- M E S KVM College Valanchery.
... Dimers of AlMe3 possess delocalized Al–C–Al bonding interactions The bonding in Al2Me4Cl2 can be described in terms of a localized scheme In Al2Ph4(μ-C≡CPh)2, the bridge bonds can be described in a similar way to those in Al2Me4(μ-Ph)2 Al2{CH(SiMe3)2}4 contains an Al–Al bond ...
... Dimers of AlMe3 possess delocalized Al–C–Al bonding interactions The bonding in Al2Me4Cl2 can be described in terms of a localized scheme In Al2Ph4(μ-C≡CPh)2, the bridge bonds can be described in a similar way to those in Al2Me4(μ-Ph)2 Al2{CH(SiMe3)2}4 contains an Al–Al bond ...
BSc-Chemistry-II
... Nomenclature, structure and bonding, physical properties, acidity of carboxylic acids, effects of substituents on acid strength. Preparation of carboxylic acids. Reactions of carboxylic acids. Hell-Volhard-Zelinsky reaction. Reduction of carboxylic acids. Mechanism of decarboxylation, esterificatio ...
... Nomenclature, structure and bonding, physical properties, acidity of carboxylic acids, effects of substituents on acid strength. Preparation of carboxylic acids. Reactions of carboxylic acids. Hell-Volhard-Zelinsky reaction. Reduction of carboxylic acids. Mechanism of decarboxylation, esterificatio ...
alcohols-II-12-ques
... Na2Cr2O7/H2SO4 followed by treatment with CH3OH, H2SO4 the product isolated is: ...
... Na2Cr2O7/H2SO4 followed by treatment with CH3OH, H2SO4 the product isolated is: ...
91391 Demonstrate understanding of the properties of organic
... evaluating or comparing and contrasting the links between the structure, functional groups, physical properties and/or reactivity of organic compounds. This requires the consistent use of chemistry vocabulary, symbols, and conventions. ...
... evaluating or comparing and contrasting the links between the structure, functional groups, physical properties and/or reactivity of organic compounds. This requires the consistent use of chemistry vocabulary, symbols, and conventions. ...
SN1 vs. SN2 Reactions - Master Organic Chemistry
... Look for halogens (Cl, Br, I) or tosylates/mesylates (OTs, OMs) Alternatively, look for alcohols (OH) if acid is present Once you've identified the leaving group, instpect the carbon it is attached to. How many carbons is that carbon connected to? That will tell you if the carbon is primary, seconda ...
... Look for halogens (Cl, Br, I) or tosylates/mesylates (OTs, OMs) Alternatively, look for alcohols (OH) if acid is present Once you've identified the leaving group, instpect the carbon it is attached to. How many carbons is that carbon connected to? That will tell you if the carbon is primary, seconda ...
PowerPoint **
... Under basic conditions, carbonyl compounds are electrophilic at carbonyl C and nuclephilic at α C’s. ...
... Under basic conditions, carbonyl compounds are electrophilic at carbonyl C and nuclephilic at α C’s. ...
Document
... • In addition reactions, reactants are added to the carbon atoms in the double or triple bond. • The double or triple bond is easily broken, since it is highly reactive. • In an addition reaction, new groups H and Br are added to the starting material. • A bond is broken and two bonds are formed ...
... • In addition reactions, reactants are added to the carbon atoms in the double or triple bond. • The double or triple bond is easily broken, since it is highly reactive. • In an addition reaction, new groups H and Br are added to the starting material. • A bond is broken and two bonds are formed ...
Document
... A functional group is the site of most chemical reactivity of a molecule Alkanes do not have a functional groups a) Alkyl group (R-): obtained by removing a hydrogen atom from an alkane (CnH2n+2): ...
... A functional group is the site of most chemical reactivity of a molecule Alkanes do not have a functional groups a) Alkyl group (R-): obtained by removing a hydrogen atom from an alkane (CnH2n+2): ...
Click on image to content
... a unique fashion, which is usually the site of chemical reactivity in an organic molecule. For Example - The hydroxyl group in ethanol (C2H5–OH) is known as a functional group. The functional group in ethene is , and in ethyne, it is – C ≡ C – . Thus, we see that the properties of a compound dep ...
... a unique fashion, which is usually the site of chemical reactivity in an organic molecule. For Example - The hydroxyl group in ethanol (C2H5–OH) is known as a functional group. The functional group in ethene is , and in ethyne, it is – C ≡ C – . Thus, we see that the properties of a compound dep ...
Alkenes undergo Addition Reactions Predict the product of each
... This hormone is made from a triene. What is the structure of the triene? What are the reaction conditions? 2. Write structural formulas for all the alkene products that could reasonably be formed from the following compound under the indicated reaction conditions. Where more than one alkene is produ ...
... This hormone is made from a triene. What is the structure of the triene? What are the reaction conditions? 2. Write structural formulas for all the alkene products that could reasonably be formed from the following compound under the indicated reaction conditions. Where more than one alkene is produ ...
Problem Set Chapter 13 Solutions February 28, 2013 13.27 Draw
... 13.50 How would you prepare the following substances from cyclopentanol? More than one step may be required. (a) Cyclopentanone (b) Cyclopentene (c) 1-Methylcyclopentanol (d) trans-2-Methylcyclopentanol ...
... 13.50 How would you prepare the following substances from cyclopentanol? More than one step may be required. (a) Cyclopentanone (b) Cyclopentene (c) 1-Methylcyclopentanol (d) trans-2-Methylcyclopentanol ...
Unit 9 The p-Block Elements
... When halogens react with other elements, they can complete their octet by either gaining an additional electron to form the halide ion, or by sharing their p electron to form a covalent bond, depending on the electronegativity of the atom with which the halogen is bonded. Ionic bonding All the Group ...
... When halogens react with other elements, they can complete their octet by either gaining an additional electron to form the halide ion, or by sharing their p electron to form a covalent bond, depending on the electronegativity of the atom with which the halogen is bonded. Ionic bonding All the Group ...
Carboxylic acids Acyl chlorides Amides Esters
... is a species attracted to a positive charge. is a species carrying a negative charge or a lone pair of electrons Examples: OH¯(aq), H2O and NH3(alc). R-X(l) + OH¯(aq) R-OH + X¯(aq) R-X(l) + NH3(alc) R-NH2 + HX(alc) - amine ; For NH3 to act as a nucleophile it must be dissolved in alcohol, ...
... is a species attracted to a positive charge. is a species carrying a negative charge or a lone pair of electrons Examples: OH¯(aq), H2O and NH3(alc). R-X(l) + OH¯(aq) R-OH + X¯(aq) R-X(l) + NH3(alc) R-NH2 + HX(alc) - amine ; For NH3 to act as a nucleophile it must be dissolved in alcohol, ...
Functional Groups
... the shape and flexibility of organic molecules. In the case of alkane molecules, the molecular structure is based on tetrahedral units and the molecular dynamics is the consequence of relatively free rotations about the carbon-carbon single bonds. These rotations give rise to different conformations ...
... the shape and flexibility of organic molecules. In the case of alkane molecules, the molecular structure is based on tetrahedral units and the molecular dynamics is the consequence of relatively free rotations about the carbon-carbon single bonds. These rotations give rise to different conformations ...
CHEM 109A CLAS Alkenes and Reactions of
... Reactions of Alkenes – See also Summary of Reactions of Alkenes Page 4 of 6 ...
... Reactions of Alkenes – See also Summary of Reactions of Alkenes Page 4 of 6 ...
1.2 The Chemicals of Life - Father Michael McGivney
... Hydrocarbons • Nonpolar and form straight or branched chains and ring shaped structures. • Names reflect the number of carbons, the number and location of any double or triple bonds and any functional groups. • Names based on the number of carbons in the longest carbon chain: 1 carbon......meth 2 c ...
... Hydrocarbons • Nonpolar and form straight or branched chains and ring shaped structures. • Names reflect the number of carbons, the number and location of any double or triple bonds and any functional groups. • Names based on the number of carbons in the longest carbon chain: 1 carbon......meth 2 c ...
diazonium salt
... Bonding system: only resonance structures, there is no classical Lewis-Langmuir formula LCAO-MO description: Three centred bond with four electrons Its reactions can be derived from its resonance structure ...
... Bonding system: only resonance structures, there is no classical Lewis-Langmuir formula LCAO-MO description: Three centred bond with four electrons Its reactions can be derived from its resonance structure ...
Carboxylic Acids
... Electron withdrawing groups can increase acid strength by weakening the OH bond and stabilizing the acid anion. The positive inductive effect of E-groups is very small through more than two or three carbon-carbon bonds. Electron donating groups reduce the partially positive charge of carboxyl carbon ...
... Electron withdrawing groups can increase acid strength by weakening the OH bond and stabilizing the acid anion. The positive inductive effect of E-groups is very small through more than two or three carbon-carbon bonds. Electron donating groups reduce the partially positive charge of carboxyl carbon ...
CARBON COMPOUNDS - SMK Raja Perempuan Ipoh
... Worksheet 2 : ALKANE a) Complete the table below. ...
... Worksheet 2 : ALKANE a) Complete the table below. ...
Alkenes
... The -orbital in alkenes is a centre of high electron density which is readily polarisable. This means that alkenes will be reactive towards reagents which are electron deficient; these are known as electrophiles. ELECTROPHILES are ELECTRON PAIR ACCEPTORS. They are particles which have centres of lo ...
... The -orbital in alkenes is a centre of high electron density which is readily polarisable. This means that alkenes will be reactive towards reagents which are electron deficient; these are known as electrophiles. ELECTROPHILES are ELECTRON PAIR ACCEPTORS. They are particles which have centres of lo ...
Option G Further Organic Chemistry
... SL students study the core of these options and HL students study the whole option (the core and the extension material). TOK: The relationship between a reaction mechanism and the experimental evidence to support it could be discussed. See 16.2.2. Core material: G1–G8 are core material for SL and H ...
... SL students study the core of these options and HL students study the whole option (the core and the extension material). TOK: The relationship between a reaction mechanism and the experimental evidence to support it could be discussed. See 16.2.2. Core material: G1–G8 are core material for SL and H ...
Haloalkane
The haloalkanes (also known, as halogenoalkanes or alkyl halides) are a group of chemical compounds derived from alkanes containing one or more halogens. They are a subset of the general class of halocarbons, although the distinction is not often made. Haloalkanes are widely used commercially and, consequently, are known under many chemical and commercial names. They are used as flame retardants, fire extinguishants, refrigerants, propellants, solvents, and pharmaceuticals. Subsequent to the widespread use in commerce, many halocarbons have also been shown to be serious pollutants and toxins. For example, the chlorofluorocarbons have been shown to lead to ozone depletion. Methyl bromide is a controversial fumigant. Only haloalkanes which contain chlorine, bromine, and iodine are a threat to the ozone layer, but fluorinated volatile haloalkanes in theory may have activity as greenhouse gases. Methyl iodide, a naturally occurring substance, however, does not have ozone-depleting properties and the United States Environmental Protection Agency has designated the compound a non-ozone layer depleter. For more information, see Halomethane. Haloalkane or alkyl halides are the compounds which have the general formula ″RX″ where R is an alkyl or substituted alkyl group and X is a halogen (F, Cl, Br, I).Haloalkanes have been known for centuries. Chloroethane was produced synthetically in the 15th century. The systematic synthesis of such compounds developed in the 19th century in step with the development of organic chemistry and the understanding of the structure of alkanes. Methods were developed for the selective formation of C-halogen bonds. Especially versatile methods included the addition of halogens to alkenes, hydrohalogenation of alkenes, and the conversion of alcohols to alkyl halides. These methods are so reliable and so easily implemented that haloalkanes became cheaply available for use in industrial chemistry because the halide could be further replaced by other functional groups.While most haloalkanes are human-produced, non-artificial-source haloalkanes do occur on Earth, mostly through enzyme-mediated synthesis by bacteria, fungi, and especially sea macroalgae (seaweeds). More than 1600 halogenated organics have been identified, with bromoalkanes being the most common haloalkanes. Brominated organics in biology range from biologically produced methyl bromide to non-alkane aromatics and unsaturates (indoles, terpenes, acetogenins, and phenols). Halogenated alkanes in land plants are more rare, but do occur, as for example the fluoroacetate produced as a toxin by at least 40 species of known plants. Specific dehalogenase enzymes in bacteria which remove halogens from haloalkanes, are also known.