The Structural Basis for Magnetic Order in New Manganese Compounds

Eriksson, Therese

January 2005

<p>Materials with new or improved properties are crucial for technological development. To provide the foundation for future successful products, it is important to prepare and characterise new chemical compounds that could show unusual properties. The properties of magnetic materials are closely related to their crystal, magnetic and electronic structures. This thesis focuses on the novel synthesis and structural characterisation of a number of new ternary or <i>pseudo</i>-ternary silicides and germanides of manganese with iridium, cobalt or palladium. To provide a more complete picture of the complex magnetic properties, crystal and magnetic structure refinements by the Rietveld method of X-ray and neutron powder diffraction data are complemented by single-crystal X-ray diffraction, electron diffraction, magnetisation measurements and Reverse Monte Carlo simulations of magnetic short-range order. The experimental results are corroborated by first-principles electronic structure and total energy calculations. </p><p>A commensurate non-collinear antiferromagnetic structure is found for most compounds of the solid solution Mn₃Ir_1-yCo_ySi_1-xGe_x. The non-collinearity is a result of geometric frustration in a crystal structure with magnetic Mn atoms located on a three-dimensional network of triangles. The close structural similarity to the β-modification of elemental manganese, which does not order magnetically, inspired a closer theoretical comparison of the Mn₃Ir_1-yCo_ySi_1-xGe_x propertieswith β-Mn.</p><p>Magnetic frustration is also observed for Mn₄Ir_7-xMn_xGe₆, and is an important factor underlying the dramatic change from commensurate antiferromagnetic order to spin glass properties induced by a small variation in Mn concentration. Magnetic short-range order with dominant antiferromagnetic correlation is observed for Mn₈Pd₁₅Si₇, and results from a random distribution of Mn atoms in-between the geometrically frustrated magnetic moments on the Mn octahedra. </p><p>An incommensurate cycloidal magnetic structure, observed for IrMnSi, is stabilised by an electronic structure effect, which also accounts for the non-collinearity of the Mn₃IrSi type magnetic structure.</p>

Inorganic chemistry

Crystal structure

Magnetic structure

Manganese compounds

Transition metal silicides

Transition metal germanides

Magnetic frustration

Neutron powder diffraction

X-ray diffraction

Magnetisation measurements

DFT

Oorganisk kemi

Inorganic chemistry

Oorganisk kemi

The Structural Basis for Magnetic Order in New Manganese Compounds

Eriksson, Therese

January 2005

Materials with new or improved properties are crucial for technological development. To provide the foundation for future successful products, it is important to prepare and characterise new chemical compounds that could show unusual properties. The properties of magnetic materials are closely related to their crystal, magnetic and electronic structures. This thesis focuses on the novel synthesis and structural characterisation of a number of new ternary or pseudo-ternary silicides and germanides of manganese with iridium, cobalt or palladium. To provide a more complete picture of the complex magnetic properties, crystal and magnetic structure refinements by the Rietveld method of X-ray and neutron powder diffraction data are complemented by single-crystal X-ray diffraction, electron diffraction, magnetisation measurements and Reverse Monte Carlo simulations of magnetic short-range order. The experimental results are corroborated by first-principles electronic structure and total energy calculations. A commensurate non-collinear antiferromagnetic structure is found for most compounds of the solid solution Mn3Ir1-yCoySi1-xGex. The non-collinearity is a result of geometric frustration in a crystal structure with magnetic Mn atoms located on a three-dimensional network of triangles. The close structural similarity to the β-modification of elemental manganese, which does not order magnetically, inspired a closer theoretical comparison of the Mn3Ir1-yCoySi1-xGex propertieswith β-Mn. Magnetic frustration is also observed for Mn4Ir7-xMnxGe6, and is an important factor underlying the dramatic change from commensurate antiferromagnetic order to spin glass properties induced by a small variation in Mn concentration. Magnetic short-range order with dominant antiferromagnetic correlation is observed for Mn8Pd15Si7, and results from a random distribution of Mn atoms in-between the geometrically frustrated magnetic moments on the Mn octahedra. An incommensurate cycloidal magnetic structure, observed for IrMnSi, is stabilised by an electronic structure effect, which also accounts for the non-collinearity of the Mn3IrSi type magnetic structure.

Inorganic chemistry

Crystal structure

Magnetic structure

Manganese compounds

Transition metal silicides

Transition metal germanides

Magnetic frustration

Neutron powder diffraction

X-ray diffraction

Magnetisation measurements

DFT

Oorganisk kemi

Inorganic chemistry

Oorganisk kemi

Atomistic Simulations of Bonding, Thermodynamics, and Surface Passivation in Nanoscale Solid Propellant Materials

Williams, Kristen

2012 August 1900

Engineering new solid propellant materials requires optimization of several factors, to include energy density, burn rate, sensitivity, and environmental impact. Equally important is the need for materials that will maintain their mechanical properties and thermal stability during long periods of storage. The nanoscale materials considered in this dissertation are proposed metal additives that may enhance energy density and improve combustion in a composite rocket motor. Density Functional Theory methods are used to determine cluster geometries, bond strengths, and energy densities. The ground-state geometries and electron affinities (EAs) for MnxO?: x = 3, 4, y = 1, 2 clusters were calculated with GGA, and estimates for the vertical detachment energies compare well with experimental results. It was found that the presence of oxygen influences the overall cluster moment and spin configuration, stabilizing ferrimagnetic and antiferromagnetic isomers. The calculated EAs range from 1.29-1.84 eV, which is considerably lower than the 3.0-5.0 eV EAs characteristic of current propellant oxidizers. Their use as solid propellant additives is limited. The structures and bonding of a range of Al-cyclopentadienyl cluster compounds were studied with multilayer quantum mechanics/molecular mechanics (QM:MM) methods. The organometallic Al-ligand bonds are generally 55-85 kcal/mol and are much stronger than Al-Al interactions. This suggests that thermal decomposition in these clusters will proceed via the loss of surface metal-ligand units. The energy density of the large clusters is calculated to be nearly 60% that of pure aluminum. These organometallic cluster systems may provide a route to extremely rapid Al combustion in solid rocket motors. Lastly, the properties of COOH-terminated passivating agents were modeled with the GPW method. It is confirmed that fluorinated polymers bind to both Al(111) and Al(100) at two Al surface sites. The oligomers HCOOH, CH3CH2COOH, and CF3CF2COOH chemisorb onto Al(111) with adsorption energies of 10-45 kcal/mol. The preferred contact angle for the organic chains is 65-85 degrees, and adsorption energy weakens slightly with increasing chain length. Despite their relatively weak adsorption energies, fluorinated polymers have elevated melting temperatures, making them good passivation materials for micron-scale Al fuel particles.

materials science

solid propellants

organometallics

ab initio calculations

antiferromagnetic materials

ferrimagnetic materials

ground states

isomerisation

magnetic moments

magnetic structure

manganese compounds

molecular clusters

photoelectron spectra

chemisorption

dispersion interactions

carboxylates

surface passivation

thermodynamics

density functional theory

Νέες πλειάδες μεικτού-σθένους (ΙΙ/ΙΙΙ) του μαγγανίου με υποκαταστάτη την 2-πυριδυλομεθανόλη : σύνθεση, δομή, χημική δραστικότητα και μαγνητική μελέτη / New mixed-valent (II/III) manganese clusters from the use of 2-(hydroxymethyl) pyridine : synthesis, structure, reactivity and magnetic studies

Αλεξανδρόπουλος, Δημήτρης

21 December 2012

Η σύνθεση και ο χαρακτηρισμός πλειάδων των μετάλλων μετάπτωσης σε ενδιάμεσες οξειδωτικές βαθμίδες αποτελεί σήμερα έναν από τους κύριους ερευνητικούς στόχους πολλών επιστημονικών ομάδων παγκοσμίως εξαιτίας των εφαρμογών που βρίσκουν σε διάφορα επιστημονικά πεδία, όπως στη βιοανόργανη χημεία, στην επιστήμη των υλικών, στη μοριακή φυσική και ηλεκτρονική, και στη θεωρητική χημεία. Οι πλειάδες αυτές περιέχουν πολλές φορές έναν ασυνήθιστα μεγάλο αριθμό ασυζεύκτων ηλεκτρονίων στη θεμελιώδη κατάσταση και παρουσιάζουν εξαιρετικό ενδιαφέρον από μαγνητικής απόψεως. Αυτό συμβαίνει γιατί μια υψηλή τιμή spin στη θεμελιώδη κατάσταση είναι αναγκαία (άλλα όχι ικανή) συνθήκη ώστε αυτού του είδους οι σύμπλοκες ενώσεις να εμφανίζουν το φαινόμενο του μονομοριακού μαγνητισμού (single-molecule magnetism). Στην παρούσα Εργασία μελετήθηκε το σύστημα αντίδρασης μαγγάνιο/2-πυριδυλομεθανόλη (hmpH), παρουσία ή απουσία κυανικών ιόντων (OCN-) και κάτω από βασικές συνθήκες, το οποίο οδήγησε στην απομόνωση και το δομικό (μέσω κρυσταλλογραφίας ακτίνων-Χ σε μονοκρυστάλλους) και μαγνητοχημικό χαρακτηρισμό των πλειάδων [Mn7(OH)3(OCN)3(hmp)9](ClO4)2 (1), [Mn16O8(OMe)4(OCN)4(O2CMe)12(hmp)6(MeOH)2] (2), [Mn18O14(O2CMe)18(hmp)4(hmpH)2(H2O)2] (3) και [Mn18O14(O2CEt)18(hmp)4(hmpH)2(H2O)2] (4). Οι πλειάδες 1-4 είναι μικτού-σθένους (ΙΙ/ΙΙΙ). Το σύμπλοκο 1 αποτελεί ένα νέο μέλος μιας μεγάλης οικογένειας επταπυρηνικών συμπλόκων με το δομικό πυρήνα τους να περιλαμβάνει έξι ιόντα Mn διευθετημένα κυκλικά γύρω από ένα έβδομο κεντρικό ιόν Mn2+. Τα σύμπλοκα 2, 3 και 4 αποτελούν παραδείγματα υψηλής πυρηνικότητας και συμμετρίας πλειάδων του Mn, με αισθητικά όμορφες δομές και ενδιαφέρουσες μαγνητικές ιδιότητες. / The synthesis and characterization of polynuclear metal complexes (clusters) containing paramagnetic 3d-metal ions in intermediate oxidation states have gained intense interest due to the applications of these compounds in several fields of science, such as bioinorganic chemistry, materials science, molecular physics and electronics, and theoretical chemistry. Such high nuclearity transition metal clusters are one of the growing research subjects in Molecular Magnetism, given the fact that they often possess a fairly large ground-state spin value, which is one of the necessary requirements for a molecule to be able to exhibit the phenomenon of single-molecule magnetism. In the present work, we studied the general reaction system manganese/2-(hydroxymethyl)pyridine (hmpH), in the presence or absence of cyanate ions (OCN-), under basic conditions, which has led to the isolation, and structural (through single-crystal X-ray crystallography) and magnetochemical characterization of the compounds [Mn7(OH)3(OCN)3(hmp)9](ClO4)2 (1), [Mn16O8(OMe)4(OCN)4(O2CMe)12(hmp)6(MeOH)2] (2), [Mn18O14(O2CMe)18(hmp)4(hmpH)2(H2O)2] (3) and [Mn18O14(O2CEt)18(hmp)4(hmpH)2(H2O)2] (4). All complexes 1-4 are mixed-valent (II/III). Complex 1 is a new member of a growing family of heptanuclear clusters with a core consisting of six Mn ions arranged in a ring around a seventh central Mn2+ ion. Complexes 2, 3 and 4 are examples of high-nuclearity and high-symmetry Mn clusters with aesthetically pleasing structures and interesting magnetic properties.

Κυανικά ιόντα

2-Πυριδυλομεθανόλη

Μοριακός μαγνητισμός

546.541

Polynuclear manganese compounds

Mixed-valence clusters

Cyanate ions

2-(Hydroxymethyl)pyridine

Single-crystal X-ray crystallography

Molecular magnetism

Composés polynucléaires du manganèse avec ligands carboxylate pont, modèles d'enzymes redox. Insertion dans des supports mésostructurés. Étude de leurs propriétés magnétiques et de leur activité catalytique / Polynuclear manganese compounds with carboxylate bridging ligands models of redox enzymes. Insertion inside mesoporous supports. Study of their magnetic and catalytic properties

Escriche Tur, Luis

21 November 2016

L’objectif de cette thèse est la synthèse de composés de manganèse et de matériaux hybrides qui soient intéressants du point de vue bioinorganique et magnétique. Pour accomplir ce but, nous avons découpé la stratégie en trois étapes constituant les différents chapitres de ce manuscrit :(a) Synthèse et caractérisation des composés moléculaires de manganèse et l’étude de leurs propriétés magnétiques.Nous avons réussi à obtenir la structure cristalline des vingt-trois nouveaux composés de Mn de différentes nucléarités, d’état d’oxydation II, III ou IV. Nous avons étudié les propriétés magnétiques de ces composés et nous avons établi des corrélations magnéto-structurales. Les composés de MnII ont été aussi étudiés par spectroscopie RPE.(b) Synthèse et caractérisation des matériaux hybrides basés sur des composés moléculaires de manganèse insérés dans de la silice mésoporeuse. Les composés moléculaires sélectionnés ont été insérés dans de la silice mésoporeuse (du type MCM-41). Les complexes de Mn dans les supports ont été caractérisés par ATG, XPS, ICP-OES, spectroscopie IR et mesures magnétiques. (c) Étude des propriétés catalytiques des composés moléculaires et des matériaux hybrides.Une famille de composés moléculaires obtenus dans cette thèse sont des modèles structuraux et fonctionnels de la catalase à Mn, une enzyme présente dans certaines bactéries, ayant des propriétés antioxydantes (H2O2 « scavenger »). L’activité catalase pour ces composés et les matériaux hybrides dérivés a été étudiée dans l’acétonitrile et dans l’eau. / The main objective of this work is the synthesis of manganese compounds and hybrid materials that may be relevant from a bioinorganic and magnetic point of view. The developed strategy comprises three main steps that form different sections in this thesis:(a) Synthesis and characterization of molecular manganese compounds and study of the magnetic propertiesThe crystal structure of twenty-three new Mn compounds of different nucleartities were obtained in which the Mn oxidation state is II, III, or IV. The magnetic properties of all these compounds were profoundly studied and they have been rationalized with their structural and electronic parameters. The MnII compounds were also studied with EPR spectroscopy. (b) Synthesis and characterization of hybrid materials based on molecular manganese compounds inside mesoporous silica.Selected molecular compounds were inserted inside mesoporous silica (MCM-41 type). The Mn complexes inside the supports were characterized with TGA, XPS, ICP-OES, IR spectroscopy, and magnetic measurements.(c) Study of the catalytic properties of both molecular compounds and hybrid materials.A family of the molecular compounds obtained in this work are structural and functional models of the Mn catalase, an enzyme found in some bacteria with antioxidant properties (H2O2 scavenger). The catalase activity for these compounds and the hybrid materials was studied in acetonitrile and water.

Magnétisme moléculaire

Composé de coordination

Catalyse

Silice mesoporeuse

Manganèse composé

Activité catalase

Ingénierie de surface

Molecular magnetism

Coordination chemistry

Catalysis

Mesoporous silica

Manganese compounds

Catalase activity

Surface engineering

Cation deficiency in lanthanum manganites

Berenov, Andrey Valdimirovich

January 1999

No description available.

546