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HYDROCARBONS. Hydrocarbons are composed, as their name suggests mainly of carbon and hydrogen atoms, though some types have oxygen, nitrogen or sulphur atoms. Hydrocarbons are divided into two groups, Aliphatics or Aromatics. Most hydrocarbons are aliphatics . . Representing Hydrocarbon.
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Hydrocarbons are composed, as their name suggests mainly of carbon and hydrogen atoms, though some types have oxygen, nitrogen or sulphur atoms. • Hydrocarbons are divided into two groups, Aliphatics or Aromatics. Most hydrocarbons are aliphatics.
Representing Hydrocarbon • There are four ways in which hydrocarbons can be represented. • 1. Chemical Formula We are used to using chemical formulas to represent compounds. Unfortunately, chemical formulas are not useful when dealing with organic molecules because the arrangement of the atoms within the molecule is important. This can be seen with the sugars glucose and fructose.
2. Structural formulas are very useful and important in organic chemistry. A structural formula shows both the type and arrangement of the elements and all bonds.
3. Condensed formulas show major bonds but normal C to H bonds are not drawn. • CH3CH2CH2CH2CH3 • 4. Line diagrams represent the molecule using lines. The end of a line means CH3 while a corner is CH2
ALKANES • Alkanes area class of HYDROCARBONS which contain only carbon and hydrogen. Two other terms which describe alkanes are saturated and paraffins. • Alkanes are SATURATED which means that each carbon is bonded to four other atoms through single covalent bonds. Hydrogen atoms usually occupy all available bonding positions after the carbons have bonded to each other. • PARAFFINS which is derived from a Latin word meaning "little activity", and means that the compounds are very unreactive. • The general structure is CnH2n+2
Properties Physical Properties Chemical Reactivity No functional groups, saturated, and class name of paraffins which means - Unreactive to other chemicals. All compounds: Combustion Reaction • Boiling points depend on chain length. The longer the chain the higher the boiling temperature • Non polar • Insoluble in water
ROOT ALKANE NAMES • Root names give the number of carbons in the longest continuous chain. Root names are used with various "endings" to indicate branches, type of bonds between carbons, and functional groups. • The following list gives the most basic root the with normal hydrocarbon alkane endings for the number of carbons in the longest continuous chain. Memorize this list. • Example: root = "eth" + alkane ending = "ane" = ethane
Cycloalkanes • Cycloalkanescontain a carbon chain that is in the form of a ring. Each cycloalkane has a formula that is 2H less than the corresponding alkane. For example, propane is C3H8 whereas cyclopropaneis C3H6. Butane is C4H10 and cyclobutane is C4H8. The names of the cyclic structures use the prefix cycloin from of the alkane name for the carbon chain. Timberlake LecturePLUS 1999
Cycloalkanes Cyclopropane CH2 CH2 CH2 Cyclobutane CH2 CH2 CH2 CH2 Timberlake LecturePLUS 1999
More Cycloalkanes Cyclopentane CH2 CH2 CH2 CH2 CH2 Cyclohexane CH2 CH2 CH2 CH2 CH2 CH2 Timberlake LecturePLUS 1999
Naming Cycloalkanes with Side Groups Number of Naming side groups One Side group name goes in front of the cycloalkane name. Two Number the ring in the direction that gives the lowest numbers to the side groups and add the number to the name. Timberlake LecturePLUS 1999
Cycloalkanes with Side Groups Timberlake LecturePLUS 1999
ISOMERS • Isomers are compounds which have the same formula but have different forms. Some isomers are known as Structural Isomers because they have a completely different atomic arrangement, while others are called Geometric Isomers because of the spacial arrangement.
Isomers of C4H10 Butane 2-Methylpropane
Reaction of Alkanes • Alkanes are very unreactive in most cases. The exceptions are Combustion and Halogenation. • Alkanes readily react with oxygen in combustion reactions to form carbon dioxide and water. The shorter chain alkanes are the ones which we normally think of as fuel such as Methane (natural gas), propane for bbqs, butane for lighters and octane for the car.
Halogenation involves the reaction of the alkane with a halogen such as F2, Cl2, Br2, or I2. • The product is an alkyl halide in which a H is replaced by a halogen atom. If the halogen is in excess the reaction contiunes until all H are replaced.
CH4 + F2 → CH3F + HF Fluromethane • CH3F + F2 → CH2F2 + HF Difluoromethane • CH2F2 + F2 → CHF3 + HF Trifluoromethane • CHF3 + F2 → CF4 + HF carbon tetrafluoride