Coordination Chemistry

... each other. It is the electron pair on the slightly negative C that is donated to the metal atom]. The metal eg orbitals are usually empty, but lie along the interuclear axis (d x2-y2 and dz2). These orbitals overlap with the sp-hybrid orbital of a ligand like CO, or the px orbital of ligands like C ...

ppt

... • They are different molecules with different properties. • They are enantiomers (nonsuperimposable mirror images). ...

CARBON AND ITS COMPOUNDS

Gmelin Tips and Reminders

Chapter 2 Notes

... • However, when two carbon atoms are joined by a double bond, the molecule has a Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings ...

Summary of AS-level Paper 2 content - A

... I can explain that chlorine atoms are formed in the upper atmosphere when ultraviolet radiation causes C–Cl bonds in chlorofluorocarbons (CFCs) to break, and that these chlorine atoms catalyse the decomposition of ozone and contribute to the hole in the ...

STRUCTURAL ISOMERISM

... the same molecule. What are structural isomers? In structural isomerism, the atoms are arranged in a completely different order. This is easier to see with specific examples. What follows looks at some of the ways that structural isomers can arise. The names of the various forms of structural isomer ...

Group 13 Compounds - University of Ottawa

... There are three available oxidation states for the group 13 compounds, represented by the basic formulae: R3M – where M(III) is any metal in the group. This is by far the most common organometallic species for group 13. R2M-MR2 – M(II) with a homonuclear bond. Not common. RM: – M(I) accessible due t ...

Chem 331 Biochemistry

... learn the structures of selected saccharides. I think it important to know what forces stabilize the complex sugars and some of the chemistry. Much of the stereochemistry is a repeat of what you’ve already learned in organic chemistry so much of this is review and isn’t a key part of what we will go ...

Reactions of Carbonyl compounds

... Use ...

Topic 20 specification content - A

... I can use 1H NMR and 13C NMR spectra and chemical shift data from the Chemistry Data Booklet to suggest possible structures or part structures for molecules, use integration data from 1H NMR spectra to determine the relative numbers of equivalent protons in the molecule and use the n+1 rule to deduc ...

Wade slides Chapter 7

... Heteroatoms • Halogens replace hydrogen atoms in hydrocarbons, so when calculating unsaturations, count halides as hydrogen atoms. • Oxygen does not change the C:H ratio, so ignore oxygen in the formula. • Nitrogen is trivalent, so it acts like half a carbon. Add the number of nitrogen atoms when ca ...

L 26 Hydrocarbons

... important ingredients in medicines and in dyes. Petroleum and coal are the major sources of various types of hydrocarbons. The products obtained from fractional distillation of petroleum and destructive distillation of coal are used almost in every sphere of life. Hydrocarbons are considered to be t ...

Bio 2 alkanes+isomerism

Phy Properties - Rosebank Progress College

... Alkanes, alkenes and alkynes all have densities less than 1g.cm-1 and are therefore less dense than water. All three groups consists of non-polar molecules which are very soluble in non-polar solvents like tetrachloromethane and benzene, but insoluble in polar solvents like water. ...

File

... Be able to use the n +1 rule to deduce the spin– spin splitting patterns of adjacent, non-equivalent protons, limited to doublet, triplet and quartet formation in simple aliphatic compounds Know that gas-liquid chromatography can be used to separate mixtures of volatile liquids ...

1.7 FUNCTIONAL GROUPS

... Certain combinations of bonds show up repeatedly in organic chemistry and organic chemists give those bonding combinations specific names. It is very useful to know the names of those specific types of bonds. Examples are shown below and you should make flash cards and learn them by heart. There can ...

C h e m g u id e –... ACID ANHYDRIDES: REACTIONS WITH WATER, ALCOHOLS AND PHENOLS

... and so the top group in your target molecule must come from an acid anhydride, but a bigger one than ethanoic anhydride. You can ignore the other group on the ring as just a distraction. You haven’t come across any reaction which would attach a group like this to a benzene ring, so it must have been ...

Alcohols

... carbon atom it is primary; two other carbon atoms – secondary and three carbon atoms – tertiary. Properties of Alcohols  The hydroxyl group in an alcohol is polar therefore hydrogen bonding occurs.  “Like dissolves Like” therefore these molecules are soluble in other polar solvents. However, in lo ...

Chemistry of Carbon - Churchill High School

... attachment of different functional groups interact with different targets in the body  different effects ...

Activity 1: Chapter 1: Carbon Compounds and Chemical Bonds

J. Org. Chem. 2001, 66, 1672

... system, we attempted to apply this methodology to the direct exhaustive reduction of the aliphatic carboxylic function. It was anticipated that a carboxylic acid 5 in the presence of the B(C6F5)3 catalyst would react with 4 equiv of HSiEt3 in a stepwise fashion to produce a hydrocarbon 3 via the int ...

4.6, 4.7 test - A

CHEM 212B, Organic Chemistry - City College of San Francisco

... A continuation of CHEM 212A. The second semester of a one-year course in organic chemistry for students who major in chemistry, biochemistry, and other chemistry-intensive sciences. IV. MAJOR LEARNING OUTCOMES Upon completion of this course a student will be able to: A. Name and draw the structures ...

CHAPTER 10 CHEMICAL BONDING II: MOLECULAR GEOMETRY

... The Lewis structure of PCl3 is shown below. Since in the VSEPR method the number of bonding pairs and lone pairs of electrons around the central atom (phosphorus, in this case) is important in determining the structure, the lone pairs of electrons around the chlorine atoms have been omitted for simp ...

< 1 ... 44 45 46 47 48 49 50 51 52 ... 141 >

Aromaticity

In organic chemistry, the term aromaticity is formally used to describe an unusually stable nature of some flat rings of atoms. These structures contain a number of double bonds that interact with each other according to certain rules. As a result of their being so stable, such rings tend to form easily, and once formed, tend to be difficult to break in chemical reactions. Since one of the most commonly encountered aromatic system of compounds in organic chemistry is based on derivatives of the prototypical aromatic compound benzene (common in petroleum), the word “aromatic” is occasionally used to refer informally to benzene derivatives, and this is how it was first defined. Nevertheless, many non-benzene aromatic compounds exist. In living organisms, for example, the most common aromatic rings are the double-ringed bases in RNA and DNA.The earliest use of the term “aromatic” was in an article by August Wilhelm Hofmann in 1855. Hofmann used the term for a class of benzene compounds, many of which do have odors (unlike pure saturated hydrocarbons). Today, there is no general relationship between aromaticity as a chemical property and the olfactory properties of such compounds, although in 1855, before the structure of benzene or organic compounds was understood, chemists like Hofmann were beginning to understand that odiferous molecules from plants, such as terpenes, had chemical properties we recognize today are similar to unsaturated petroleum hydrocarbons like benzene.In terms of the electronic nature of the molecule, aromaticity describes the way a conjugated ring of unsaturated bonds, lone pairs of electrons, or empty molecular orbitals exhibit a stabilization stronger than would be expected by the stabilization of conjugation alone. Aromaticity can be considered a manifestation of cyclic delocalization and of resonance. This is usually considered to be because electrons are free to cycle around circular arrangements of atoms that are alternately single- and double-bonded to one another. These bonds may be seen as a hybrid of a single bond and a double bond, each bond in the ring identical to every other. This commonly seen model of aromatic rings, namely the idea that benzene was formed from a six-membered carbon ring with alternating single and double bonds (cyclohexatriene), was developed by August Kekulé (see History section below). The model for benzene consists of two resonance forms, which corresponds to the double and single bonds superimposing to produce six one-and-a-half bonds. Benzene is a more stable molecule than would be expected without accounting for charge delocalization.

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Aromaticity