Global ETD Search

1	Electrical Properties and Band Diagram of InSb-InAs Nanowire Type-III Heterojunctions Chen, Chao-Yang 21 November 2013 (has links) The electrical properties of nanowire-based n-InSb-n-InAs heterojunctions grown by chemical beam epitaxy were investigated both theoretically and experimentally. This heterostructure presented a type-III band alignment with the band bendings at 0.12 eV for InAs side and 0.16 − 0.21 eV in InSb. Analysis of the temperature dependent current voltage characteristics showed that the current through the heterojunction is caused mostly by generation-recombination processes in the InSb and at the heterointerface. Due to the partially overlapping valence band of InSb and the conduction band of InAs, the second process was fast and activationless. Theoretical analysis showed that, depending on the heterojunction parameters, the flux of non-equilibrium minority carriers may have a different direction, explaining the experimentally observed non-monotonic coordinate dependence of the electron beam induced current at the vicinity of heterointerface. Nanowire III-V semiconductor Nanotechnology Electron Beam Induced Current 0794 0611
2	Electrical Properties and Band Diagram of InSb-InAs Nanowire Type-III Heterojunctions Chen, Chao-Yang 21 November 2013 (has links) The electrical properties of nanowire-based n-InSb-n-InAs heterojunctions grown by chemical beam epitaxy were investigated both theoretically and experimentally. This heterostructure presented a type-III band alignment with the band bendings at 0.12 eV for InAs side and 0.16 − 0.21 eV in InSb. Analysis of the temperature dependent current voltage characteristics showed that the current through the heterojunction is caused mostly by generation-recombination processes in the InSb and at the heterointerface. Due to the partially overlapping valence band of InSb and the conduction band of InAs, the second process was fast and activationless. Theoretical analysis showed that, depending on the heterojunction parameters, the flux of non-equilibrium minority carriers may have a different direction, explaining the experimentally observed non-monotonic coordinate dependence of the electron beam induced current at the vicinity of heterointerface. Nanowire III-V semiconductor Nanotechnology Electron Beam Induced Current 0794 0611
3	Radiation Effects on Wide Band Gap Semiconductor Transport Properties Schwarz, Casey Minna 01 January 2012 (has links) In this research, the transport properties of ZnO were studied through the use of electron and neutron beam irradiation. Acceptor states are known to form deep in the bandgap of doped ZnO material. By subjecting doped ZnO materials to electron and neutron beams we are able to probe, identify and modify transport characteristics relating to these deep accepter states. The impact of irradiation and temperature on minority carrier diffusion length and lifetime were monitored through the use of the Electron Beam Induced Current (EBIC) method and Cathodoluminescence (CL) spectroscopy. The minority carrier diffusion length, L, was shown to increase as it was subjected to increasing temperature as well as continuous electron irradiation. The near-band-edge (NBE) intensity in CL measurements was found to decay as a function of temperature and electron irradiation due to an increase in carrier lifetime. Electron injection through application of a forward bias also resulted in a similar increase of minority carrier diffusion length. Thermal and electron irradiation dependences were used to determine activation energies for the irradiation induced effects. This helps to further our understanding of the electron injection mechanism as well as to identify possible defects responsible for the observed effects. Thermal activation energies likely represent carrier delocalization energy and are related to the increase of diffusion length due to the reduction in recombination efficiency. The effect of electron irradiation on the minority carrier diffusion length and lifetime can be attributed to the trapping of non-equilibrium electrons on neutral acceptor levels. The effect of neutron irradiation on CL intensity can be attributed to an increase in shallow donor concentration. Thermal activation energies resulting from an increase in L or decay of CL intensity monitored through EBIC and CL measurements for p-type Sb doped ZnO were found to be the range of Ea = 112 to 145 meV. P-type Sb doped ZnO nanowires under the influence of temperature and electron injection either through continuous beam impacting or through forward bias, displayed an increase in L and corresponding decay of CL intensity when observed by EBIC or CL measurements. These measurements led to activation energies for the effect ranging from Ea = 217 to 233 meV. These values indicate the possible involvement of a SbZn-2VZn acceptor complex. For N-type unintentionally doped ZnO, CL measurements under the influence of temperature and electron irradiation by continuous beam impacting led to a decrease in CL intensity which resulted in an electron irradiation activation energy of approximately Ea = 259 meV. This value came close to the defect energy level of the zinc interstitial. CL measurements of neutron irradiated ZnO nanostructures revealed that intensity is redistributed in favor of the NBE transition indicating an increase of shallow donor concentration. With annealing contributing to the improvement of crystallinity, a decrease can be seen in the CL intensity due to the increase in majority carrier lifetime. Low energy emission seen from CL spectra can be due to oxygen vacancies and as an indicator of radiation defects. Wide band gap semiconductors zno gan nanowires radiation neutron electron beam induced current cathodoluminescence Physics
4	Minority carrier diffusion length in proton-irradiated indium phosphide using electron-beam-induced current Hakimzadeh, Roshanak January 1993 (has links) No description available.
5	Carrier transport properties measurements in wide bandgap materials Cropper, André D. 06 June 2008 (has links) This dissertation examines the carrier transport properties, diffusion length, effective carrier lifetime, and resistivity in two wide bandgap materials, GaN and diamond. A combination of two methods was used to obtain these transport properties. The two were optical beam induced current (OBIC) and electron beam induced current (EBIC) time of flight transient measurements. These techniques consist of measuring the current response to the drift and diffusion of generated electron-hole pair carriers created by a short-duration pulse of radiation. Under OBIC, a short duration pulsed optical source, with an electron beam excitation pulse time much less than the transit time of the material, was used to generate excess carriers within the absorption depth of the material. The second method of excitation, EBIC involved the use of a modified SEM with a photoemission source (L-EBIC) and a high speed pulsed thermionic electron source (T-EBIC) to generate an electron beam. This electron beam was used to create a large number of electron-hole pairs at various penetration depths within the materials. Measurements on GaN found the diffusion length was 7.84 µm with the L-EBIC and 7.78 µm with the T-EBIC. After annealing at 900°C for 30 min. the GaN diffusion length increased to 9.89 µm (L-EBIC). The dark resistivity was 1.79 x 10¹⁰Ω-cm, and the carrier lifetimes were 1.7 µs with L-EBIC and 3.36 & 3.9 ns with OBIC. The author believed that the L-EBIC result was a good representation of the carrier lifetime within the material, while the shorter OBIC results were due to the combine high surface and interface recombination processes. The diamond dark resistivity was found to be 6.14 x 10¹¹Ω-cm and the diffusion lengths were 94.1 µm and 97 µm from the L-EBIC and T-EBIC respectively. All measurements were within 10 % spread. The real value of this contribution lies in determining the diffusion lengths in GaN and diamond by the EBIC techniques, measuring the effective surface\interface and thin film carrier lifetime of GaN utilizing a combination of OBIC and L-EBIC techniques, and evaluating the dark resistivity in GaN and diamond materials. These measurements can lead to a better understanding and exploitation of the electrophysical behavior of these materials. / Ph. D. carrier lifetime diffusion length electron beam induced current LD5655.V856 1995.C767
6	Microstructural investigation of defects in epitaxial GaAs grown on mismatched Ge and SiGe/Si substrates Boeckl, John J. 13 July 2005 (has links) No description available. molecular beam epitaxy MBE metal organic chemical vapor deposition MOCVD electron beam induced current EBIC defects transmission electron microscopy TEM
7	N and p-type doping of GaN nanowires : from growth to electrical properties / Nanofils de GaN dopés de type n et de type p : de la croissance aux propriétés électriques Fang, Zhihua 15 March 2017 (has links) Les nanostructures à base de nitrures d’éléments III suscitent un intérêt croissant, en raison de leurs propriétés singulières et de leurs applications technologiques potentielles, dans les diodes électroluminescentes (LED) notamment. La maîtrise et le contrôle du dopage de ces nanostructures est un enjeu crucial, mais difficile. A ce sujet, cette thèse apporte une contribution nouvelle, en explorant le processus de dopage de type n et p des nanofils (NFs) de GaN crus par épitaxie par jets moléculaires (EJM). En particulier, les propriétés électriques de ces structures ont été caractérisées par une approche multi-technique, à l’échelle du NF unique.Tout d'abord, les propriétés structurales et électriques d'une série de NFs de GaN dopés au Si (type n) ont été étudiées. Des mesures de spectroscopie de rayons X à haute résolution sur des NFs individuels ont mis en évidence une incorporation de Si plus élevée dans les NFs que dans les couches minces épitaxiées, ainsi qu’une migration du Si à la surface du NF pour le fil ayant le niveau de dopage le plus élevé. Des mesures de transport sur des NFs uniques (quatre contacts avec une température allant de 300 K jusqu’à 5 K) ont démontré un contrôle du dopage, avec une résistivité allant de 10^2 à 10^-3 Ω.cm et une concentration de porteurs comprise entre 10^17 et 10^20 cm-3. Des mesures réalisées sur des transistors à effet de champ à NFs uniques non intentionnellement dopés ont démontré qu’ils sont de type n avec une mobilité de porteurs élevée.Parallèlement à cela, les conditions de croissance de NFs de GaN dopés au Mg (p-type) et de jonctions p-n ont été déterminées afin d’obtenir une incorporation significative en Mg. Les propriétés électriques de jonctions p-n axiale à base de NFs de GaN posées sur un substrat de SiO2 et contactés avec de l’oxyde d’indium-étain (ITO) ont été étudiées en utilisant la technique du courant induit par faisceau électronique (EBIC). L’analyse EBIC a permis de localiser la jonction p-n le long du fil et de clairement montrer son bon fonctionnement en polarisation directe ou inverse. L'analyse EBIC a démontré que le GaN de type p est hautement résistif, confirmant ainsi les difficultés à réaliser des mesures de transport sur ce matériau.Cette étude originale a permis de décrire les propriétés électriques et de dopage de ces NFs de GaN à une échelle nanoscopique, facilitant ainsi la fabrication des futurs dispositifs incorporant des nanostructures à base de GaN. / III-nitride nanostructures have been attracting increasing attention due to their peculiar properties and potential device applications as lighting LEDs. The control and evaluation of the doping in the nanostructures is a crucial, yet a challenging issue. This thesis advances the field by exploring the n and p type doping process of GaN nanowires (NWs) grown by molecular beam epitaxy (MBE). In particular, their electrical properties have been revealed through a multi-technique approach at the single NW level.Firstly, the structural and electrical properties of a series of Si-doped (n-type) GaN NWs have been studied. High resolution energy dispersive X-ray spectroscopy measurements on single NWs have illustrated the achievement of a higher Si incorporation in NWs than in epilayers, and Si segregation at the edge of the NW with the highest doping. Furthermore, direct transport measurements (four probes measurements from 300 K down to 5 K) on single NWs have shown a controlled doping with resistivity from 10^2 to 10^-3 Ω.cm, and a carrier concentration from 10^17 to 10^20 cm-3. Field effect transistor measurements have evidenced the n-type nature and a high electron mobility of the non-intentionally doped NWs.Secondly, the growth conditions of Mg-doped (p-type) and axial GaN p-n junction NWs have been determined to achieve significant Mg incorporation. Furthermore, the electrical properties of the axial GaN p-n junction NWs, dispersed on SiO2 and contacted by ITO, have been studied using electron beam induced current (EBIC) technique. EBIC technique revealed the location of the p-n junction and clearly demonstrated its operation under reverse and forward polarization. Moreover, EBIC showed highly resistive p-GaN in accordance with the difficulties to perform direct transport measurements on p-GaN NWs.This original study provides a nanoscale description of the electrical and doping properties of the GaN NWs, facilitating the fabrication of the future GaN nanostructures based devices. Épitaxie par jets moléculaires GaN Nanofils Dopage de type n et type p Jonction p-N axiale Molecular beam epitaxy GaN Nanowires N and p-Type doping Axial p-N junction Electron beam induced current 530
8	Développement et application de la technique analytique de courant induit par faisceau d’électrons pour la caractérisation des dispositifs à base de nanofils de nitrure de gallium et de silicium / Development and application of electron beam induced current analytical technique for characterization of gallium nitride and silicon nanowire-based devices Neplokh, Vladimir 23 November 2016 (has links) In this thesis I present a study of nanowires, and, in particular, I apply EBIC microscopy for investigation of their electro-optical properties. First, I describe details of the EBIC analytical technique together with a brief historical overview of the electron microscopy, the physical principles of the EBIC, its space resolution, parameters defining the signal amplitude, and the information we can acquire concerning defects, electric fields, etc. Then I focus on the characterization of LEDs based on GaN nanowires, which were analyzed in a cross-section and in a top view configurations. The EBIC measurements were correlated with micro-electroluminescence mapping. Further, I address the fabrication and measurement of nanowire-based InGaN/GaN LEDs detached from their original substrate. I present the EBIC measurements of individual nanowires either cut from their substrate and contacted in a planar geometry or kept standing on supphire substrate and cleaved to reveal the horizontal cross-section.The next part of this thesis is dedicated to an EBIC study of irregular Si nanowire array-based solar cells, and then of the regular nanowire array devices. The current generation was analyzed on a submicrometer scale. Finally, I discuss the fabrication and EBIC measurements of GaN nanowires grown on Si substrate. In particular, I show that the p-n junction was induced in the Si substrate by Al atom diffusion during the nanowire growth. / Dans cette thèse je me propose d’étudier des nano-fils, et en particulier d’utiliser la technique EBIC pour explorer leurs propriétés électro-optiques. Je décris d’abord les détails de la technique d’analyse EBIC avec un bref retour historique sur la microscopie électronique, le principe physique de l’EBIC, sa résolution spatiale, les paramètres conditionnant l’amplitude du signal, et les informations que l’on peut en tirer sur le matériau en termes de défauts, champ électrique, etc. Je m’intéresse ensuite à la caractérisation de LEDs à nano-fils à base de GaN, qui ont été observés par EBIC, soit en coupe soit en vue plane (depuis le haut des fils). Les mesures EBIC sont comparées à celles de micro-électroluminescence. Plus loin j’adresse la fabrication et la mesure de nano-fils à base de GaN séparés de leur substrat d’origine. Je présente les mesures EBIC de nano-fils uniques entiers, puis de nano-fils en coupe horizontale.La partie suivante de la thèse traite d’étude EBIC des cellules solaires à base de nano-fils Si ayant d’abord une géométrie aléatoire, puis une géométrie régulière. La génération de courant dans ces cellules solaires est analysée à l’échelle submicronique. A la fin du manuscrit je discute la fabrication et les mesures EBIC de fils GaN épitaxiés sur Si. Je montre en particulier qu’une jonction p-n est enduite dans le substrat Si par la diffusion d’Al lors de la croissance de nanofils. Nanofils (NWs) Diodes électroluminescentes (LED) Cellule solaire Nitrure de gallium (GaN) Silicium (Si) Nanowires (NWs) Electron beam induced current (EBIC) Light emitting diode (LED) Solar cell Gallium nitride (GaN) Silicium (Si)

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