CATHODOLUMINESCENCE

Abstract

In Cu(In,Ga)Se2 (CIGS) thin‐film solar cells, laterally inhomogeneous distributions of point defects may induce electrostatic potential fluctuations and thus reduce the open‐circuit voltage (Voc). In the present work, we investigate possible origins of fluctuating potentials and estimate the amplitude of fluctuations and Voc losses in solar cells with various [Ga] in the CIGS absorber, with different buffer layers and with different durations of an RbF postdeposition treatment (PDT). Electron‐beam‐induced current measurements were employed to study the local difference in the width of the space‐charge region (wSCR). It is shown that the amplitude of fluctuations in the wSCR depends significantly on the choice of buffer system and on the duration of the RbF PDT. In addition, energy‐dispersive X‐ray spectroscopy and cathodoluminescence measurements reveal that band‐gap fluctuations do not have substantial impact on the device performance. Finally, some of the investigated cells were exposed to light soaking, which was found to be a means to reduce the detected electrostatic potential fluctuations and also to increase the effective electron diffusion length in the CIGS absorber for a part of the investigated cells. [ABSTRACT FROM AUTHOR]

Published

2020

10. Technology Support for High-Throughput Processing of Thin-Film CdTe PV Modules: Final Technical Report, April 1998 - October 2001

Author

Powell, R

Published

2002

11. Overcoming degradation mechanisms in CdTe solar cells: First annual report, August 1998--August 1999

Author

Dobson, K

Published

2000

12. Enhanced Hydrogen Evolution under Simulated Sunlight from Neutral Electrolytes on (ZnSe)0.85(CuIn0.7Ga0.3Se2)0.15 Photocathodes Prepared by a Bilayer Method.

Author

Kaneko, Hiroyuki, Minegishi, Tsutomu, Nakabayashi, Mamiko, Shibata, Naoya, and Domen, Kazunari

Subjects

*PHOTOCATHODES, *ELECTROCHEMISTRY, *HYDROGEN production, *HYDROGEN evolution reactions, *CROSS-sectional method

Abstract

A (ZnSe)0.85(CuIn0.7Ga0.3Se2)0.15 photocathode with a bilayer structure was fabricated and found to exhibit a photocurrent almost twice that of a photocathode with a monolayer structure during hydrogen evolution from water. The cathodic photocurrent reached maximum values of 12 and 4.9 mA cm−2 at 0 and 0.6 VRHE in a neutral phosphate buffer under simulated sunlight, while the half-cell solar-to-hydrogen conversion efficiency was 3.0 % at 0.6 VRHE, with a maximum value of 3.6 % at 0.45 VRHE. Cross-sectional mapping of the electron-beam-induced current established that the increased photocurrent can be attributed to improved uniformity at the solid-liquid junction in the bilayer sample, which results in enhanced carrier collection. [ABSTRACT FROM AUTHOR]

Published

2016

13. Effect of Σ3 generation on random grain boundaries in multicrystalline silicon.

Author

Luo, Xianjia, Prakash, Ronit R., Chen, Jun, Jiptner, Karolin, and Sekiguchi, Takashi

Subjects

*SILICON compounds, *CRYSTAL grain boundaries, *PHYSICAL constants, *CHEMICAL templates, *STEADY state conduction

Abstract

The effect of Σ3 generation on random grain boundaries (R-GBs) were investigated using multicrystalline Si (mc-Si) grown from the microcrystalline template with random orientation. There existed three cases for the contrast variation of electron-beam-induced current (EBIC) on R-GBs after Σ3 generation from them, namely decrease, increase and constant cases. No clear tendency of EBIC contrast variation was found at the initial growth stage. On the other hand, the constant case became dominant at the steady state. This result indicates that Σ3 generation does not affect the electrical activity of R-GBs. [ABSTRACT FROM AUTHOR]

Published

2016

14. Reprint of “Imaging of diamond defect sites by electron-beam-induced current”.

Author

Kono, S., Teraji, T., Kodama, H., and Sawabe, A.

Subjects

*DIAMOND crystals, *CRYSTAL defects, *ELECTRON beams, *SCHOTTKY barrier, *IMAGE intensifiers

Abstract

The method of electron-beam-induced current (EBIC) was used to visualize the defect sites on a p-type (boron-doped) diamond (001) film. For this purpose, an Ag-Schottky layer (~ 2 mm × ~ 2 mm × ~ 50 nm) was deposited on the oxygen-terminated p-type diamond (001) film and used as a source of EBIC signal. The signal current of EBIC image appeared to be as large as ~ 1200 times that of the incident electron-beam current and the difference range in image intensity was also large (1–1200). The observed EBIC images showed many kinds of signatures that are possible ‘killer’ defects for Schottky devices. In order to identify ‘killer’ defects in the EBIC image, an array of Ag-dots (~ 40 × ~ 50 μm 2 ) was deposited on an oxygen-terminated p-type diamond (001) film and I–V characteristics were measured on 53 Ag-dots. The resulting I–V characteristics showed that 21 Ag-dots reside on ‘killer’ defects. Comparison between the EBIC image and the positions of Ag-dots residing on ‘killer’ defects showed that large dark dots in EBIC image correspond to the position of ‘killer’ defects. The number density of the large dark dots (i.e., ‘killer’ defects) was ~ 10 4 /cm 2 in the present sample. It is suggested that a high yield Schottky-junction device may be fabricated by avoiding these ‘killer’ defects by the use of EBIC. [ABSTRACT FROM AUTHOR]

Published

2016

15. Imaging of diamond defect sites by electron-beam-induced current.

Author

Kono, S., Teraji, T., Kodama, H., and Sawabe, A.

Subjects

*DIAMOND crystals, *IMAGING systems, *CRYSTAL defects, *ELECTRON beams, *SCHOTTKY barrier diodes, *P-type semiconductors

Abstract

The method of electron-beam-induced current (EBIC) was used to visualize the defect sites on a p-type (boron-doped) diamond (001) film. For this purpose, an Ag-Schottky layer (~ 2 mm × ~ 2 mm × ~ 50 nm) was deposited on the oxygen-terminated p-type diamond (001) film and used as a source of EBIC signal. The signal current of EBIC image appeared to be as large as ~ 1200 times that of the incident electron-beam current and the difference range in image intensity was also large (1–1200). The observed EBIC images showed many kinds of signatures that are possible ‘killer’ defects for Schottky devices. In order to identify ‘killer’ defects in the EBIC image, an array of Ag-dots (~ 40 × ~ 50 μm 2 ) was deposited on an oxygen-terminated p-type diamond (001) film and I–V characteristics were measured on 53 Ag-dots. The resulting I–V characteristics showed that 21 Ag-dots reside on ‘killer’ defects. Comparison between the EBIC image and the positions of Ag-dots residing on ‘killer’ defects showed that large dark dots in EBIC image correspond to the position of ‘killer’ defects. The number density of the large dark dots (i.e., ‘killer’ defects) was ~ 10 4 /cm 2 in the present sample. It is suggested that a high yield Schottky-junction device may be fabricated by avoiding these ‘killer’ defects by the use of EBIC. [ABSTRACT FROM AUTHOR]

Published

2015

16. Investigation of nitride films by the electron-beam-induced current method.

Author

Yakimov, E.

Abstract

The peculiarities of the application of the electron-beam-induced current (EBIC) method for characterizing nitride-based semiconductor materials with a submicron diffusion length of excess charge carriers are analyzed. It is shown that the most reliable diffusion-length values are obtained by measuring the dependence of the induced current on the beam energy. The reasons for submicron resolution in the detection of extended defects in these materials by EBIC are discussed. [ABSTRACT FROM AUTHOR]

Published

2015

17. Attraction of semiconductor nanowires: An in situ observation.

Author

Chen, Bin, Gao, Qiang, Chang, Li, Wang, Yanbo, Chen, Zibin, Liao, Xiaozhou, Tan, Hark Hoe, Zou, Jin, Ringer, Simon P., and Jagadish, Chennupati

Subjects

*GALLIUM arsenide semiconductors, *SEMICONDUCTOR nanowires, *TRANSMISSION electron microscopy, *NANOSTRUCTURED materials, *DEFORMATIONS (Mechanics), *MAGNETIC properties of metals

Abstract

Abstract: In situ deformation transmission electron microscopy was used to study the attraction behavior of GaAs semiconductor nanowires (NWs). The NWs demonstrated an interesting phenomenon of either head-to-head or body-to-body attraction at distances that depend on the NW diameters. The NWs with a diameter of ∼25nm attracted at a distance of ∼25nm, while large-diameter NWs of ∼55nm showed no obvious attraction. The underlying mechanism governing the attraction of the NWs is proposed and discussed with a mechanistic model. The diameter dependence on the NW attraction behavior is discussed. The finding provides an understanding of the Ampère force in nanostructured materials caused by an electron-beam-induced current while technologically it provides useful hints for designing NW-based devices according to the diameter-dependent attraction behavior of NWs. [Copyright &y& Elsevier]

Published

2013

18. Mapping of minority carrier lifetime distributions in multicrystalline silicon using transient electron-beam-induced current.

Author

Takuya Kushida, Shigeyasu Tanaka, Chiaki Morita, Takayoshi Tanji, and Yoshio Ohshita

Subjects

*ELECTRON beams, *SCANNING transmission electron microscopy, *COMPUTER simulation, *ELECTRON beam induced current, *SILICON wafers

Abstract

We have used transient electron-beam-induced current (EBIC) to map minority carrier lifetime distributions in multicrystalline Silicon (mc-Si). In this technique, the electron beam from a scanning transmission electron microscope was on-off modulated while the sample was scanned. The resulting transient EBIC was analyzed to form a lifetime map. An analytical function was introduced as part of the analysis in determining this map. We have verified this approach using numerical simulations and have reproduced a lifetime map for an mc-Si wafer. [ABSTRACT FROM AUTHOR]

Published

2012

19. Analysis of Cu(In,Ga)(S,Se)2 thin-film solar cells by means of electron microscopy

Author

Abou-Ras, D., Dietrich, J., Kavalakkatt, J., Nichterwitz, M., Schmidt, S.S., Koch, C.T., Caballero, R., Klaer, J., and Rissom, T.

Subjects

*SOLAR cells, *THIN films, *COPPER compounds, *ELECTRON microscopy, *INTERFACES (Physical sciences), *ELECTRON holography, *ELECTRON beams, *ELECTRON energy loss spectroscopy, *ELECTRON backscattering

Abstract

Abstract: The present work gives an overview of how electron microscopy and its related techniques are used to analyze individual layers and their interfaces in Cu(In,Ga)(S,Se)2 thin-film solar cells. Imaging of samples can be performed at scales of down to the (sub)angstroms range. At similar spatial resolutions, information on composition can be gathered by means of energy-dispersive X-ray spectroscopy (EDX) and on spatial distributions of electrostatic Coulomb potentials in the specimen by applying electron holography. Microstructural and compositional properties as well as charge-carrier collection and radiative recombination behavior of the individual layers are accessible by use of electron backscatter diffraction, EDX, electron-beam-induced current (EBIC) and cathodoluminescence measurements, available in scanning electron microscopy. The present contribution gives an overview of the various scanning and transmission electron microscopy techniques applied on Cu(In,Ga)(S,Se)2 thin-film solar cells, examples from case studies, and also demonstrates how these techniques may be combined in order to improve the analysis. Particularly, EBIC results show a reduced charge-carrier collection at Cu(In,Ga)Se2 grain boundaries, while no indication was found for a charge accumulation at the grain boundaries by electron holography. [Copyright &y& Elsevier]

Published

2011

20. High Spatial Resolution Ion Imaging by Focused Electron-Beam Excitation with Nanometric Thin Sensor Substrate.

Author

Nii, Kiyohisa, Inami, Wataru, and Kawata, Yoshimasa

Subjects

*SPATIAL resolution, *ELECTRON beams, *IMAGING systems in chemistry, *ELECTRONIC excitation, *IMAGING systems, *DETECTORS

Abstract

We developed a high spatially-resolved ion-imaging system using focused electron beam excitation. In this system, we designed a nanometric thin sensor substrate to improve spatial resolution. The principle of pH measurement is similar to that of a light-addressable potentiometric sensor (LAPS), however, here the focused electron beam is used as an excitation carrier instead of light. A Nernstian-like pH response with a pH sensitivity of 53.83 mV/pH and linearity of 96.15% was obtained. The spatial resolution of the imaging system was evaluated by applying a photoresist to the sensing surface of the ion-sensor substrate. A spatial resolution of 216 nm was obtained. We achieved a substantially higher spatial resolution than that reported in the LAPS systems. [ABSTRACT FROM AUTHOR]

Published

2022

21. Electron-Beam-Induced-Current Investigation of GaN/AlGaN/Si Heterostructures Using Scanning Transmission Electron Microscopy.

Author

Tanaka, Shigeyasu, Aoyama, Kentaro, Ichihashi, Mikio, Arai, Shigeo, Honda, Yoshio, and Sawaki, Nobuhiko

Subjects

*GALLIUM nitride, *ALUMINUM, *SILICON, *HETEROSTRUCTURES, *SCANNING transmission electron microscopy

Abstract

An electron-beam-induced-current technique has been applied to scanning transmission electron microscopy to characterize GaN/AlGaN/n-Si heterostructures. The structure was formed by metalorganic vapor phase epitaxy using AlGaN as an intermediate layer. Two samples with nominal intermediate layer thicknesses of 60 and 120 nm were studied. It was found that there is a junction in the n-type Si region underneath the nitride/Si interface irrespective of the intermediate layer thickness, whereas induced current occurred neither in the nitride region nor at the nitride/Si interface. The junction formed was found to be undulated. The sample with the thin intermediate layer had undulations of a shorter periodicity than that with the thick intermediate layer. The formation of the junction is attributed to the diffusion of Al during the nitride growth. [ABSTRACT FROM PUBLISHER]

Published

2007

22. Vertical Transport Study of III-V Type-II Superlattices

Author

Dr. Ganesh Balakrishnan, Dr. Sanjay Krishna, Dr. Elizabeth H. Steenbergen, Dr. Rohit P. Prasankumar, Taghipour, Zahra, Dr. Ganesh Balakrishnan, Dr. Sanjay Krishna, Dr. Elizabeth H. Steenbergen, Dr. Rohit P. Prasankumar, and Taghipour, Zahra

Subjects

Vertical transport

Abstract

Type-II strained layer superlattice (T2SL) semiconductors hold great promise for mid- and long-wavelength infrared photodetectors. While T2SL-based materials have advanced significantly in the last three decades, an outstanding challenge to improve the T2SLs is to understand the carrier transport and its limitations, in particular along the superlattice growth layers. In this dissertation, an overview of the current state-of-the-art InAs/GaSb T2SLs is presented. Fundamental semiconductor device equations and transport properties, including miniband conduction and the drift-diffusion parameters, are reviewed, and the fundamental limiting factors in carrier's transport are discussed. Furthermore, the standard method of electron-beam-induced current technique to measuring these parameters is described. The bulk of the manuscript will then explore the characterization of transport properties in an InAs/GaSb nBp photodetector through a variety of techniques. Through electron-beam-induced-current ($EBIC$) measurements, the minority carrier diffusion length along the growth direction has been measured. The $EBIC$ analysis combined with lifetime measurements using time-resolved microwave reflectance method is then used to calculate the minority electron mobility along the growth direction. Quantum efficiency modeling technique is used as an alternative approach to studying transport and quantify the complex relationships between the device performance and the underlying physics involved in it. Photocurrent-voltage measurement is also used to qualitatively investigate the drift characteristics, such as the field dependence of the drift mobility and drift velocity. Finally, the result of a recent study on the electronic band structure of a series of narrow-band superlattices is summarized.

Published

2018

23. On the degradation of InGaAsP/InP-based bulk lasers.

Author

Kallstenius, T., Backstrom, J., Smith, U., and Stoltz, B.

Abstract

Degradation of InGaAsP-InP-based buried-heterostructure bulk (BH-bulk) lasers has been studied by means of electroluminescence (EL), photoluminescence (PL), electron-beam-induced current (EBIC) and transmission electron microscopy (TEM). Lasers with p/n as well as semi-insulating (SI) current-blocking layers were studied. The results show that moderate increases in the threshold current correlate well with formation of dark defects (DD's) (i.e., dark-line defects (DLD's) or dark-spot defects (DSD's), which cannot be distinguished in our case due to the narrowness of the laser stripe.) The DD's were found to be caused by dislocation loops. The dependence of threshold current increase on the number of DD's is explained in terms of a model which includes effects due to the DD's, as well as changes in the regions outside the DD's. The latter is found to be responsible for the major part of the threshold current increase. Values for the ratio between the carrier lifetimes inside and outside the DD's are presented, for the first time. In our lasers, strong degradation differs from moderate degradation in that DD's do not form during aging. The presence of dislocation loops only at the sidewalls of the active stripe in lasers with p/n current-blocking layers points to the sidewalls as being critical. The near absence of dislocation loops and the smaller increase in threshold current in SI lasers which have degraded strongly, compared to the strongly degrading p/n lasers, suggest that strong degradation is a synergistic combination of damage in the sidewalls and Zn indiffusion from the current-blocking layers [ABSTRACT FROM PUBLISHER]

Published

1999

24. Site of Acoustic Signal Generation by Chopped Electron Beam (Electron-Acoustic Microscopy).

Author

Takenoshita, Hiroshi and Kobayashi, Mutsuo

Abstract

The junction between the base and the collector of an npn Si transistor-chip was exposed by angle lapping and microscopically observed. The specimen thus prepared under various bias conditions was observed by SEM and electron-acoustic microscopy (EAM). The results are as follows. (1) The site of acoustic signal generation by irradiation of the chopped electron beam remains unchanged under varying bias voltages. (2) The amplitude of the acoustic signal changes under various bias conditions. (3) The acoustic signal- and electron-beam-induced current signals nearly correspond to each other under bias applications, but they are clearly different signal modes. The mechanism of acoustic signal generation is suggested and discussed. [ABSTRACT FROM PUBLISHER]

Published

1991

25. Electron beam induced current on carbon nanotubes measured through substrate electrodes

Author

Park, J. K. and Ahn, Y. H.

Published

2015

26. Nanoscale Dopant Profiling of Individual Semiconductor Wires by Capacitance-Voltage Measurement.

Author

Lassiaz T, Tchoulfian P, Donatini F, Brochet J, Parize R, Jacopin G, and Pernot J

Abstract

Developing nanoscale electrical characterization techniques adapted to three-dimensional (3D) geometry is essential for optimization of the epitaxial structure and doping process of nano- and microwires. In this paper, we demonstrate the assessment of the depletion width as well as the doping profile at the nanoscale of individual microwire core-shell light-emitting devices by capacitance-voltage measurements. A statistical study carried out on single wires shows the consistency of the doping profile values measured for individual microwires compared to assemblies of hundreds of wires processed on the same sample. The robustness of this method is then demonstrated on four epitaxial structures with different growth and doping conditions. Finally, electron-beam-induced current and secondary electron profiles are used to validate the depletion region width and the position in the core-shell structure.

Published

2021

27. Determination of Current Leakage Sites in Diamond p–n Junction.

Author

Murooka, Takuya, Umezawa, Hitoshi, Makino, Toshiharu, Ogura, Masahiko, Kato, Hiromitsu, Yamasaki, Satoshi, Iwasaki, Takayuki, Pernot, Julien, and Hatano, Mutsuko

Subjects

*ATOMIC force microscopy techniques, *SCANNING electron microscopes, *DISLOCATIONS in crystals, *LEAKAGE

Abstract

Current leakage sites in diamond p–n junction are determined by measuring an electron‐beam–induced current (EBIC) technique and conductive atomic force microscopy (C‐AFM). Current leakage sites in p–n diodes, particularly, can be determined by means of EBIC without destruction of the device structure. From EBIC observation, bright spots with higher signal intensity than these in surrounding region are observed in p–n diodes, and these spots strongly correlate with the leakage current. It is found that these bright spots are originating from pits of comet‐shaped defects observed by a scanning electron microscope. With C‐AFM, the leakage current is detected at pits of comet‐shaped defects. Reduction in comet‐shaped defects shall be reduced using the technique of reduction in dislocation and high‐quality crystal growth to suppress the leakage current. [ABSTRACT FROM AUTHOR]

Published

2019

28. Electron-beam-induced current measurements with applied bias provide insight to locally resolved acceptor concentrations at p-n junctions

Author

Stephan Brunken, N. Baldaz, N. Schäfer, Christian Boit, and Daniel Abou-Ras

Subjects

Methods and concepts for material development, p-n junction, Materials science, Electrical junction, Electron beam-induced current, Doping, Analytical chemistry, General Physics and Astronomy, Biasing, 530 Physik, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Space charge, Molecular physics, Capacitance, lcsh:QC1-999, electron-beam-induced current, local electrical property, electrical junction, ddc:530, measurement, Electric potential, Electric current, lcsh:Physics

Abstract

Electron beam induced current EBIC measurements have been employed for the investigation of the local electrical properties existing at various types of electrical junctions during the past decades. In the standard configuration, the device under investigation is analyzed under short circuit conditions. Further insight into the function of the electrical junction can be obtained when applying a bias voltage. The present work gives insight into how EBIC measurements at applied bias can be conducted at the submicrometer level, at the example of CuInSe2 solar cells. From the EBIC profiles acquired across ZnO CdS CuInSe2 Mo stacks exhibiting p n junc tions with different net doping densities in the CuInSe2 layers, values for the width of the space charge region, w, were extracted. For all net doping densities, these values decreased with increasing applied voltage. Assuming a linear relationship between w2 and the applied voltage, the resulting net doping densities agreed well with the ones obtained by means of capacitance voltage measurements. C 2015 Author s . All article content, except where otherwise noted, is licensed under a Creative Commons Attribution 3.0 Unported License

Published

2015

29. Assessing the Device-performance Impacts of Structural Defects with TCAD Modeling

Author

Needleman, David Berney, Wagner, Hannes, Altermatt, Pietro P., Buonassisi, Tonio, Needleman, David Berney, Wagner, Hannes, Altermatt, Pietro P., and Buonassisi, Tonio

Abstract

Advanced solar cell architectures like passivated emitter and rear (PERC) and heterojunction with intrinsic thin layer (HIT) are increasingly sensitive to bulk recombination. Present device models consider homogeneous bulk lifetime, which does not accurately reflect the effects of heterogeneously distributed defects. To determine the efficiency potential of multicrystalline silicon (mc-Si) in next-generation architectures, we present a higher-dimensional numerical simulation study of the impacts of structural defects on solar cell performance. We simulate these defects as an interfacial density of traps with a single mid-gap energy level using Shockley-Read-Hall (SRH) statistics. To account for enhanced recombination at the structural defects, we apply a linear scaling to the majority-carrier capture cross-section and scale the minority-carrier capture cross-section with the inverse of the line density of traps. At 300 K, our simulations of carrier occupation and recombination rate match literature electron-beam-induced current (EBIC) data and first-principles calculations of carrier capture, emission, and recombination for all the energy levels associated with dislocations decorated with metal impurities. We implement our model in Sentaurus Device, determining the losses across different device architectures for varying impurity decoration of grain boundaries.

Published

2015

30. Effect of Crystallographic Orientation and Nanoscale Surface Morphology on Poly-Si/SiO x Contacts for Silicon Solar Cells.

Author

Kale AS, Nemeth W, Guthrey H, Nanayakkara SU, LaSalvia V, Theingi S, Findley D, Page M, Al-Jassim M, Young DL, Stradins P, and Agarwal S

Abstract

High-efficiency crystalline silicon (Si) solar cells require textured surfaces for efficient light trapping. However, passivation of a textured surface to reduce carrier recombination is difficult. Here, we relate the electrical properties of cells fabricated on a KOH-etched, random pyramidal-textured Si surface to the nanostructure of the passivated contact and the textured surface morphology. The effects of both microscopic pyramidal morphology and nanoscale surface roughness on passivated contacts consisting of polycrystalline Si ( poly -Si) deposited on top of an ultrathin, 1.5-2.2 nm, SiO x layer are investigated. Using atomic force microscopy, we show a pyramid face, which is predominantly a Si(111) plane to be significantly rougher than a polished Si(111) surface. This roughness results in a nonuniform SiO x layer as determined by transmission electron microscopy of a poly -Si/SiO x contact. Our device measurements also show an overall more resistive and hence a thicker SiO x layer over the pyramidal surface as compared to a polished Si(111) surface, which we relate to increased surface roughness. Using electron-beam-induced current measurements of poly -Si/SiO x contacts, we further show that the SiO x layer near the pyramid valleys is preferentially more conducting and hence likely thinner than over pyramid tips, edges, and faces. Hence, both the microscopic pyramidal morphology and nanoscale roughness lead to a nonuniform SiO x layer, thus leading to poor poly -Si/SiO x contact passivation. Finally, we report >21% efficient and ≥80% fill-factor front/back poly -Si/SiO x solar cells on both single-side and double-side textured wafers without the use of transparent conductive oxide layers, and show that the poorer contact passivation on a textured surface is limited to boron-doped poly -Si/SiO x contacts.

Published

2019

31. Vertical Transport Study of III-V Type-II Superlattices

Author

Taghipour, Zahra

Subjects

Vertical transport, Carrier dynamics, Band Structure, Type-II superlattices, Density Functional Theory, Electron-Beam-Induced Current, Electronic Devices and Semiconductor Manufacturing, Semiconductor and Optical Materials

Abstract

Type-II strained layer superlattice (T2SL) semiconductors hold great promise for mid- and long-wavelength infrared photodetectors. While T2SL-based materials have advanced significantly in the last three decades, an outstanding challenge to improve the T2SLs is to understand the carrier transport and its limitations, in particular along the superlattice growth layers. In this dissertation, an overview of the current state-of-the-art InAs/GaSb T2SLs is presented. Fundamental semiconductor device equations and transport properties, including miniband conduction and the drift-diffusion parameters, are reviewed, and the fundamental limiting factors in carrier's transport are discussed. Furthermore, the standard method of electron-beam-induced current technique to measuring these parameters is described. The bulk of the manuscript will then explore the characterization of transport properties in an InAs/GaSb nBp photodetector through a variety of techniques. Through electron-beam-induced-current ($EBIC$) measurements, the minority carrier diffusion length along the growth direction has been measured. The $EBIC$ analysis combined with lifetime measurements using time-resolved microwave reflectance method is then used to calculate the minority electron mobility along the growth direction. Quantum efficiency modeling technique is used as an alternative approach to studying transport and quantify the complex relationships between the device performance and the underlying physics involved in it. Photocurrent-voltage measurement is also used to qualitatively investigate the drift characteristics, such as the field dependence of the drift mobility and drift velocity. Finally, the result of a recent study on the electronic band structure of a series of narrow-band superlattices is summarized.

Published

2018

32. Enhanced Hydrogen Evolution under Simulated Sunlight from Neutral Electrolytes on (ZnSe) 0.85 (CuIn 0.7 Ga 0.3 Se 2 ) 0.15 Photocathodes Prepared by a Bilayer Method.

Author

Kaneko H, Minegishi T, Nakabayashi M, Shibata N, and Domen K

Abstract

A (ZnSe) 0.85 (CuIn 0.7 Ga 0.3 Se 2 ) 0.15 photocathode with a bilayer structure was fabricated and found to exhibit a photocurrent almost twice that of a photocathode with a monolayer structure during hydrogen evolution from water. The cathodic photocurrent reached maximum values of 12 and 4.9 mA cm -2 at 0 and 0.6 V RHE in a neutral phosphate buffer under simulated sunlight, while the half-cell solar-to-hydrogen conversion efficiency was 3.0 % at 0.6 V RHE , with a maximum value of 3.6 % at 0.45 V RHE . Cross-sectional mapping of the electron-beam-induced current established that the increased photocurrent can be attributed to improved uniformity at the solid-liquid junction in the bilayer sample, which results in enhanced carrier collection., (© 2016 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

33. On the Origin of Electron-Beam-Induced-Current Contrast of Extended Defects in Silicon

Author

Kittler, M. and Seifert, W.

Subjects

Electron-beam-induced current, silicon, grain boundaries, precipitates, diffusion length, intrinsic and extrinsic EBIC contrast, extended crystal defects, stacking faults, Biology, dark and bright EBIC contrast, dislocations, semiconductor characterization

Abstract

The paper reviews the origin of bright and dark Electron-Beam-Induced Current (EBIC) contrast due to extended defects in silicon, inclusively a brief discussion of contrast modelling. Particular emphasis is put on the role of impurities demonstrated to determine contrast in many cases (extrinsic contrast origin). The understanding of the prevalent contrast type -dark contrast due to enhanced recombination at defects -is well supported by existing phenomenological contrast models which can, therefore, be used as a basis for contrast interpretation. In the context of extrinsic vs. intrinsic contrast origin, the influence of defect dimensionality on contrast is addressed, indicating that grain boundaries of even low recombination activity might produce detectable contrast, in contradiction to dislocations and point-like defects. It is shown that transition-metal precipitates are very efficient recombination sites and that their activity is in accordance with the existence of internal Schottky barriers.

Published

1992

34. Enhanced Carrier Collection from CdS Passivated Grains in Solution-Processed Cu2ZnSn(S,Se)4 Solar Cells.

Author

Werner M, Keller D, Haass SG, Gretener C, Bissig B, Fuchs P, La Mattina F, Erni R, Romanyuk YE, and Tiwari AN

Abstract

Solution processing of Cu2ZnSn(S,Se)4 (CZTSSe)-kesterite solar cells is attractive because of easy manufacturing using readily available metal salts. The solution-processed CZTSSe absorbers, however, often suffer from poor morphology with a bilayer structure, exhibiting a dense top crust and a porous bottom layer, albeit yielding efficiencies of over 10%. To understand whether the cell performance is limited by this porous layer, a systematic compositional study using (scanning) transmission electron microscopy ((S)TEM) and energy-dispersive X-ray spectroscopy of the dimethyl sulfoxide processed CZTSSe absorbers is presented. TEM investigation revealed a thin layer of CdS that is formed around the small CZTSSe grains in the porous bottom layer during the chemical bath deposition step. This CdS passivation is found to be beneficial for the cell performance as it increases the carrier collection and facilitates the electron transport. Electron-beam-induced current measurements reveal an enhanced carrier collection for this buried region as compared to reference cells with evaporated CdS.

Published

2015

35. Reprint of 'Imaging of diamond defect sites by electron-beam-induced current'

Author

Hideyuki Kodama, Shozo Kono, Atsuhito Sawabe, and Tokuyuki Teraji

Subjects

Materials science, Chemistry(all), 02 engineering and technology, engineering.material, Physics and Astronomy(all), 01 natural sciences, Signal, Optics, 0103 physical sciences, Materials Chemistry, Electron-beam-induced current, Electrical and Electronic Engineering, 010302 applied physics, Number density, business.industry, Electron beam-induced current, Mechanical Engineering, Schottky diode, Diamond, General Chemistry, 021001 nanoscience & nanotechnology, Electronic, Optical and Magnetic Materials, Schottky device, engineering, Defect, 0210 nano-technology, business

Abstract

The method of electron-beam-induced current (EBIC) was used to visualize the defect sites on a p-type (boron-doped) diamond (001) film. For this purpose, an Ag-Schottky layer (~ 2 mm × ~ 2 mm × ~ 50 nm) was deposited on the oxygen-terminated p-type diamond (001) film and used as a source of EBIC signal. The signal current of EBIC image appeared to be as large as ~ 1200 times that of the incident electron-beam current and the difference range in image intensity was also large (1–1200). The observed EBIC images showed many kinds of signatures that are possible ‘killer’ defects for Schottky devices. In order to identify ‘killer’ defects in the EBIC image, an array of Ag-dots (~ 40 × ~ 50 μm 2 ) was deposited on an oxygen-terminated p-type diamond (001) film and I–V characteristics were measured on 53 Ag-dots. The resulting I–V characteristics showed that 21 Ag-dots reside on ‘killer’ defects. Comparison between the EBIC image and the positions of Ag-dots residing on ‘killer’ defects showed that large dark dots in EBIC image correspond to the position of ‘killer’ defects. The number density of the large dark dots (i.e., ‘killer’ defects) was ~ 10 4 /cm 2 in the present sample. It is suggested that a high yield Schottky-junction device may be fabricated by avoiding these ‘killer’ defects by the use of EBIC.

36. Assessing the Device-performance Impacts of Structural Defects with TCAD Modeling

Author

Hannes Wagner, Pietro P. Altermatt, Tonio Buonassisi, David Berney Needleman, Massachusetts Institute of Technology. Department of Mechanical Engineering, Needleman, David Berney, Wagner, Hannes, and Buonassisi, Anthony

Subjects

First-principles calculation, Electronic design automation, 7. Clean energy, Solar cell performance, law.invention, Electric currents, Models, Photovoltaics, law, Architecture, Electron-beam-induced current, Numerical simulation studies, Electron beam-induced current, Heterojunction, Heterojunction with intrinsic thin layers, Heterojunctions, Optoelectronics, Defects, Grain boundary, ddc:620, Impurities, Inverse problems, Solar cells, Silicon, Materials science, chemistry.chemical_element, Solar power generation, Energy(all), Solar cell, Electronic engineering, Konferenzschrift, Common emitter, dislocation, Computer simulation, business.industry, silicon, modeling, Device architectures, photovoltaics, Dislocations (crystals), chemistry, grain boundary, Grain boundaries, Multicrystalline silicon (mc-Si), Calculations, business, ddc:600

Abstract

Advanced solar cell architectures like passivated emitter and rear (PERC) and heterojunction with intrinsic thin layer (HIT) are increasingly sensitive to bulk recombination. Present device models consider homogeneous bulk lifetime, which does not accurately reflect the effects of heterogeneously distributed defects. To determine the efficiency potential of multicrystalline silicon (mc-Si) in next-generation architectures, we present a higher-dimensional numerical simulation study of the impacts of structural defects on solar cell performance. We simulate these defects as an interfacial density of traps with a single mid-gap energy level using Shockley-Read-Hall (SRH) statistics. To account for enhanced recombination at the structural defects, we apply a linear scaling to the majority-carrier capture cross-section and scale the minority-carrier capture cross-section with the inverse of the line density of traps. At 300 K, our simulations of carrier occupation and recombination rate match literature electron-beam-induced current (EBIC) data and first-principles calculations of carrier capture, emission, and recombination for all the energy levels associated with dislocations decorated with metal impurities. We implement our model in Sentaurus Device, determining the losses across different device architectures for varying impurity decoration of grain boundaries., American Society for Engineering Education. National Defense Science and Engineering Graduate Fellowship, National Science Foundation (U.S.). Engineering Research Centers Program (Cooperative Agreement EEC-1041895)

37. CuInSe{sub}2/Cd(Zn)S solar cell modeling and analysis

Author

Rothwarf, A.

Published

1986

38. Electron-beam-induced current microcharacterization of fabrication defects in hydrogenated amorphous silicon solar cells

Author

Madan, A., Yacobi, B. G., and McMahon, T. J.

Published

1984

39. Theory of Electron Beam Induced Current and Cathodoluminescence Contrasts from Structural Defects of Semiconductor Crystals; Steady-State and Time-Resolved Problems

Author

Jakubowicz, A.

Subjects

electron-beam-induced current, time-resolved measurements, Life Sciences, cathodoluminescence, contrast, scanning electron microscopy, defects, dislocations, grain-boundaries

Abstract

Electron-beam-induced current and cathodoluminescence are powerful tools for revealing and characterizing point-like defects, dislocations, and grain boundaries in semiconductor crystals. This paper reviews the theoretical studies of electron-beam-induced current and cathodoluminescence contrasts from local structure defects of semiconductor crystals (the geometrical aspects of both contrasts, the assessment of the defect properties from the contrast, the evaluation of bulk parameters in the presence of defects, and time-resolved characterization of defects), including recent developments in this area.

Published

1987

40. Junction Electron-Beam-Induced Current Techniques for the Analysis of Photovoltaic Devices

Author

Matson, R. J.

Subjects

Photovoltaics, CuInSe2, Junction Electron-Beam-Induced Current, Electron-Beam-Induced Current, Charge-Collection Microscopy, Cross-Sectional Electron-Beam Induced Current, Biology

Abstract

A number of useful electron-beam-induced current (EBIC) techniques have evolved through the study of junction behavior in photovoltaic (PV) devices in cross section as a function of light and voltage bias, temperature, and electron beam scanning parameters. The necessary hardware modifications, the techniques themselves, and their applications are presented. In the case of PV devices, light and/or voltage biasing the entire device while electron probing it in cross section permits the observation of the distribution of the narrowing or extension of the space-charge region. Monitoring the junction behavior as a function of temperature has at least two applications. In situ heating of the device in the junction EBIC (JEBIC) mode permits the observation of the rate of movement of the junction further into the material as a function of time and temperature. Through low-temperature studies of cross sections, the change in the material's electrical properties have been recorded and correlated with device I-V and quantum efficiency measurements at these temperatures. Further, the JEBIC profile has been used to predict the quantum efficiency of the device. In the case of thin-film CdS/CuinSe2 devices, newly developed JEBIC techniques have been instrumental in determining the role of oxygen in improving device performance and stability.

Published

1987

41. Assessing the Device-performance Impacts of Structural Defects with TCAD Modeling

Author

Needleman, David Berney, Wagner, Hannes, Altermatt, Pietro P., and Buonassisi, Tonio

Subjects

Inverse problems, Solar cells, First-principles calculation, Silicon, Electronic design automation, Dewey Decimal Classification::600 | Technik::620 | Ingenieurwissenschaften und Maschinenbau, 7. Clean energy, Solar cell performance, Solar power generation, Electric currents, Models, Architecture, Electron-beam-induced current, Numerical simulation studies, Konferenzschrift, dislocation, Solar cell, modeling, Heterojunction with intrinsic thin layers, Dewey Decimal Classification::600 | Technik, Device architectures, Photovoltaics, grain boundary, Dislocations (crystals), Grain boundaries, Multicrystalline silicon (mc-Si), Heterojunctions, Defects, Calculations, FOS: Civil engineering, Impurities

Abstract

Advanced solar cell architectures like passivated emitter and rear (PERC) and heterojunction with intrinsic thin layer (HIT) are increasingly sensitive to bulk recombination. Present device models consider homogeneous bulk lifetime, which does not accurately reflect the effects of heterogeneously distributed defects. To determine the efficiency potential of multicrystalline silicon (mc-Si) in next-generation architectures, we present a higher-dimensional numerical simulation study of the impacts of structural defects on solar cell performance. We simulate these defects as an interfacial density of traps with a single mid-gap energy level using Shockley-Read-Hall (SRH) statistics. To account for enhanced recombination at the structural defects, we apply a linear scaling to the majority-carrier capture cross-section and scale the minority-carrier capture cross-section with the inverse of the line density of traps. At 300 K, our simulations of carrier occupation and recombination rate match literature electron-beam-induced current (EBIC) data and first-principles calculations of carrier capture, emission, and recombination for all the energy levels associated with dislocations decorated with metal impurities. We implement our model in Sentaurus Device, determining the losses across different device architectures for varying impurity decoration of grain boundaries.

42. Chemical Beam Epitaxy of 1.55-Mu-M Separate-Confinement Heterostructure Multiple-Quantum-Well Laser-Diodes

Author

Carlin, J. F. R., Sallese, Jean-Michel, Defays, M. P., Grunberg, P. J., Rudra, A. P., Bonard, J. M., Ilegems, M., and Ganiere, J. D.

Subjects

ELECTRON-BEAM-INDUCED CURRENT, Condensed Matter::Materials Science, GAINASP, INP, QUANTUM WELL, Physics::Optics, GROWTH, LASER, CBE, CHEMICAL BEAM EPITAXY, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, TRANSMISSION ELECTRON MICROSCOPY

Abstract

We report on the realization of InGaAs-lnGaAsP separate confinement heterostructure multiple quantum well lasers grown by chemical beam epitaxy. We discuss key growth parameters and characterization by secondary-ion mass spectroscopy, transmission electron microscopy, electron-beam-induced current, and x-ray diffraction. Threshold current densities as low as 450 A/cm(2) are obtained on lasers with five strained InGaAs quantum wells, along with internal quantum efficiencies of 90% and optical losses of 5 cm(-1).