Hydrocarbon Compounds - By Razi

(C4H10)

(C4H10)

Hydrocarbons 

OBJECTIVES:

Describe the relationship  between number of valence electrons and bonding in carbon.

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Hydrocarbons 

OBJECTIVES: 

Define and describe alkanes.

Hydrocarbons 

OBJECTIVES: 

Relate the polarity of  hydrocarbons to their  solubility.

Organic Chemistry and Hydrocarbons “Organic” originally referred to any chemicals that came from organisms  1828 - German chemist Friedrich Wohler synthesized urea in a lab  Today, organic chemistry is the chemistry of virtually all compounds containing the element carbon 

Friedrich Wohler  1800  – 1882 Used

inorganic substances to synthesize urea, a carbon compound found in urine. This

re-defined organic chemistry.

Organic Chemistry and Hydrocarbons Over a million organic compounds, with a dazzling array of properties  Why so many? Carbon’s unique  bonding ability!  Let’s start with the simplest of the organic compounds. These are the Hydrocarbons 

Organic Chemistry and Hydrocarbons 

Hydrocarbons contain only two elements: 1) hydrogen, and 2) carbon 

simplest hydrocarbons called “alkanes”, which contain only carbon to carbon single covalent bonds (CnH2n+2)

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methane (CH4) with one carbon is the simplest alkane. It is the major component of natural gas

Organic Chemistry and Hydrocarbons  

Review structural formulas - p.694 Carbon has 4 valence electrons, thus forms 4 covalent bonds 

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not only with other elements, but also forms bonds WITH ITSELF (nonpolar)

Ethane (C2H6) is the simplest alkane with a carbon to carbon bond

Straight-Chain Alkanes Straight-chain alkanes contain any number of carbon atoms, one after  the other , in a chain pattern meaning one linked to the next (not  always straight ) C-C-C C-C-C-C etc.  Names of alkanes always will always end with -ane 

Straight-Chain Alkanes 

Combined with the -ane ending is a prefix for the number of carbons 

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Table 22.1, page 695

Homologous series- a group of  compounds that have a constant increment of change In alkanes, it is: -CH2- (methylene)

Straight-Chain Alkanes 

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Many alkanes used for fuels: methane,  propane, butane, octane As the number of carbons increases, so does the boiling and melting pt. 

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The first 4 are gases; #5-15 are liquids; higher alkanes are solids

Condensed structural formulas? Note examples on page 696

Naming Straight-Chain Alkanes 

 Names recommended by IUPAC - the International Union of Pure and A pplied Chemistry 

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end with – ane; the root part of the name indicates the # of carbons

We sometimes still rely on common names, some of which are well-known

Naming Straight-Chain Alkanes IUPAC names may be long and cumbersome  Common names may be easier or  more familiar, but usually do not describe the chemical structure!  Methane is natural gas or swamp gas 

Branched-Chain Alkanes 

Branched-chain means that other  elements besides hydrogen may be attached to the carbon  halogens, oxygen, nitrogen, sulfur, and even other carbons  any atom that takes the place of a hydrogen on a parent hydrocarbon is called a substituent   , or the branched  part

Branched-Chain Alkanes 

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A hydrocarbon substituent is called an alkyl group or sometimes radicals  use the same prefixes to indicate the number of carbons, but -ane ending is now -yl such as: methyl, ethyl,  propyl, etc. Gives much more variety to the organic compounds

Branched-Chain Alkanes 

Rules for naming – go from right to left - page 698

1. Longest C-C chain is parent 2. Number so branches have lowest # 3. Give position number to branch 4. Prefix (di, tri) more than one branch 5. Alphabetize branches (not prefix) 6. Use proper punctuation ( - and , )

- Page 699

Branched-Chain Alkanes 

From the name, draw the structure, in a right-to-left manner:

1. Find the parent, with the -ane 2. Number carbons on parent 3. Identify substituent groups (give lowest number); attach 4. Add remaining hydrogens

- Page 700

Alkanes 

Draw 3-ethylpentane

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Draw 2,3,4-trimethylhexane

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Since the electrons are shared equally, the molecule is nonpolar  

thus, not attracted to water 

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oil (a hydrocarbon) not soluble in H2O

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“like dissolves like”

Section 22.2 Unsaturated Hydrocarbons 

OBJECTIVES:

Describe the difference  between unsaturated and saturated hydrocarbons.

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Section 22.2 Unsaturated Hydrocarbons 

OBJECTIVES: 

Distinguish the structures of  alkenes and alkynes.

Alkenes  Multiple bonds can also exist  between the carbon atoms  Hydrocarbons containing carbon to carbon double bonds are called alkenes (CnH2n) C=C CC=C  Called “unsaturated” if they contain double or triple bonds

Naming Alkenes 

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Find longest parent that has the double  bond in it  New ending: -ene  Number the chain, so that the double  bond gets the lower number   Name and number the substituents Samples on page 702

Alkynes  Hydrocarbons containing carbon to carbon triple bonds are called alkynes ethyne (CnH2n-2) -C C Alkynes are not plentiful in nature  Simplest is ethyne- common name acetylene (fuel for torches)  Table 22.3, p. 703 for boiling pt.

Section 22.3 Isomers 

OBJECTIVES:

Explain why structural isomers have different  properties.

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Section 22.3 Isomers 

OBJECTIVES:

Describe the conditions under  which geometric isomers are  possible.

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Section 22.3 Isomers 

OBJECTIVES: 

Identify optical isomers.

Structural Isomers Compounds that have the same molecular formula, but different molecular structures, are called structural isomers  Butane and 2-methylpropane (made by  breaking carbon off the end, and making it a branch in the middle)  Also have different properties, such as  b.p., m.p., and reactivity 

Structural Isomers of Butane, C4H10

Stereoisomers 

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Don’t forget that these structures are really 3-dimensional stereoisomers- molecules of the same molecular structure that differ only in the arrangement of the atoms in space. Two types are a) geometric and b) optical

Geometric Isomers 

There is a lack of rotation around a carbon to carbon multiple bond 

has an important structural implication

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Two possible arrangements: 1. trans configuration - substituted groups on opposite sides of double  bond 2. cis configuration - same side

Geometric Isomers

Trans-2-butene

Substituted groups are on the same side of the double bond (in this case, both are above)

Substituted groups are on opposite sides of the double bond (in this case, one is above, the other  is below)

Cis-2-butene

Geometric Isomers 

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Trans-2-butene and Cis-2-butene shown on page 705 differ in the geometry of the substituted groups (to double bond) like other structural isomers, have different physical and chemical properties ( note page 705-middle)

Optical Isomers 

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Asymmetric carbon? C with 4 different groups attached. Conceptual Problem 22.4, p.706

Molecules containing asymmetric carbons have “handedness”, and exist as stereoisomers. 

Figure 22.9, page 705

Optical Isomers, and these will each show an asymetric carbon (4 different branches attached) The asymetric carbon

Section 22.4 Hydrocarbon Rings 

OBJECTIVES: 

Identify cyclic ring structures.

Section 22.4 Hydrocarbon Rings 

OBJECTIVES: 

Describe bonding in benzene.

Cyclic Hydrocarbons 

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The two ends of the carbon chain are attached in a ring in a cyclic hydrocarbon 

sample drawings on page 709

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named as “cyclo- ____”

hydrocarbon compounds that do NOT contain rings are known as aliphatic compounds

Aromatic Hydrocarbons 

A special group of unsaturated cyclic hydrocarbons is known as arenes  

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contain single rings, or groups of rings also called “aromatic hydrocarbons”, because of pleasant odor  simplest aromatic is benzene (C6H6) Term “aromatic” applies to materials with  bonding like that of benzene

Aromatic Hydrocarbons 

Benzene is a six-carbon ring, with alternating double and single  bonds 

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exhibits resonance, due to location of  the double and single bonds-p.710

Benzene derivatives possible: 

methylbenzene, 3-phenylhexane, ethylbenzene (top page 711)

Aromatic Hydrocarbons 

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One derivative of Benzene is called phenylethene, or commonly named STYRENE. Foamed styrene is trademarked by Dow Chemical as “styrofoam” CH2

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Other manufacturers items usually  just called “foam cups”

CH

Aromatic Hydrocarbons 

Benzene derivatives can have two or  C more substitutents: 

1,2-dimethylbenzene

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1,3-dimethylbenzene

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1,4-dimethylbenzene

C

C 

C

Can use ortho for 1,2; meta for 1,3; and  para for 1,4 (page 711)

Section 22.5 Hydrocarbons From Earth’s Crust

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OBJECTIVES: 

Identify three important fossil fuels and describe their  origins.

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Section 22.5 Hydrocarbons From Earth’s Crust

OBJECTIVES: 

Describe the composition of  natural gas, petroleum, and coal.

Section 22.5 Hydrocarbons From Earth’s Crust

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OBJECTIVES:

Describe what happens when  petroleum is refined.

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Natural Gas 

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Fossil fuels provide much of the world’s energy  Natural gas and petroleum contain mostly the aliphatic (or straight-chain) hydrocarbons – formed from marine life  buried in sediment of the oceans  Natural gas is an important source of  alkanes of low molecular mass

Natural Gas 

 Natural gas is typically:

80% methane, 10% ethane, 4%  propane, and 2% butane with the remainder being nitrogen and higher  molar mass hydrocarbons

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also contains a small amount of He, and is one of it’s major sources

Natural Gas 

 Natural gas is prized for combustion,  because with adequate oxygen, it burns with a hot, clean blue flame: 

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CH4 + 2O2  CO2 + 2H2O + heat

Incomplete burning has a yellow flame, due to glowing carbon parts, as well as making carbon monoxide

Petroleum 

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The compounds found in petroleum (or  crude oil) are more complex than those in natural gas Usually straight-chain and branchedchain alkanes, with some aromatic compounds also Crude oil must be refined (separated)  before being used

Petroleum 

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It is separated by distillation into fractions, according to boiling pt. Fractions containing higher molar mass can be “cracked” into more useful shorter chain components, such as gasoline and kerosene 

involves catalyst and heat

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starts materials for plastics and paints

Coal 

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From huge fern trees and mosses decaying millions of years ago under  great pressure of rocks / soil. Stages in coal formation:

1. Peat- soft, fibrous material much like decayed garden refuse; high water  content. After drying will make a lowcost, smoky fuel

Coal 2. Lignite- peat left in the ground longer, loses it’s fibrous texture, and is also called brown coal 

harder than peat; higher C content (50%); still has high water content

3. Bituminous, or soft coal- formed after  more time; lower water content, higher  C content (70-80%)

Coal 4. Anthracite, or hard coal 

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carbon content exceeding 80%, making it an excellent fuel source

Coal may be found close to the surface (strip-mined), or deep within the earth Pollutants from coal are common; soot and sulfur problems

BIG BRUTUS Dragline used to remove the overburden of a strip mining coal field near West Mineral, Kansas. Note the size of  the man standing next to it.

Coal 

Coal may be distilled for many products  

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coal gas, coal tar, coke, and ammonia further distilled into benzene, toluene, naphthalene, phenol- the aromatics Coke is almost pure carbon; produces intense heat and little or no smoke, thus used in industrial processes