Fabrication d'une sonde pour le champ proche optique en technologie sol-gel / Manufacturing of near-field optics probe using sol-gel technology

Mourched, Bachar

07 December 2012

L'utilisation de la microscopie de champ proche optique SNOM reste très limitée dû aux difficultés de mise en œuvre instrumentale. La sonde de champ proche est le cœur du microscope et la maîtrise de son utilisation (suppression d'un certain nombre de réglages optiques) constitue la clé technique de l'accès de cette méthode à un plus grand nombre d'utilisateurs. Ces travaux de thèse s'effectuent dans le contexte d'un projet qui consiste à réaliser la preuve de concept d'une sonde novatrice en matériau hybride organique/minéral, de type levier, intégrant une fonction optique. Dans la première partie, une étude bibliographique retrace l'historique des microscopies et donne le principe du champ proche optique. Ensuite, les différentes sondes commerciales de type fibre optique ou cantilever, à ouverture ou sans ouverture, ou autre, leurs avantages et inconvénients, leurs techniques de fabrication et les principaux matériaux utilisés sont présentés. En se basant sur cette étude bibliographique, on propose une nouvelle sonde à pointe pleine en matériau hybride qui associe les avantages de chaque type de sonde. Les raisons du choix du matériau hybride comme matériau de base de la sonde et ses caractéristiques sont aussi présentées dans cette partie. Dans une deuxième partie on détaille le procédé de fabrication du matériau (synthèse) ainsi que le rôle des différentes étapes dans ce procédé et les changements réalisées suite à des modifications des paramètres de la synthèse. Une caractérisation de ce matériau est aussi réalisée dans cette partie en mesurant son indice de réfraction et son module d'Young. La troisième partie est consacrée à la détermination des dimensions de la sonde qui permettent de maximiser le transfert de puissance optique en émission et réception. Ceci est fait en se basant sur une étude plus théorique au travers de simulations. L'effet de plusieurs paramètres sur la propagation de la lumière dans la sonde est étudié (longueur, largeur, épaisseur et raideur du levier ainsi qu'ouverture à l'extrémité de la pointe). La quatrième partie est dédié à la réalisation des sondes "micropoutres sol-gel" et aux caractérisations mécaniques et optiques associées. Elle présente le procédé de fabrication optimisé de sondes optiques couplant la définition des sondes par méthode de masquage et leur libération par gravure réactive ionique et gravure au fluorure de xénon "DRIE + XeF2". A partir de ce procédé, des guides d'ondes optiques ont été réalisés et caractérisés permettant la détermination des pertes optiques et donc du coefficient d'absorption du matériau hybride développé. La conclusion présente les perspectives ouvertes et en cours de ce travail dans le cadre d'un projet plus global. . / .The use of near-field optical microscopy SNOM is still very limited due to difficulties in instrumental work. The probe is the heart of the microscope and control its use (removal of optical settings number) is the technique key to access this method to a larger number of users. This thesis work is realized in the context of a project to achieve a concept proof for an innovative probe organic / inorganic hybrid material, lever type, incorporating an optical function. In the first part, the history of microscopy and the principle of the optical near field are described in a literature study. Then, the various commercial probes of optical fiber or cantilever type, with aperture or apertureless, or otherwise, their advantages and disadvantages, their manufacturing techniques and the main materials used are presented. Based on this literature study, we propose a new probe full tip hybrid material that combines the advantages of each type of probe. The choice reasons of the hybrid material as base material of the probe and its characteristics are also presented in this part. In the second part we detail the manufacturing process of the material (synthesis) as well as each step role in this process and changes made in response to changes in the synthesis parameters. Characterization of this material is also carried out in this part by measuring its refractive index and its Young's modulus. The third part is devoted to the determination of the probe dimensions to maximize the optical transmission and collection power based on a theoretical study through simulations. Several parameters effect on the light propagation in the probe is also studied (length, width, thickness and stiffness of the lever and aperture towards the end of the tip). The fourth part is dedicated to the probe achievement in hybrid material and associated mechanical and optical characterizations. It presents the manufacturing optimized process of optical probes coupling masking defining method probes and releasing method by reactive ion etching and etching xenon fluoride "DRIE + XeF2". Using this process, optical waveguides were realized and characterized for the determination of optical losses and therefore the absorption coefficient of the developed hybrid material. The conclusion presents open perspectives as part of a larger project.

Sol-gel

Sol-gel process

Optical nanoscopy of transient states in condensed matter

Kehr, Susanne C., Kuschewski, Frederik, Green, Bert, Bauer, Ch., Eng, Lukas M., Gensch, Michael

20 January 2016

Recently, the fundamental and nanoscale understanding of complex phenomena in materials research and the life sciences, witnessed considerable progress. However, elucidating the underlying mechanisms, governed by entangled degrees of freedom such as lattice, spin, orbit, and charge for solids or conformation, electric potentials, and ligands for proteins, has remained challenging. Techniques that allow for distinguishing between different contributions to these processes are hence urgently required. In this paper we demonstrate the application of scattering-type scanning near-field optical microscopy (s-SNOM) as a novel type of nano-probe for tracking transient states of matter. We introduce a sideband-demodulation technique that allows for probing exclusively the stimuli-induced change of near-field optical properties. We exemplify this development by inspecting the decay of an electron-hole plasma generated in SiGe thin films through near-infrared laser pulses. Our approach can universally be applied to optically track ultrafast/-slow processes over the whole spectral range from UV to THz frequencies.

info:eu-repo/classification/ddc/000

ddc:000

info:eu-repo/classification/ddc/500

ddc:500

Luminiscence polovodičů studovaná rastrovací optickou mikroskopií v blízkém poli / Luminescence of semiconductors studied by scanning near-field optical microscopy

Těšík, Jan

January 2017

This work is focused on the study of luminescence of atomic thin layers of transition metal chalkogenides (eg. MoS2). In the experimental part, the work deals with the preparation of atomic thin layers of semiconducting chalcogenides and the subsequent manufacturing of plasmonic interference structures around these layers. The illumination of the interference structure will create a standing plasmonic wave that will excite the photoluminescence of the semiconductor. Photoluminescence was studied both by far-field spectroscopy and near-field optical microscopy.

Příprava a testování SNOM sond speciálních vlastností / Preparation and testing of SNOM probes

Bobek, Juraj

January 2019

Fotonická krystalická vlákna (PCF) představují slibný nástroj pro spojení technik známých z mikroskopie rastrovací sondou, elektronové mikroskopie a systémů pro vstřikování plynu. Přivedení světla a přenos pracovního plynu současně do blízkosti vzorku umístěného uvnitř elektronového mikroskopu přináší nové možnosti experimentů. PCF by mohly být použity nejen k charakterizaci nebo modifikaci struktur na mikroskopické úrovni, ale také k jejich výrobě. Tato práce se zabývá výzkumem literárních zdrojů s tématikou fotonických krystalů s důrazem na PCF. Leptání PCF pomocí kyseliny fluorovodíkové bez poškození jejich vnitřní struktury je experimentálně studováno s velkou precizností. Optické vlastnosti závislé na geometrii PCF jsou testovány pro různé modifikace PCF. Dále se práce zabývá spojením PCF s mikroskopií atomárních sil a následnou integrací do elektronového mikroskopu.

Studium vlastností ohýbaných FRP výztuží / Study of properties of bent FRP reinforcement

Lipoldová, Marie

January 2021

The diploma thesis deals with the study of bent FRP reinforcements with the main focus on the methods of production of bent FRP reinforcement, examples of their application in structures. The work also mentions the effects of aggressive environments on the durability of FRP. In the practical part, a search of the possibilities of testing the properties of bent FRP reinforcement. Subsequently, an experiment is designed and performed to monitor changes in the properties of straight and bent FRP reinforcement exposed to the alkaline environment and water at 20 °C and 40 °C. Finally, the evaluation of changes in mechanical properties and observation of reinforcements using optical and scanning electron microscopy is performed.

Excitation, Interaction, and Scattering of Localized and Propagating Surface Polaritons

Renger, Jan

19 July 2006

Surface polaritons, i.e., collective oscillations of the surface charges, strongly influence the optical response at the micro- and nanoscale and have to be accounted for in modern nanotechnology. Within this thesis, certain basic phenomena involving surface polaritons are investigated by means of the semianalytical multiple-multipole (MMP) method. The results are compared to experiments. In the first part, the surface plasmon resonance (SPR) of metal nanoparticles is analyzed. This resonant collective oscillation of the free electrons in a metallic nanoparticle leads to an enhancement and confinement of the local electric field at optical frequencies. The local electric field can be further increased by tailoring the shape of the particle or by using near-field-interacting dimers or trimers of gold nanospheres. The hot spots found under such conditions increase the sensitivity of surface-enhanced Raman scattering by several orders of magnitude and simultaneously reduce the probed volume, thereby providing single-molecule sensitivity. The sub-wavelength-confined strong electromagnetic field associated with a SPR provides the basis for scattering-type near-field optical microscopy or tip-enhanced Raman spectroscopy, where the metal particle serves as a probe that is scanned laterally in the vicinity of a substrate. The presence of the latter causes a characteristic shift of the SPR towards lower frequencies. This effect originates in the near-field interaction of the surface charges on the objects. Furthermore, the excitation of higher-order modes becomes possible in case of an excitation by a strongly inhomogeneous wave, such as an evanescent wave. These modes may significantly contribute to the near field but have only very little influence on the far-field signature. Instead of using resonant probes, one may place a nonresonant probe in the vicinity of a substrate having a high density of electromagnetic surface states. This also produces a resonance of the light scattering by the system. Especially polar crystals, such as the investigated silicon carbide, feature such a high density of surface phonon polariton states in the mid-infrared spectral region, which can be excited due to the near-field interaction with a polarized particle. Thereby, a resonance is created leading to a strong increase of the electric field at the interface. In the second part of the thesis, special emphasis is put on surface plasmon polaritons (SPPs). Such propagating surface waves can be excited directly by plane waves only at patterned interfaces. This process is studied for the case of a groove. The groove breaks the translational invariance, so that the SPPs can be launched locally at the edges of the groove. Additionally, the mode(s) inside the groove are excited. These modes can basically be understood as metal-insulator-metal cavity modes. Their dispersion strongly depends on the groove width. The cavity behavior caused by the finite depth provides another degree of freedom for optimizing the SPP excitation by plane waves. Thin metallic films deposited on glass offer two different SPP waveguide modes, each of which can be addressed preferentially by a proper choice of the width of the groove. The reflection, transmission, scattering, and the conversion of the modes at discontinuities such as edges, steps, barriers, and grooves can be controlled by appropriately designing the geometry at the nanoscale. Furthermore, the excitation of SPPs at single and multiple slits in thin-film metal waveguides on glass and their propagation and scattering is shown by scanning near-field optical experiments. Such waveguide structures offer a means for transporting light in a confined way. Especially triangularly shaped waveguides can be used to guide light in sub-wavelength spaces. / Die Wechselwirkung von elektromagnetischer Strahlung mit subwellenlängenkleinen Teilchen bzw. Oberflächenstrukturen ermöglicht nicht nur eine Miniaturisierung optischer Geräte, sondern erlaubt sehr interessante Anwendungen, beispielsweise in der Sensorik und Nahfeldoptik. In der vorliegenden Arbeit werden die zu Grunde liegenden Effekte im Rahmen der klassischen Elektrodynamik mit Hilfe der semianalytischen Methode der multiplen Multipole (MMP) analysiert, und die Ergebnisse werden mit Experimenten verglichen. Im ersten Teil werden Oberflächenplasmonenresonanzen (engl. surface plasmon resonance - SPR) einzelner und wechselwirkender Metallteilchen untersucht. Die dabei auftretende resonante kollektive Schwingung der freien Elektronen des Partikels bewirkt eine deutliche Erhöhung und Lokalisierung des elektromagnetischen Feldes in seiner Umgebung. Die spektrale Position und die Stärke der SPR eines Nanoteilchens, die von dessen geometrischer Form, Permittivität und Umgebung abhängen, können nur im Grenzfall sehr kleiner Teilchen elektrostatisch beschrieben werden, wohingegen der verwendete semianalytische MMP-Ansatz weitaus flexibler ist und insbesondere auch auf größere Partikel, Teilchen mit komplizierterer Form bzw. Ensembles von Partikeln anwendbar ist. Die betrachteten einzelnen kleinen (< Wellenlänge) Goldkügelchen und Silberellipsoide besitzen eine stark ausgeprägte SPR im sichtbaren optischen Bereich. Diese ist auf eine dipolartige Polarisierung des Teilchens zurückzuführen. Höhere Moden der Polarisation können entweder als Folge von Retardierungseffekten an größeren (mit der Wellenlänge vergleichbaren) Teilchen oder bei der Verwendung inhomogener (z.B. evaneszenter) Wellen angeregt werden. Partikel, die sich in der Nähe eines Substrates befinden, unterliegen der Nahfeldwechselwirkung zwischen den (lichtinduzierten) Oberflächenladungen auf der Oberfläche des Teilchens und des Substrats. Dies führt zu einer Verschiebung der SPR zu niedrigeren Frequenzen und einer Erhöhung des lokalen elektrischen Feldes. Letzteres bildet die Grundlage z.B. der spitzenverstärkten Raman-Spektroskopie und der optischen Nahfeldmikroskopie mit Streulichtdetektion. Dasselbe Prinzip bewirkt ein stark überhöhtes elektrisches Feld zwischen miteinander wechselwirkenden Nanopartikeln, welches z.B. die Sensitivität der oberflächenverstärkten Raman-Mikroskopie um mehrere Größenordnungen steigern kann. Im Gegensatz zur SPR einzelner Nanopartikel kann die Resonanz der Lichtstreuung im Fall eines Partikels in der Nähe eines Substrats aus der durch die Nahfeldwechselwirkung induzierten Anregung elektromagnetischer Oberflächenzustände entstehen. Diese wirken ihrerseits auf das Nanopartikel zurück, wobei eine resonante Lichtstreuung beobachtbar ist. Dieser, am Beispiel einer metallischen Nahfeldsonde über einem Siliziumcarbid-Substrat analysierte, Effekt ermöglicht bei einer ganzen Klasse von polaren Kristallen interessante Anwendungen in der Mikroskopie und Sensorik basierend auf der hohen Dichte von Oberflächenphononpolaritonen dieser Kristalle im mittleren infraroten Spektralbereich und deren nahfeldinduzierten Anregung. Im zweiten Teil der Arbeit werden kollektive Anregungen von Elektronen an Metalloberflächen untersucht. Die dabei auftretenden plasmonischen Oberflächenwellen (engl. surface plasmon polaritons - SPPs) weisen einen exponentiellen Abfall der Intensität senkrecht zur Grenzfläche auf. Diese starke Lokalisierung der Energie an der Oberfläche bildet die Grundlage vieler Anwendungen, z.B. im Bereich der hochempfindlichen Detektion (bio)chemischer Verbindungen oder für eine zweidimensionale Optik (engl. plasmonics). Das Aufheben der Translationsinvarianz längs der Oberfläche ermöglicht die direkte Anregung von SPPs durch ebene Wellen. Die Abhängigkeit dieser Kopplung von der Geometrie wird am Beispiel eines Nanograbens untersucht. Dabei werden neben den SPPs ebenfalls eine oder mehrere Moden im Graben angeregt. Folglich ermöglicht die geeignete Wahl der Grabengeometrie die Optimierung der Umwandlung von ebenen Wellen in SPPs. Im - in der Praxis weit verbreiteten - Fall asymmetrisch eingebetteter metallischer Dünnschichtwellenleiter existieren zwei Moden. In Abhängigkeit von der Grabenbreite kann die eine oder die andere Mode bevorzugt angeregt werden. Die Analyse der Wechselwirkung von SPPs mit Oberflächenstrukturen, z.B. Kanten, Stufen, Barrieren und Gräben, zeigt die Möglichkeit der Steuerung der Reflexions-, Transmissions- und Abstrahleigenschaften durch die gezielte Wahl der Geometrie der "Oberflächendefekte" auf der Nanoskala und deckt die zu Grunde liegenden Mechanismen und die daraus resultierenden Anforderungen bei der Herstellung neuer plasmonischer Komponenten auf. Exemplarisch wird das Prinzip der SPP-Anregung an einzelnen und mehreren Gräben in dünnen metallischen Filmen sowie der subwellenlängen Feldlokalisierung an sich verjüngenden metallischen Dünnschichtwellenleitern unter Verwendung der optischen Nahfeldmikroskopie experimentell gezeigt.

info:eu-repo/classification/ddc/530

ddc:530

Bistable self-assembly in homogeneous colloidal systems for flexible modular architectures

Steinbach, Gabi, Nissen, Dennis, Albrecht, Manfred, Novak, Ekaterina V., Sánchez, Pedro A., Kantorovich, Sofia S., Gemming, Sibylle, Erbe, Artur

29 April 2016

This paper presents a homogeneous system of magnetic colloidal particles that self-assembles via two structural patterns of different symmetry. Based on a qualitative comparison between a real magnetic particles system, analytical calculations and molecular dynamics simulations, it is shown that bistability can be achieved by a proper tailoring of an anisotropic magnetization distribution inside the particles. The presented bistability opens new possibilities to form two-dimensionally extended and flexible structures where the connectivity between the particles can be changed in vivo. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/539

ddc:539

info:eu-repo/classification/ddc/541

ddc:541

Information Transduction Between Spintronic, Photonic, and Magnetic States in Two-Dimensional Hybrid Systems

Luo, Yunqiu (Kelly)

January 2019

No description available.

Condensed Matter Physics

Materials Science

Optics

Spintronics

Photonics

Magnetism

Valleytronics

Information Transduction

Two-Dimensional Materials

Van der Waals Heterostructure

Graphene

Transition Metal Dichalcogenides

Optical Spin Injection

Optical Microscopy

Ultrafast Dynamics

DEVELOPMENT OF FLUORESCENCE-DETECTED PHOTOTHERMAL MICROSCOPY METHODS FOR MAPPING CHEMICAL COMPOSITION

Aleksandr Razumtcev (18097990)

04 March 2024

<p dir="ltr">The beautiful complexity of our world is manifested in how macro- and even planetary-scale processes are essentially completely determined and regulated by chemical and physical transformations happening at the micro- and nanoscale. The introduction and subsequent development of optical microscopy methods have provided us with a unique opportunity to visualize, probe, and sometimes even control these processes that are too small to be seen by the human eye by their nature.</p><p dir="ltr">Among the great variety of truly impressive advances in microscopy instrumentation, two techniques stand out in their widespread and usefulness. First of them, fluorescence imaging has completely revolutionized the study of biological specimens and living systems due to its unprecedented single-molecule sensitivity and resolution combined with video-rate imaging capability. On the other hand, chemical imaging in the mid-infrared region provides an unmatched amount of chemical information enabling label-free mapping of the spatial distribution of various classes of biological molecules. However, each of these techniques falls short where the other excels. For example, despite its high resolution and sensitivity, fluorescence imaging does not carry direct chemical information and relies on labeling specificity, while infrared microscopy is diffraction-limited at the resolution of several micrometers and suffers from low penetration depth in aqueous solutions.</p><p dir="ltr">This dissertation introduces a novel imaging method designed to combine the advantages of fluorescence imaging and infrared spectroscopy. Fluorescence-detected photothermal mid-IR (F-PTIR) microscopy is presented in <b>chapter 1</b> as a technique enabling sub-diffraction chemically-specific microscopy by detecting local temperature-induced fluctuations in fluorescence intensity to inform on localized mid-infrared absorption. F-PTIR applications in targeted biological microspectroscopy (<b>chapter 1</b>) and pharmaceutical materials (<b>chapters 2 and 3</b>) analysis are demonstrated to highlight the potential of this new method. Furthermore, instrumentation developments relying on modern radiation sources such as dual-comb quantum cascade laser and synchrotron infrared radiation are shown to improve spectral acquisition speed (<b>chapter 4</b>) and spectral coverage (<b>chapter 5</b>), respectively, to extend the application range of F-PTIR.</p>

Analytical spectrometry

Optical microscopy

Spectroscopy

Fluorescence microscopy

Infrared microscopy

Photothermal microscopy

synchrotron radiation

synchrotron infrared microscopy

Huntington's disease

Nonlinear Optical Spectroscopy

Dual-comb spectroscopy

A Petrographic and Paragenetic Characterization of the Ertelien Ni-Cu Deposit (Norway) / En petrografisk och paragenetisk karaktärisering av Ertelien Ni-Cu-fyndigheten (Norge)

Niarezka, Alena

January 2023

The escalating demand for metals driven by advancements in renewable energy technologies and hightech products has underscored the significance of understanding and characterizing ore deposits. This study focuses on the Ertelien Ni-Cu deposit in Norway, a region rich in nickel, cobalt, and copper resources—essential components for the transition to a sustainable energy future. The deposit, located within the Kongsberg belt, holds substantial economic potential due to its Ni-Cu-Co sulfide mineral enrichment. Previous assay results from drill cores, optical microscopy, and electron probe micro-analysis were employed to characterize the mineralogy and based on this interpreter the formation mechanisms, and enrichment processes that formed the deposit.  The Ertelien deposit represents an igneous origin with significant Ni-Cu-Co content estimated at 2.7 million metric tons, with grades of 0.83%, 0.69%, and 0.06%, respectively, within a gabbronorite intrusive body. Optical microscopy and electron probe micro-analysis revealed a complex mineral assemblage including common silicates such as plagioclase, pyroxene, amphibole, mica, olivine, and others, as well as sulfides such as pyrite, chalcopyrite, pyrrhotite, pentlandite.  The primary objective of this study is to conduct an in-depth examination of the geological, mineralogical, and enrichment aspects of the Ertelien deposit. Specifically, primary magmatic and assimilation processes involved in the formation of Ni-Cu-deposits were be evaluated, as well as any potential metal redistribution resulting from secondary processes. Mineralogical studies, facilitated by combining optical microscopy and electron microprobe analysis provided important information on the mechanisms contributing to metal enrichment in or deposits. Optical microscopy and electron probe microanalysis revealed a complex mineral assemblage including common silicates such as plagioclase, pyroxene, amphibole, mica, olivine, and others, as well as sulfides such as pyrite, chalcopyrite, pyrrhotite, pentlandite.  The analyzed rock suite spans a range of compositions from gabbroic to tonalite, with MgO concentrations varying from 0.38 to 22.96 wt.%. Overall, there is a discernible trend of sulfur enrichment in or near samples characterized by low MgO and high Na2O and CaO contents, suggesting that sulfide saturation is likely associated with the assimilation of S-bearing gneisses into which the Ertelien gabbronorites intruded. Ni concentrations exhibit an increasing trend with depth. The nickel-to-cobalt ratio (Ni/Co) displays a discernible pattern that correlates with sulfide crystallization during the process of magmatic fractionation. Notable distinctions observed among groups characterized by differing Ni/Co contents in chalcopyrite, pentlandite, pyrrhotite, and pyrite reveal distinct trends in Ni concentrations. In conjunction with the presence of sphalerite and Ag-pentlandite, which are indicative of lower temperature origin compared to magmatic activity, all these observations provide compelling indications of diverse potential sources, including variations in magma compositions and the influence of hydrothermal processes.  Investigating ore formation conditions enhances the mining sector's ability to identify high-potential mineralization areas, vital for ensuring a stable supply of metals essential for renewable energy systems, electric vehicles, and advanced electronics. / Den eskalerande efterfrågan på metaller som drivs av framsteg inom förnybar energiteknik och högteknologiska produkter har understrukit betydelsen av att förstå och karakterisera malmfyndigheter. Denna studie fokuserar på Ertelien Ni-Cu-fyndigheten i Norge, en region rik på nickel-, kobolt- och kopparresurser – väsentliga komponenter för övergången till en hållbar energiframtid. Fyndigheten, som ligger inom Kongsbergsbältet, har en betydande ekonomisk potential på grund av dess Ni-Cu-Cosulfidmineralanrikning. Tidigare analysresultat från borrkärnor, optisk mikroskopi och elektronsondsmikroanalys användes för att karakterisera mineralogin och baserat på denna tolk för bildningsmekanismerna och anrikningsprocesserna som bildade fyndigheten.  Ertelien-avlagringen representerar ett magmatiskt ursprung med betydande Ni-Cu-Co-innehåll uppskattat till 2.7 miljoner ton, med halter på 0.83%, 0.69% respektive 0.06% inom en gabbronorit-intrusiv kropp. Optisk mikroskopi och elektronsondsmikroanalys avslöjade en komplex mineralsammansättning inklusive vanliga silikater som plagioklas, pyroxen, amfibol, glimmer, olivin och andra, såväl som sulfider som pyrit, kolopirit, pyrrotit, pentlandit.  Det primära syftet med denna studie är att genomföra en djupgående undersökning av de geologiska, mineralogiska och anrikningsaspekterna av Ertelienfyndigheten. Specifikt utvärderades primära magmatiska och assimileringsprocesser involverade i bildandet av Ni-Cu-avlagringar, såväl som eventuell metallomfördelning till följd av sekundära processer. Mineralogiska studier, underlättade genom att kombinera optisk mikroskopi och elektronmikrosondanalys gav viktig information om de mekanismer som bidrar till metallanrikning i eller avlagringar. Optisk mikroskopi och elektronsondsmikroanalys avslöjade en komplex mineralsammansättning inklusive vanliga silikater som plagioklas, pyroxen, amfibol, glimmer, olivin och andra, såväl som sulfider som pyrit, kolopirit, pyrrotit, pentlandit.  Den analyserade bergsviten sträcker sig över en rad kompositioner från gabbroic till tonalit, med MgOkoncentrationer som varierar från 0.38 till 22.96 viktprocent. Sammantaget finns det en urskiljbar trend av svavelanrikning i eller nära prover som kännetecknas av lågt MgO och högt Na2O- och CaO-innehåll, vilket tyder på att sulfidmättnad sannolikt är associerad med assimileringen av S-bärande gnejser i vilka Ertelien-gabbronoriterna inträngde. Ni-koncentrationer uppvisar en ökande trend med djupet. Förhållandet nickel till kobolt (Ni/Co) visar ett urskiljbart mönster som korrelerar med sulfidkristallisation under processen för magmatisk fraktionering. Anmärkningsvärda skillnader som observerats bland grupper som kännetecknas av olika Ni/Co-halter i karbonat, pentlandit, pyrrotit och pyrit avslöjar distinkta trender i Nikoncentrationer. I samband med närvaron av sfalerit och Ag-pentlandit, som indikerar lägre temperaturursprung jämfört med magmatisk aktivitet, ger alla dessa observationer övertygande indikationer på olika potentiella källor, inklusive variationer i magmasammansättningar och påverkan av hydrotermiska processer.  Att undersöka malmbildningsförhållanden förbättrar gruvsektorns förmåga att identifiera mineraliseringsområden med hög potential, avgörande för att säkerställa en stabil tillgång på metaller som är nödvändiga för förnybara energisystem, elfordon och avancerad elektronik.

Ertelien Ni-Cu deposit

ore geology

enrichment processes

nickel

cobalt

copper

optical microscopy

electron probe micro-analysis

critical metals

Ertelien Ni-Cu fyndighet

malmgeologi

anrikningsprocesser

nickel

kobolt

koppar

optisk mikroskopi

elektronsondsmikroanalys

kritiska metaller

Earth and Related Environmental Sciences

Geovetenskap och miljövetenskap