Saturated and unsaturated compounds

A saturated compound is a chemical compound (or ion) that resists addition reactions, such as hydrogenation, oxidative addition, and binding of a Lewis base. The term is used in many contexts and for many classes of chemical compounds. Overall, saturated compounds are less reactive than unsaturated compounds. Saturation is derived from the Latin word saturare, meaning 'to fill'. Unsaturated compounds generally carry out typical addition reactions that are not possible with saturated compounds such as alkanes. A saturated organic compound has only single bonds between carbon atoms. An important class of saturated compounds are the alkanes. Many saturated compounds have functional groups, e.g., alcohols. The concept of saturation can be described using various naming systems, formulas, and analytical tests. For instance, IUPAC nomenclature is a system of naming conventions used to describe the type and location of unsaturation within organic compounds. The "degree of unsaturation" is a formula used to summarize and diagram the amount of hydrogen that a compound can bind. Unsaturation can be determined by NMR, mass spectrometry and IR spectroscopy, or by determining a compound's bromine number or iodine number. Unsaturated fat The terms saturated vs unsaturated are often applied to the fatty acid constituents of fats. The triglycerides (fats) that comprise tallow are derived from the saturated stearic and monounsaturated oleic acids. Many vegetable oils contain fatty acids with one (monounsaturated) or more (polyunsaturated) double bonds in them. In organometallic chemistry, a coordinatively unsaturated complex has fewer than 18 valence electrons and thus is susceptible to oxidative addition or coordination of an additional ligand. Unsaturation is characteristic of many catalysts. The opposite of coordinatively unsaturated is coordinatively saturated. Complexes that are coordinatively saturated rarely exhibit catalytic properties. In physical chemistry, when referring to surface processes, saturation denotes the degree at which a binding site is fully occupied.

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Indice d'iode

vignette|Comme on peut le constater sur cette image, l'iode (le X) se fixe sur les doubles liaisons. L'indice d'iode d'un lipide est la masse de diiode (), exprimée en grammes, capable de se fixer sur les insaturations (doubles liaisons le plus souvent) des acides gras contenus dans cent grammes de matière grasse. L'indice d'iode d'un acide gras saturé est nul. Si la masse molaire de l'acide gras (déterminée par son indice d'acide) et son indice d'iode sont connus, le nombre de doubles liaisons peut être déterminé.

Addition oxydante

L'addition oxydante et l'élimination réductrice sont deux réactions importantes de la chimie organométallique. L'addition oxydante est un processus qui augmente le degré d'oxydation et le nombre de coordination du centre métallique du complexe qui réagit. Cette réaction est généralement une étape d'un cycle catalytique ; il en est de même de étape inverse : l'élimination réductrice. Il est impossible d'avoir une de ces deux réactions dans un cycle sans que l'autre ne soit présente, car il faut restaurer le degré d'oxydation ainsi que le nombre de coordination du centre métallique.

Dissociative substitution

In chemistry, dissociative substitution describes a reaction pathway by which compounds interchange ligands. The term is typically applied to coordination and organometallic complexes, but resembles the SN1 mechanism in organic chemistry. This pathway can be well described by the cis effect, or the labilization of CO ligands in the cis position. The opposite pathway is associative substitution, being analogous to SN2 pathway. Pathways that are intermediate between the pure dissociative and pure associative pathways are called interchange mechanisms.

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