Synthesis, characterization and electrochemical hydrogen storage properties of mechanicalyl alloyed Ti-Mg-Ni : application as negative electrode for Ni-MH battery / Elaboration par mécanosynthèse et caractérisation des propriétés de stockage électrochimique d'hydrogène d'alliages Ti-Mg-Ni : application en vue de leur utilisation comme électrode négative d'accumulateur Ni-MH.

Zhang, Zhao

07 April 2017

Le stockage de l'hydrogène est l'un des plus grands problèmes techniques qui restreignent l'application pratique de l'hydrogène. Les hydrures métalliques sont considérés comme la solution principale à ce problème puisqu'ils peuvent absorber et désorber de façon réversible une grande quantité d'hydrogène sous une température et une pression modérées. Par ailleurs, les hydrures métalliques utilisés comme électrodes négatives dans les accumulateurs Nickel-Métal Hydrure (Ni-MH) sont également les composants clés des performances de ces derniers.Dans cette thèse, les alliages métalliques TiMgNix, MgTi1-xNix et TiMg1-xNix ont été synthétisés par broyage mécanique à partir de poudres élémentaires. La microstructure et les transformations de phase des échantillons préparés ont été caractérisées par DRX, MEB et MET (avec microanalyse EDS).Les propriétés d'hydrogénation ont été mesurées par réaction d'hydrogène solide-gaz et par des essais électrochimiques. Un diagramme de composition-capacité 3D a été établi sur la base du diagramme de phase ternaire Ti-Mg-Ni. Un procédé de broyage en deux étapes a été mis en œuvre pour améliorer les performances électrochimiques des alliages Ti-Mg-Ni.De plus, les alliages TiNi1-xCux ont été synthétisés par broyage mécanique et ensuite recuits. L 'influence de la substitution du nickel par le cuivre sur la structure et les propriétés électrochimiques est étudiée en utilisant une double approche: expérimentale et par simulation.Les résultats obtenus par la théorie de la fonctionnelle de la densité (DFT) en utilisant le programme CASTEP montrent que l'enthalpie de formation et l'énergie d'adsorption de l¿hydrogène de la phase pseudo-binaire Ti(Ni, Cu) sont en bon accord avec les résultats expérimentaux. / The storage of hydrogen is one of the biggest technical problem that restrict the practical application of hydrogen. Metal hydrides are mainly regarded as the solution facing to this issue since it can reversibly absorb and desorb big amount of hydrogen under moderate temperature and pressure. Meanwhile, metal hydrides used as the negative electrodes of Ni-MH batteries are also the key components to the battery performance.In this thesis, the metallic composite TiMgNix, MgTi1-xNix and TiMg1-xNix were synthesized by mechanical alloying from elemental powder. The microstructure and phase transformation of prepared samples were characterized by XRD, SEM, TEM (EDS support). The hydrogenation properties were measured by hydrogen solid-gas reaction and electrochemical tests. Based on the Ti-Mg-Ni ternary phase diagram, a 3D composition-capacity diagram have been established. Two-step mill process was proposed for meliorating the electrochemical performance of Ti-Mg-Ni alloys.Additionally, TiNi1-xCux alloys had been synthesized by mechanical alloying and subsequent annealing and studied using experimental and computational approaches. The influence of Cu substitution for Ni on the phase structure and electrochemical properties are investigated. The first principle calculation was carried out to study the formation enthalpy and hydrogen adsorption energy of pseudo-binary Ti(Ni, Cu) phase. The computational results are in good agreement with experimental results.

Accumulateurs Ni-MH

Ti-Mg-Ni

Hydrures métalliques

Mécanosynthèse

Stockage d’hydrogène électrochimique

DFT

Ti-Mg-Ni

Metal hydrides

Electrochemical hydrogen storage

DFT

Ni-MH batteries

Mechanical alloying

620.1

Influência da substituição do cobalto por estanho e cobre na microestrutura e propriedades elétricas em ligas a base de LaMgAlMnCoNi / Influence of replacement of cobalt by tin and copper on microstructure and electrical properties of LaMgAlMnCoNi based alloys

Julio César Serafim Casini

03 July 2015

Neste trabalho, avaliou-se inicialmente o efeito da substituição de elementos em ligas à base de LaMgAlMnCoNi do tipo AB5 com adição de estanho (Sn) e cobre (Cu) em substituição ao cobalto (Co), para utilização em ligas absorvedoras de hidrogênio e em eletrodos negativos de baterias de Ni-HM. Avaliou-se a influência desta substituição na microestrutura do material. Notou-se que o aumento da concentração de estanho promove a formação da fase LaNiSn nas ligas, bem como a diminuição das duas fases principais: LaNi5 e (La,Mg)Ni3. Adicionalmente, utilizou-se o refinamento de Rietveld para quantificar as fases em cada composição. Posteriormente, propôs-se um estudo da absorção de hidrogênio. Notou-se que a liga com cobalto apresentou a melhor capacidade de absorção de hidrogênio. Ademais, verificou-se o comportamento destas ligas na capacidade de descarga, estabilidade cíclica e na alta taxa de descarga de baterias de Ni-HM. A maior capacidade de descarga medida foi para a liga de cobalto, atingindo 337,1 mAh/g. Notou-se, posteriormente uma melhora na estabilidade cíclica das baterias com o aumento do teor de cobre. Além disso, observou-se que a alta taxa de descarga apresenta melhores valores com a adição de cobre na composição. Por fim, avaliou-se o efeito da susceptibilidade a corrosão. Notou-se que o estanho promove um aumento na resistência à corrosão das ligas em eletrólito alcalino. / In this work, it has firstly been evaluated the effect of tin (Sn) and copper (Cu) substituting cobalt (Co) in LaMgAlMnCoNi AB5-type alloys for use in hydrogen storage materials and negative electrodes of Ni-MH batteries. The influence of this substitution on the microstructure of these materials has been evaluated. It could be noted that increasing the tin concentration promotes the formation of LaNiSn phase and decrease of two main phases of these alloys: LaNi5 and (La,Mg)Ni3. Additionally, the Rietveld refinement has been evaluated to quantify phases in each composition. Subsequently, it has been proposed a study of the hydrogen absorption in these alloys. It could be observed that the cobalt alloy showed the best hydrogen absorption capacity. Moreover, the behavior of these alloys has been investigated in the discharge capacity, cyclic stability and high rate dischargeability of Ni-MH batteries. The highest discharge capacity has been measured for cobalt alloy, reaching 337.1 mAh/g. It has been noted, further improvement in the cyclic stability batteries with increasing copper content in the alloys. Furthermore, it has been observed that the high rate dischargeability has better values with the addition of copper in the composition. Finally, it has been evaluated the effect of susceptibility to corrosion. It has been noted that tin promotes an increase in corrosion resistance of the alloys in an alkaline electrolyte.

baterias Ni-MH

ligas de estocagem de hidrogênio

ligas de LaNi5

terras raras

hydrogen storage alloys

LaNi5 based alloys

Ni-MH batteries

rare earths

Hydrogen absorption/desorption properties of the Sc(AlxNi1-x)2 system

Ångström, Jonas

January 2011

Sc(AlxNi1-x)2 is a pseudobinary C14 Laves phase and a potential interstitial hydrogen storage material or anode in a Ni-MH battery. A previous study showed that Sc1Al1Ni1 can store hydrogen reversibly; both interstitially and trough decomposition into ScH2 and AlNi. It is also known that the exact composition is very important for the hydrogen storage properties of pseudobinary Laves phases. This thesis work is aimed at synthesising Sc(AlxNi1-x)2 and study the effect of the Ni/Al ratio on the hydrogen absorption/desorption process as well as the interstitial storage capacity. Compositions with high nickel content had the highest capacity (at least 0.67wt% for ScAl0.66Ni1.34) and ones with high aluminium content had the lowest total storage capacity (0wt% for ScAl1.28Ni0.62). The former composition was also shown to absorb and desorb hydrogen during multiple cycles. Desorption of interstitial hydrogen from ScAl0.66Ni1.34 requires 4.6kJ/mol in activation energy.

hydrogen storage

Laves phases

Ni-MH batteries

intermetallic compounds

alloy

alloys

Nickel

Hydrogen

Scandium

Sc

Ni

Aluminium

Aluminum

Al

Nickel metal hydride batteries

Laves phase

vätelagrning

Lavesfaser

Ni-MH batteri

intermetalliska föreningar

legering

legeringar

nickel

väte

skandium

aluminium

Lavesfas