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1	Determination of Phase Fraction, Lattice Parameters and Crystallite Size in Mechanically Alloyed Fe-Ni Powders Simhadri, Dileep 19 December 2003 (has links) This is the first systematic report on the synthesis of mechanically alloyed Fe-Ni powders ball milled at liquid nitrogen temperature. Pure Fe-Ni samples were ball milled in a SPEX 8000 shaker mill at liquid nitrogen temperature. X-ray diffractometry was used to determine the phase fractions of the bcc and fcc phases in the alloys and to determine the lattice parameters and crystallite size. The main objective of this project is to study how the milling at low temperatures affects the region of two phase co-existence, phase structure and crystallite size. It was found that the composition ranges of the bcc and fcc single phase regions were extended well beyond the equilibrium ranges. The results obtained for the samples ball milled at liquid nitrogen temperature were compared to the previous samples ball milled at room temperature. XRD Mechanical alloying Fe-Ni
2	Equilibres de phases et microstructures d'alliages CU-FE-NI riches en FE / Design of a new iron-nickel-copper binder for diamond tools Crozet, Coraline 28 January 2011 (has links) Ce travail a pour but l’acquisition de connaissances fondamentales dans les équilibres de phases et les transformations de phases des alliages ternaires contenant du fer, du nickel et du cuivre.Cette étude est composée de trois parties : la première est consacrée aux équilibres de phase entre600°C et 1000°C dans le coin riche en fer du système ternaire Cu-Fe-Ni, la seconde concerne l’analyse des transformations de phases dans des alliages modèles suivant deux vitesses de refroidissement et la troisième étudie les alliages industriels.Cette approche expérimentale est appuyée par des calculs thermodynamiques. Une comparaison est effectuée avec les données issues de la littérature. Les sections isothermes à 600°C, 800°C et1000°C ont été reconfirmées. Les domaines triphasés αFe/γFe/γCu ont été déterminés à 600°C et800°C et semblent décalés vers de plus fortes teneurs en Ni. La lacune de miscibilité est moins étendue que celle calculée et ce particulièrement du côté du binaire Cu-Ni.Les transformations de phase γ→α apparaissant lors du refroidissement d’alliages Fe-xCu-10Ni et Fe-10Cu-xNi (0<x<15 % en masse) ont été étudiées. Elles sont observées dans tous les alliages refroidis lentement par dilatométrie sauf dans l’alliage binaire Fe-Cu. Les températures de transformation sont systématiquement inférieures aux températures d’équilibre et cet écart augmente lorsque les teneurs en Ni et Cu augmentent. La formation de la ferrite bainitique est favorisée par l’addition de Cu dans les alliages trempés Fe-xCu-10Ni et par l’addition de Ni dans les alliages Fe-10Cu-xNi tandis que la ferrite massive se forme préférentiellement lors du refroidissement lent. Une diminution des températures de transformation se produit lorsque la taille de grains est affinée et est reliée au processus d’accommodation plastique liée à la transformation.La composition et la vitesse de refroidissement jouent un rôle sur la dureté de ces alliages via la présence de Ni en solution solide ainsi que le nombre et la taille des précipités de Cu. / This work aims in getting fundamental knowledge of phase equilibria and microstructures of ternary alloys containing copper, nickel and iron. The thesis is composed of three parts: a first part is devoted to phase equilibria in the Fe-rich corner of the ternary Cu-Fe-Ni system between 600°C and 1000°C, a second part is devoted to the microstructures in these materials for model alloys, for two cooling rates and a third part is devoted to industrial alloys.Phase equilibria of the system are investigated in the range 600-1000°C using diffusion multiples in conjunction with selected equilibrated alloys. This experimental approach is supplemented by thermodynamic calculations. A comparison is drawn with data reported in the literature. The isothermal sections at 600°C, 800°C and 1000°C have been reconfirmed. The three-phase regions αFe/γFe/γCu are determined at 600°C and 800°C and appear shifted to a higher Ni content. The miscibility gap is narrower than the calculated, particularly on the Cu-Ni binary sides.Austenite/ferrite phase transformations occurring on cooling in Fe-xCu-10Ni and Fe-10Cu-xNi alloys,0<x<15 (mass%), have been studied. The influence of copper and nickel additions and of the cooling rate on the microstructure is discussed. Metastable transformations in slowly cooled alloys have been detected by dilatometry in all alloys except in the binary Fe-10Cu alloy: all the cooling transformation temperatures are systematically lower than the equilibrium temperature and the Ni and Cu addition decrease this transformation temperature. The formation of bainitic ferrite is favoured by copper additions in quenched Fe-xCu-10Ni alloys and by Ni addition in Fe-10Cu-xNi alloys while massive ferrite form preferentially during slow cooling. A decrease of the transformation temperatures is recorded when the alloys have a finer grain size likely related to plastic accommodation processes.The composition and cooling rate influence the hardness of the alloys mostly dependant on the amount of Ni in solid solution and on the rate and size of Cu precipitates. Thermodynamique Transformation de phase Alliages Fe-Ni-Cu Thermodynamic Phase transformations Fe-Ni-Cu alloys
3	Textural and compositional analysis of Fe-Ni metallic spherules in impact melt from Monturaqui Crater, Chile Cukierski, Daniel Owen 01 May 2013 (has links) The scope of this project is to collect and interpret geochemical and textural data of iron-nickel (Fe-Ni) spherules in impact melt from the Monturaqui Impact Crater, Chile to investigate the processes accounting for the compositional variations. Major element data are collected on in situ spherules in one thin section and three epoxy rounds by electron microprobe and major element, trace element, and platinum group element data are collected by inductively coupled plasma mass spectrometry on spherules separated from impact glass by electric pulse disintegration (Figure 1C-1D). Major element, trace element, and platinum group element data are collected on a piece of iron shale from Monturaqui by using both instruments. Though the variation of the major elements within Fe-Ni spherules has been well documented, the variations of trace elements have not been rigorously investigated. This study aims to document the variations seen in major elements, trace elements, and platinum group elements in the Fe-Ni spherules relative to the iron impactor. The impactor was originally classified as a group I coarse octahedrite based on the Ni content of Fe-Ni spherules in the impact melt as well as the morphology of the iron shale (Bunch and Cassidy, 1972; Buchwald, 1975). For this study, major element, trace element, and platinum group element data were collected on a piece of iron shale from Monturaqui to provide a more robust classification. Fe-Ni spherules Hexahedrite Monturaqui Ni-rich rims Geology
4	Aplica??o de nanopart?culas bimet?licas de Ni-Fe estabilizadas com s?lica e quitosana para remedia??o de ?gua contaminada com nimesulida Gon?alves, Andressa Aparecida 23 March 2016 (has links) Submitted by Guilherme Orsetti (guilherme.orsetti@ufvjm.edu.br) on 2016-07-14T19:37:31Z No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) andressa_ aparecida_goncalves.pdf: 2921232 bytes, checksum: 7bb7b4fc7e6bed0489470006df3aeb04 (MD5) / Approved for entry into archive by Rodrigo Martins Cruz (rodrigo.cruz@ufvjm.edu.br) on 2016-07-18T14:56:29Z (GMT) No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) andressa_ aparecida_goncalves.pdf: 2921232 bytes, checksum: 7bb7b4fc7e6bed0489470006df3aeb04 (MD5) / Made available in DSpace on 2016-07-18T14:56:29Z (GMT). No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) andressa_ aparecida_goncalves.pdf: 2921232 bytes, checksum: 7bb7b4fc7e6bed0489470006df3aeb04 (MD5) Previous issue date: 2016 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior (Capes) / Funda??o de Amparo ? Pesquisa do estado de Minas Gerais (FAPEMIG) / Nanopart?culas bimet?licas (bNPs) de Ni-Fe estabilizadas com s?lica (Ni-Fe/SIL) e quitosana (Ni-Fe/QUI) foram sintetizadas e caracterizadas para aplica??o em ?gua contaminada para remo??o da nimesulida (NMS). Para os ensaios em batelada em solu??es aquosas, fatores que afetam a remo??o NMS tais como a concentra??o inicial de NMS e a dosagem de Ni-Fe/SIL e Ni-Fe/QUI foram investigados sistematicamente. A remo??o completa da NMS foi obtida em 15 min de rea??o ao utilizar-se as bNPs 8%Ni-Fe/SIL, na velocidade 250 rpm, dose de 0,6g e concentra??o inicial de 50 mg L-1. J? a remo??o completa ao utilizar-se as bNPs 17%Ni- Fe/QUI foi obtida ap?s 17,5 min de rea??o de 40 mg L-1 de NMS com 0,8 g de 17%Ni- Fe/QUI e agita??o de 250 rpm. Como esperado para uma rea??o heterog?nea realizada em batelada, sob vigorosa agita??o, foi verificado que a taxa de remo??o aumentou com o aumento da concentra??o inicial da NMS e da dosagem de 8%Ni-Fe/SIL e 17%Ni-Fe/QUI. Foi realizado um estudo do efeito da velocidade de agita??o do sistema, verificando que este ? um fator que influencia diretamente na taxa de remo??o. O estudo de remo??o na presen?a e na aus?ncia de oxig?nio dissolvido revelou que a presen?a deste ?ltimo exerce uma pequena influ?ncia no processo de remo??o. Um estudo comparativo da remo??o utilizando a bNPs na presen?a e na aus?ncia dos agentes estabilizantes foi realizado nas mesmas propor??es, sendo verificado que os n?veis de remo??o foram superiores para o sistema em presen?a de estabilizantes. A an?lise do subproduto formado da NMS mostrou que este ? menos t?xico que o composto original. O presente trabalho demonstra que o processo de tratamento redutivo alternativo fazendo uso de nanopart?culas bimet?licas contendo Fe e Ni ? muito promissor para a elimina??o da NMS. / Disserta??o (Mestrado) ? Programa de P?s-Gradua??o em Qu?mica, Universidade Federal dos Vales do Jequitinhonha e Mucuri, 2016. / ABSTRACT Fe-Ni bimetallic nanoparticles stabilized with silica (Ni-Fe/SIL) and chitosan (Ni-Fe/CS) were synthesized and characterized for use in contaminated water for removal of nimesulide (NMS). For the test batch in aqueous solutions, factors affecting the removal of drugs such as the initial concentration of NMS and dosage of Ni-Fe/SIL and Ni-Fe/CS were investigated systematically. The complete removal of the NMS was obtained in 15 min of reaction using up the bNPS 8%Ni-Fe/SIL speed 250 rpm, initial concentration of 50 mg L- and 0.6g dose. Since complete removal when using bNPs 17%Ni-Fe/CS was obtained after 17.5 minutes of reaction 40 mg L-1 NMS with 0.8 g of 17%Ni-Fe/CS and stirring 250 rpm. As expected for a heterogeneous reaction carried out in batch, under vigorous stirring, it was found that the removal rate increased with the increase of the initial concentration of the drugs and dosage of Ni-Fe/SIL and Ni-Fe/CS. A study of the effect of system stirring speed was carried out by checking that this is a factor that directly influence the removal rate. The removal of the presence and in the absence of dissolved oxygen showed that the presence of the latter exerts a small influence on the removal process. A comparison of removal using the bNPs in the presence and in the absence of stabilizers was performed in the same proportions, and found that the removal rates were higher for the system in the presence of stabilizers. The analysis of the byproduct formed from the NMS showed that it is less toxic than the parent compound. The present work demonstrates that the reductive treatment process alternative making use of bimetallic nanoparticles containing Fe and Ni is very promising for the elimination of NMS. bNPs Fe-Ni Nimesulida Quitosana S?lica Nimesulide Silica Chitosan
5	Fusion sélective par laser - influence de l'atmosphère et réalisation d'alliage in situ / Selective laser melting - influence of atmosphere and realization of in-situ fonction alloy Zhang, Baicheng 04 April 2013 (has links) Au cours de la dernière décennie, le procédé de fabrication additive par fusion sélective d'un lit de poudre SLM a attiré une grande attention dans le domaine de l'industrie, car il permet de produire rapidement des pièces de formes complexes. Le but de ce travail est d'étendre les performances des procédés SLM en étudiant la possibilité d'élaborer des pièces en atmosphère raréfiée. Pour atteindre cet objectif, une approche théorique et expérimentale a été développée, avec la mise en place d'une machine de fusion sélective par laser capable de travailler dans le domaine de pression de 1 à 10-2 mbar.Le travail sous vide permet d'éviter la formation du "bouclier" de plasma généré à partir de l'atmosphère de gaz ionisé par l'énergie du laser. Ceci permet d'une part d'éviter la contamination chimique du matériau (oxydation, nitruration,...) au cours des processus de fusion et d'autre part de réduire le taux de porosité. L'effet des paramètres du laser et des variables d'environnement sur la qualité de pièces a été étudié en considérant le cas du fer pur, de l'acier Inox 316L et du titane.Par ailleurs nous avons étudié la possibilité d'obtenir des alliages in-situ au cours de la fabrication par la technique SLM à partir de mélanges de poudres.Des essais ont été conduits à partir de mélanges Mg/Al, Fe/Ni et Ti/Ni. Dans tous les cas nous avons pu obtenir des alliages in-situ pour les domaines de composition visés qui correspondent à des applications pratiques (structures légères, alliage magnétique à faible coercivité, alliage à mémoire de forme). Les propriétés des matériaux obtenus, d'après les premières caractérisations effectuées, se comparent de façon favorable par rapport aux techniques classiques d'élaboration et de mise en œuvre. / During the last decade, selective laser melting attracted attention in industry because it could allow producing parts with complex shapes rapidly and accurately. The aim of this work is to obtain parts with desired properties by SLM technology. To achieve this point, a theoretical and experimental approach was developed concerning a new process which carries out the selective laser melting process at pressures in the range 1 to 1×10-2 mbar.Vacuum operating under allows avoiding the plasma shield generated from the gas atmosphere ionized by the high laser energy, which on the one hand avoids the chemical contamination (oxidizing, nitriding…) during the melting process and on the other hand reduces the porosity rate. The effect of laser parameters and environment variables on the quality of parts was studied by considering the case of pure iron, stainless steel 316L and titanium.Moreover, we studied the possibility of obtaining in-situ alloys during the SLM manufacturing technique from mixtures of powders.Tests were conducted from mixtures Mg/Al, Fe/Ni and Ti/Ni. In all cases we were able to obtain in-situ alloys for areas covered composition corresponding to practical applications (lightweight structures, low coercivity magnetic alloy, shape memory alloy). The properties of material obtained from the characterizations performed, which are comparable with the conventional development and implementation. Fusion sélective par laser Titane SLM sous vide Mélange de poudres Mg-Al Fe-Ni Ti-Ni SLM under vacuum Mixed powder Mg-Al Fe-Ni Ti-Ni
6	Corrosion en eau supercitrique : Apport à la compréhension des mécanismes pour des alliages Fe-Ni-Cr de structure c.f.c / Mechanism study of c.f.c Fe-Ni-Cr alloy corrosion in supercritical water Payet, Mickaël 28 June 2011 (has links) L’eau supercritique peut être utilisée comme caloporteur à haute pression pour améliorer le rendement des centrales électriques. Pour un concept de réacteur nucléaire, la durée de vie des matériaux est un paramètre important en termes de sécurité. Par conséquent, les critères de sélection des matériaux pour un concept de réacteur à l’eau supercritique concernent les propriétés mécaniques à haute température pour une bonne tenue au fluage et à l’irradiation mais également une résistance à la corrosion généralisée et à la corrosion sous contrainte. Ce travail à pour objectif d’améliorer la compréhension des mécanismes de corrosion en eau supercritique à 600°C et 25 MPa pour des alliages c.f.c contenant du fer, du nickel et du chrome. Des essais de corrosion ont été réalisés sur des autoclaves échantillons d’alliages 316L et 690 en prenant en compte l’état de surface. Les couches d’oxydes formées ont été décrites en termes de morphologie, de composition et de structure, après caractérisations par microscopie électronique à balayage, par spectroscopie à décharge luminescente et par diffraction des rayons X. Si un comportement de type gazeux de l’eau supercritique est attendu dans les conditions d’essai, les résultats montrent une dissolution significative de certains éléments de l’alliage. Par conséquent, la corrosion en eau supercritique peut être considérée comme similaire à la corrosion aqueuse avec un effet de la température qui peut influencer la diffusion en phase solide par exemple. Pour l’alliage 690, la couche d’oxyde protectrice formée sur une surface polie est composée de chromine et surmontée d’un chromite ou d’un spinelle mixte de nickel et de fer. La double couche d’oxyde formée sur une surface de même finition pour l’alliage 316L semble moins protectrice. La couche externe de magnétite est poreuse et la couche interne riche en chrome est non homogène. Pour chaque alliage, l’étude des mécanismes de diffusion, grâce à des expériences utilisant des marqueurs ou des traceurs, révèle une croissance de la couche d’oxyde contrôlée par un processus anionique. Cependant, l’état de surface influence fortement les mécanismes de formation des couches d’oxyde. La comparaison des résultats sur l’acier suggère qu’il y a une concurrence entre l’oxydation du fer et celle du chrome. Une quantité suffisante de chrome est nécessaire pour former une fine couche d’oxyde protectrice. Les surfaces très déformées ou à microstructure à grains très fins conduisent à des fines couches d’oxyde de chrome, grâce à une forte densité de site de germination ou grâce aux courts-circuits de diffusion du chrome. L’état de surface est donc déterminant pour l’acier mais le même paramètre engendre des effets différents pour l’alliage à base de nickel. Les surfaces usinées deviennent sensibles à une oxydation interne du chrome, même si une fine couche d’oxyde continue et riche en chrome et manganèse se forme. Ce phénomène suggère une diffusion accélérée concurrentielle entre l’oxygène et le chrome. Pour conclure, ce travail propose un mécanisme de croissance de la couche d’oxyde dans chaque cas et discute des conditions favorables à la formation d’une couche d’oxyde protectrice riche en chrome dans l’optique d’une application au réacteur à eau supercritique. / Supercritical water can be use as a high pressure coolant in order to improve the thermodynamic efficiency of power plants. For nuclear concept, lifetime is an important safety parameter for materials. Thus materials selection criteria concern high temperature yield stress, creep resistance, resistance to irradiation embrittlement and also to both uniform corrosion and stress corrosion cracking.This study aims for supplying a new insight on uniform corrosion mechanism of Fe-Ni-Cr f.c.c. alloys in deaerated supercritical water at 600°C and 25MPa. Corrosion tests were performed on 316L and 690 alloys as sample autoclaves taking into account the effect of surface finishes. Morphologies, compositions and crystallographic structure of the oxides were determined using FEG scanning electron microscopy, glow discharge spectroscopy and X-ray diffraction. If supercritical water is expected to have a gas-like behaviour in the test conditions, the results show a significant dissolution of the alloy species. Thus the corrosion in supercritical water can be considered similar to corrosion in under-critical water assuming the higher temperature and its effect on the solid state diffusion. For alloy 690, the protective oxide layer formed on polished surface consists of a chromia film topped with an iron and nickel mixed chromite or spinel. The double oxide layer formed on 316L steel seems less protective with an outer porous layer of magnetite and an inhomogeneous Cr-rich inner layer. For each alloy, the study of the inner protective scale growth mechanisms by marker or tracer experiments reveals that diffusion in the oxide scale is governed by an anionic process. However, surface finishes impact deeply the growth mechanisms. Comparisons between the results for the steel suggest that there is a competition between the oxidation of iron and chromium in supercritical water. Sufficient available chromium is required in order to form a thin oxide layer. Highly deformed or ultra fine microstructure surfaces lead to thin chromium rich oxide layers thanks to either diffusion short circuiting or increasing Cr oxide nucleation site. The nature of the surface is a determining factor in the steel instance. The same parameter breeds different effects for the Ni-based alloy. Machined surfaces lead to internal oxidation on alloy 690 even if a thin Cr and Mn rich oxide scale is formed. Competitive diffusion of oxygen and Cr species through the diffusion short circuit paths of the alloy is suggested. This work proposes oxide growth mechanisms for each case. Finally the conditions leading to the formation of chromium-rich protective oxide films in supercritical water are discussed. Corrosion en eau supercritique Courts-circuits de diffusion Alliage de Fe-Ni-Cr Effet de l’état de surface Supercritical water corrosion Diffusion short-circuits Fe-Ni-Cr alloys Surface finish effect
7	The formation of plate martensite in a Fe-High Ni alloy: Crystallography and Variant Selection Malet, Loïc 18 May 2015 (has links) Mainly two different morphologies of martensite can be obtained in steels depending on the amount of alloying elements. The first morphology, referred to as lath martensite, forms in low alloy, low carbon steels. It is, by far, the most extensively studied form of martensite due to its industrial applications. The second morphology of martensite, referred to as plate martensite, forms in highly alloyed and in high carbon steels and in particular in Fe-High Ni alloys. In this case, the transformation product is disc shaped and internally twinned. This morphology is the only form of martensite that has the potential to exhibit shape memory properties. It is therefore of great interest to understand the mechanisms of its formation. This is investigated in the present dissertation through the study of the martensitic transformation occurring in a Fe-30.5%Ni-0.155%C alloy. More precisely, the influence of stress and grain size on the crystallography of plate martensite is discussed in the general framework of the phenomenological theory of martensite crystallography. This theory allows associating a unique shape deformation to each orientational variant. In this way, the experimental observations carried out at different length scales by means of optical microscopy, EBSD and TEM can be used to infer the transformation path followed under different conditions. Firstly, the burst configurations of variants observed in coarse-grained austenite under stress free conditions are rationalized by considering the mechanical couplings between the variants. It is shown that self-accommodating and autocatalytic couplings are responsible for the formation of hierarchical configurations of variants. More precisely, the transformation is shown to occur through the alternate formation of perpendicular plate groups of variants. Self-accommodation is the dominant coupling between variants of the same plate group while autocatalytic couplings are responsible for the transfer of the transformation from one generation to the next. It is suggested that the plastic accommodation of the shape deformation plays a dominant role in propagating the transformation to a lower length scales. Secondly, the influence of a uniaxial stress state on the transformation is studied. It is seen experimentally that only the most favoured variants are systematically formed in coarse Cube grains while coarse non-Cube grains generally transform into plate groups of variants that are only moderately favoured by the stress. These observations are well explained by considering the interaction energy between the applied stress and the shape deformation associated with the transformation. Thirdly, the influence of the austenitic grain size on the transformation is also studied. A decrease in grain size is seen to decrease the martensite start temperature. For a grain size below about 10µm, the thermal transformation in liquid nitrogen is indeed suppressed in the present alloy. This observation is related to the increasing yield strength of austenite as the grain size is reduced. A noticeable change in the morphology of martensite also accompanies the decrease in grain size. Indeed, martensite forming in coarse-grained austenite is mostly lens shaped and partially twinned while it appears plate shaped and fully twinned in smaller grains. Furthermore, martensite forming in fine-grained austenite develops self-accommodating configurations suggesting that most of the transformation deformations are elastically accommodated in this case. This is believed to be related to the observance of a shape memory effect in the present alloy in its fine-grained condition. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles
8	The Electrodeposition of Fe-Ni-Cr Alloys from Aqueous Electrolytes EverhartC, Charles January 2009 (has links) No description available. Chemical Engineering Chemistry Materials Science electrodeposition Fe-Ni-Cr alloy stainless steel 316 protective coatings
9	Studium reakční syntézy intermetalických materiálů z depozitů kinetického naprašování binárních systémů obsahujících železo / Reaction synthesis of bulk intermetallic materials from cold spray deposits from binary powders containing iron Dyčková, Lucie January 2015 (has links) This thesis deals with reaction synthesis of materials Fe–Al, Fe–Cu and Fe–Ni from cold spray. In literature analysis are introduced these systems and for each system there is brief description of binary equilibrium diagram. Furthermore here are some short explanations of diffusion, Kirkendall effect and other possible processing technologies of intermetallic materials. In experimental part, samples of sprayed materials were annealed and then microstructural changes were investigated. This thesis contains photographs of microstructure, results from scanning electron microscopy, X-ray, and measurements of microhardness.
10	Mössbauer Spectroscopy of Meteoritic and Synthetic Fe-Ni Alloys Abdu, Yassir Ahmed Mohamed January 2004 (has links) <p>This thesis reports on the results of investigating Fe-containing minerals in meteorites, with focus on Fe-Ni minerals and their magnetic properties, along with some synthetic Fe-Ni analogues. The New Halfa meteorite, which fell in Sudan 1994, has been studied using Mössbauer spectroscopy, X-ray diffraction, and electron microprobe analysis techniques, and classified as an ordinary L-type chondrite of petrologic type 4. Mössbauer spectra of taenite-enriched samples from the metal particles of the New Halfa (L4) and Al Kidirate (H6) meteorites identify the following γ (fcc) Fe-Ni phases: the ferromagnetic atomically ordered taenite (<i>tetrataenite</i>) with ~ 50 at % Ni, the ferromagnetic disordered taenite with ~ 50 at % Ni, the low-Ni (~ 25 at %) paramagnetic taenite (<i>antitaenite</i>). The presence of the superstructure of tetrataenite is confirmed by synchrotron X-ray diffraction.</p><p>Fe-rich γ (fcc) Fe-Ni alloys with compositions Fe<sub>79</sub>Ni<sub>21</sub>, Fe<sub>76</sub>Ni<sub>24</sub>, and Fe<sub>73</sub>Ni<sub>27</sub>, which serve as synthetic analogues of antitaenite, are prepared by mechanical alloying and subsequent annealing at 650 °C. The Mössbauer results indicate that these alloys are inhomogeneous and contain a high moment (HM) ferromagnetic Ni-rich phase (> 30 at % Ni) and a low moment (LM) paramagnetic Fe-rich phase, which orders antiferromagnetically at low temperature. The coexistence of these phases is attributed to phase segregation occurring on short range, probably nanometer scale, consistent with the Fe-Ni phase diagram below 400 °C where there is a miscibility gap associated with a spinodal decomposition in alloys with < 50 at % Ni.</p><p>The combined high field Mössbauer spectroscopy and SQUID magnetometry results on these alloys at room temperature indicate large induced local magnetic moments in the paramagnetic part of the sample, which increases with increasing the Ni content. The results, when compared with the high field Mössbauer results on antitaenite from the metal particle of Al Kidirate and New Halfa meteorites may be used to estimate the Ni content of antitaenite in meteorites.</p><p>High pressure <sup>57</sup>Fe Mössbauer spectroscopy measurements up to ~ 41 GPa have been carried out at room temperature using the diamond anvil cell (DAC) technique in order to investigate the magnetic properties of γ (fcc) <sup>57</sup>Fe<sub>53</sub>Ni<sub>47</sub> alloy. The results indicate a pressure induced Invar effect at ~ 7 GPa and a non-magnetic or paramagnetic state above 20 GPa, demonstrating the volume dependence of the magnetic moment of γ (fcc) Fe-Ni alloys.</p> Earth sciences Meteorites Tetrataenite Antitaenite Mössbauer spectroscopy Mechanical alloying Fe-Ni alloys High pressure Geovetenskap Earth sciences Geovetenskap

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