Active dopant profiling and Ohmic contacts behavior in degenerate n-type implanted silicon carbide

This Letter reports on the active dopant profiling and Ohmic contact behavior in degenerate P-implanted silicon carbide (4H-SiC) layers. Hall measurements showed a nearly temperature-independent electron density, corresponding to an electrical activation of about 80% of the total implanted dose. Using the Hall result as calibration, the depth resolved active P-profile was extracted by scanning capacitance microscopy (SCM). Such information on the active P-profile permitted to elucidate the current injection mechanism at the interface of annealed Ni Ohmic contacts with the degenerate n-type 4H-SiC layer. Modeling the temperature dependence of the specific contact resistance with the thermionic field emission mechanism allowed extracting a doping concentration of 8.5 × 1019 cm−3 below the metal/4H-SiC interface, in excellent agreement with the value independently obtained by the SCM depth profiling. The demonstrated active dopant profiling methodology can have important implications in the 4H-SiC device technology

Coupled experiment/simulation approach for the design of radiation-hardened rare-earth doped optical fibers and amplifiers

We developed an approach to design radiation-hardened rare earth -doped fibers and amplifiers. This methodology combines testing experiments on these devices with particle swarm optimization (PSO) calculations. The composition of Er/Yb-doped phosphosilicate fibers was improved by introducing Cerium inside their cores. Such composition strongly reduces the amplifier radiation sensitivity, limiting its degradation: we observed a gain decreasing from 19 dB to 18 dB after 50 krad whereas previous studies reported higher degradations up to 0°dB at such doses. PSO calculations, taking only into account the radiation effects on the absorption efficiency around the pump and emission wavelengths, correctly reproduce the general trends of experimental results. This calculation tool has been used to study the influence of the amplifier design on its radiation response. The fiber length used to ensure the optimal amplification before irradiation may be rather defined and adjusted to optimize the amplifier performance over the whole space mission profile rather than before integration in the harsh environments. Both forward and backward pumping schemes lead to the same kind of degradation with our active fibers. By using this promising coupled approach, radiation-hardened amplifiers nearly insensitive to radiations may be designed in the future

Radiation hardening of Rare-Earth doped fiber amplifiers

We investigated the radiation hardening of optical fiber amplifiers operating in space environments. Through a real-time analysis in active configuration, we evaluated the role of Ce in the improvement of the amplifier performance against ionizing radiations. Ce-codoping is an efficient hardening solution, acting both in the limitation of defects in the host glass matrix of RE-doped optical fibers and in the stabilization of lasing properties of the Er3+-ions. On the one hand, in the nearinfrared region, radiation induced attenuation measurements show the absence of radiation induced P-related defect species in host glass matrix of the Ce-codoped active fibers; on the other hand, in the Ce-free fiber, the higher lifetime variation shows stronger local modifications around the Er3+-ions with the absence of Ce

Design of Radiation-Hardened Rare-Earth Doped Amplifiers Through a Coupled Experiment/Simulation Approach

We present an approach coupling a limited experimental number of tests with numerical simulations regarding the design of radiation-hardened (RH) rare earth (RE)-doped fiber amplifiers. Radiation tests are done on RE-doped fiber samples in order to measure and assess the values of the principal input parameters requested by the simulation tool based on particle swarm optimization (PSO) approach. The proposed simulation procedure is validated by comparing the calculation results with the measured degradations of two amplifiers made with standard and RH RE-doped optical fibers, respectively. After validation, the numerical code is used to theoretically investigate the influence of some amplifier design parameters on its sensitivity to radiations. Simulations show that the RE-doped fiber length used in the amplifier needs to be adjusted to optimize the amplifier performance over the whole space mission profile rather than to obtain the maximal amplification efficiency before its integration in the harsh environment. By combining this coupled approach with the newly-developed RH RE-doped fibers, fiber-based amplifiers nearly insensitive to space environment may be designed in the future

Durcissement aux radiations d'amplificateurs à fibres optiques dopés aux terres rares

Cette thèse est consacrée à l'étude de la réponse aux radiations d'amplificateurs à fibre optiques dopées Er 3+ et Yb3+. Ces dispositifs fonctionnant à 1,5 µm ont été conçus pour des applications spatiales et l'évaluation de leurs performances revêt d’une importance capitale dans un tel environnement hostile. Deux traitements, le chargement en H2 et le co-dopage au Ce du cœur de la fibre, ont été étudiés comme solutions de durcissement aux radiations. Une étude spectroscopique a permis d’approfondir la connaissance des mécanismes physiques de base responsables de la dégradation de ces composants et par conséquent de proposer des solutions de durcissement. La thèse est organisée en trois parties. La Partie I présente une description générale des fibres dopées aux ions de Terres Rares (TR), avec l'introduction des concepts de base de la physique de tels éléments et leur interaction avec la matrice hôte (verre phosphosilicate). L'état de l'art concernant les effets des rayonnements sur les fibres dopées aux TR est également présenté. La Partie II décrit les échantillons et les techniques expérimentales utilisées. La Partie III décrit les principaux résultats dont les tests, en configuration active, démontrent que le co-dopage au Ce ainsi que le chargement en H2 ont un rôle-clé dans la limitation des pertes induites par rayonnement. L'analyse spectroscopique de la matrice vitreuse (Raman) et des ions TR (par mesures de luminescence stationnaire et résolue en temps) mettent en exergue un fort effet de durcissement, conduisant à une préservation de l'efficacité du système physique en opérationThis thesis is devoted to the study of the radiation response of optical amplifiers based on Er/Yb doped fibers. These devices operating at 1.5 µm are conceived for space applications and contextually the evaluation of their performance in such harsh environment becomes of crucial importance. Two treatments, the H2-loading and the Ce-doping of the fiber core, are investigated as radiation hardening solutions. A spectroscopic study has been associated, in order to improve the knowledge of the physical mechanisms responsible for the signal degradation and the action of the hardening solutions. The thesis is organized in three parts. Part I deals with a general description of the Rare-Earth (RE)-doped fibers, with the introduction of some basic concepts of the RE-ion physics and their interaction with the host matrix material (phosphosilicate glass). The state-of-art of the radiation effects on the optical fibers, particularly the RE- doped fibers, is also overviewed. Part II describes the samples (fiber fabrication, geometry and chemical compositions), and the used experimental techniques, including a short discussion on the related theoretical background. Part III describes the main results; firstly, the active tests, performed on the RE-doped fiber as part of an optical amplifier, demonstrate that the Ce-codoping and H2-load have a key-role in the limitation of the radiation induced losses. Then, the spectroscopic analysis of the phosphosilicate glass (Raman study) and of the RE-ions (stationary and time-resolved luminescence) show a stabilization effect due to the two treatments, leading to a preservation of the high efficiency of the physical system under stud

Full non-destructive characterization of doped optical fibre preforms

We present a non-destructive optical technique for a full characterization of rare-earth-doped optical preforms. Specifically, a combined profiling of refractive-index and active-dopant was carried out in the same region of opticalpreforms by performing ray deflection and photoluminescence projection measurements, respectively. In this way, the optical core, delineated by the refractive index profile, was used to define the actual active dopant distributions within the core. Using the same experimental set-up, it was also possible to uniquely provide the maximum value of active-ion concentration reached inside the core. The study was carried out on an optical fiber preform sample doped with Yb3+ ions in high concentration. Comparison with independent measurements, such as those performed by a commercial refractiveindex profiler and microstructural secondary-ion mass spectrometry analysis, confirms the accuracy of the proposed technique in the optical features evaluation

Instrumentation for simultaneous non-destructive profiling of refractive index and rare-earth-ion distributions in optical fiber preforms

We present a non-destructive technique for a combined evaluation of refractive index and active-dopant distribution in the same position along a rare-earth-doped optical fiber preform. The method relies on luminescence measurements, analyzed through an optical tomography technique, to define the active dopant distribution and ray-deflection measurements to calculate the refractive index profile. The concurrent evaluation of both the preform refractive index and the active dopant profiles allows for an accurate establishment of the dopant distribution within the optical core region. This combined information is important for the optimization and development of a range of advanced fibers, used, for example, in a high-power fiber lasers and modern spatial-division-multiplexing optical communication systems. In addition, the non-destructive nature allows the technique to be used to identify the most appropriate preform segment, thus increasing fiber yield and reducing development cycles. We demonstrate the technique on an Yb3+-doped aluminosilicate fiber preform and compare it with independent refractive index and active-dopant measurements. This technique will be useful for quality evaluation and optimization of optical fiber preforms and lends itself to advanced instrumentation

Dataset for Instrumentation for Simultaneous Non-Destructive Profiling of Refractive Index and Rare-Earth-Ion Distributions in Optical Fiber Preforms

Assigned DOI: https://doi.org/10.5258/SOTON/D0701 Dataset supports: Vivona, M. and Zervas, M. N. Instrumentation for Simultaneous Non-Destructive Profiling of Refractive Index and Rare-Earth-Ion Distributions in Optical Fiber Preforms. Publication in the journal Instruments.</span

Non-destructive microscopic characterization of optical fiber preforms

We present a non-destructive optical technique, based on luminescence spectroscopy measurements and optical computerized tomography, to measure Yb3+ single ion and Yb3+-Yb3+ cluster distributions inside the core of optical fiber preforms. The core refractive index distribution was also measured and used to define the actual active dopant distributions within the core