Enos Kiremire Bücher

Die neue Clustertheorie wurde angewandt, um eine breite Palette chemischer Cluster zu analysieren und zu kategorisieren. Dazu gehören Cluster wie Borane, Metalloborane, Heteroborane, goldene Cluster, Zintl-Ionen, Matrjoschka-Cluster, Metallcarbonyl-Cluster und Kohlenwasserstoffe. Dieses Buch konzentriert sich auf die Analyse und Kategorisierung von chemischen Katalysatorclustern auf Metallbasis. Die Mehrzahl der Cluster gehört zu den Clan-Serien D1, D2, D5 und D6. Die meisten der bekannten industriellen Katalysatoren gehorchen entweder der 16- oder 18-Elektronen-Regel und sind monozentrisch. Es besteht die Möglichkeit, dass multizentrische Cluster ähnlicher Clan-Reihen katalytisch wirken könnten.

Die Untersuchung chemischer Cluster betont die zentrale Rolle von Skelettzahlen, die zur Zerlegung der Clusterformel in den K(n)-Parameter führen. Dieser Parameter ermöglicht die Extraktion von Valenzelektronen aus Clustern und unterstützt die Konstruktion isomerer Strukturen. Die Formel K = n + t beschreibt dabei die Beziehung zwischen Skelett-Elementen und internen Linien oder Dreiecken. Gut konstruierte Figuren ermöglichen die Ableitung isomerer Clusterstrukturen und stehen im Einklang mit dem Konzept der "Goodness of fit", was die geometrische Struktur der Cluster betrifft.

Die Entdeckung einer Ordnung innerhalb der Carbonyl-Cluster-Formeln eröffnet neue Perspektiven in der Chemie. Die Forschung identifiziert eine spezifische Reihe, die durch S = 4n + q definiert ist, und ermöglicht die Umwandlung von Clusterformeln in eine Kategorisierungsformel K* = Cy + Dz. Dabei repräsentiert Dz die Sippe und Cy die Familie der Cluster. Eine neu gefundene intrinsische Erzeugungsfunktion R = n (K -1) + 1 kann alle möglichen Fragmente und Cluster aus einem Vorläuferskelettfragment generieren, was sowohl bekannte als auch unbekannte stabile chemische Cluster umfasst.

The book delves into the intricate analysis of transition metal and main group element clusters, highlighting their adherence to specific mathematical series for categorization. It emphasizes the isolobal relationship between these series and introduces the capping theory, which evolves from skeletal numbers to precise calculations of cluster valence electrons (CVE). This theory is presented as a natural law governing chemical clusters, demonstrating its significance in accurately determining CVE and generating cluster formulas.

The study explores the unique behavior of chemical clusters formed by main group and transition elements, revealing a phenomenon known as double capping. It introduces a parameter, K*, to categorize clusters based on their skeletal elements, which evolve through three distinct types: growing, mature, and capping series. Mature clusters correspond to the Closo series, while capping series indicate the formation of nuclei that consist of one or more skeletal elements. Notably, golden clusters typically center around one or two skeletal elements, while palladium carbonyl clusters involve two or more.

This work explores the systematic organization of carbonyl clusters, revealing that they adhere to the formula S = 4n + q, where n is the number of skeletal elements. This insight led to the development of a categorization formula K* = Cy + Dz, distinguishing between cluster families and series clans. A significant breakthrough was the identification of an intrinsic generating function R = n (K -1) + 1, which can produce all possible fragments and clusters from a precursor, encompassing both known and unknown stable chemical structures.

Focusing on the analysis of transition metal carbonyl clusters, the book introduces a method for applying skeletal numbers to categorize these clusters. It distinguishes between skeletal numbers of individual elements and their linkages in clusters, while illustrating key relationships in empirical formulas. The text provides six fundamental equations for calculating cluster valence electrons and includes articles that utilize both skeletal numbers and the 4N series approach. Overall, it offers robust techniques for analyzing clusters in both main group and transition metal elements.

Focusing on the relationship between skeletal elements and valence electrons, this book explores a 4n-based series approach to understanding molecular geometry. It highlights how specific configurations, such as (6,86) and (6,26), lead to octahedral shapes in both transition metal carbonyls and main group elements. The text emphasizes that concepts like valency and the octet rule also apply to main group fragments, aligning them with transition metal clusters when masking electrons are considered. Previous articles provide a foundation for this extensive analysis.

The book presents a novel approach to analyzing and categorizing golden clusters through the 14N/4N method, showcasing its efficiency and precision. It begins with successful applications to osmium clusters before shifting focus to gold clusters, revealing their adherence to the 4N series principle. The study highlights the composition of clusters, often dominated by one or two elements, and introduces the concept of "black-hole" nuclei in certain clusters. Additionally, it incorporates graph theory to illustrate isomeric structures and ligand distributions around skeletal elements.

The book explores the historical development of number and cluster theory in chemical clusters, focusing on main group and transition metal elements. It details the progression from the 4N/14 Series to the establishment of cluster numbers and skeletal numbers. Key concepts include the categorization of clusters into CLAN and FAMILY series, the introduction of cluster valence equations, and the construction of isomeric structures using the K(n) parameter. Additionally, it highlights the dichotomous relationship within clusters, consisting of Cy and Dz components.