Topic 10 & 20 - Organic chemistry

Question 1

WWhat are the features of a homologous series?

Answer 1

1. Same general formula
2. Neighbouring members differ by CH₂
3. Similar chemical properties
4. Gradation in physical properties

Question 2

What kind of a trend is there in the boiling points of a homologous series?

Answer 2

The boiling point increases with the number of -CH₂ groups

Question 3

Distinguish between empirical, molecular and structural formulas

Answer 3

An empirical formula shows the simplest whole number ratio of the atoms it contains

A molecular formula shows the actual number of atoms of each element present

A structural formula is one that shows unambiguously how the atoms are arranged together

Question 4

What are the three types of structural formulas?

Answer 4

A full structural formula shows every atom and bond in the compond

A condensed structural formula can omit bonds between atoms and can swho identical groups bracketed together for simplicity

A stereochemical formula attemps to show the relative positions of atoms and groups in three dimensions

Question 5

What are structural isomers?

Answer 5

Compounds with the same molecular formula with different arrangement of atoms

Question 6

What is the structural formula of an amine group and what is the suffix name of it?

Answer 6

–NH₂

–anamine

Primary, secondary, and tertiary amine, respectively:

Question 7

What is the structural formula of an amide group and what is the suffix name of it?

Answer 7

–CONH₂

–anamide

Primary amide:

Question 8

What is the structural formula of an ester group and what is the suffix name of it?

Answer 8

–COOC–

–anoate

Question 9

What is the structural formula of a nitrile group and what is the suffix name of it?

Answer 9

–CN

–ananetrile

Question 10

What is the structural formula of a ketone group and what is the suffix name of it?

Answer 10

–C–COC–

–anone

Question 11

What is the structural formula of an aldehyde group and what is the suffix name of it?

Answer 11

–CHO

–anal

Question 12

What is the structural formula of an alcohol group and what is the suffix name of it?

Answer 12

–OH

–anol

Question 13

What is the structural formula of an a carboxylic acid group and what is the suffix name of it?

Answer 13

–COOH

–anoic acid

Question 14

What is the difference between a *primary, secondary, *and tertiary atom?

Answer 14

A primary atom is attached to only one other carbon

A secondary atom is attached to two carbon atoms

A tertiary atom is attached to three carbon atoms

Question 15

What is the order of volatility of alcohols, halogenoalkanes, carboxylic acids, ketones, alkanes, and aldehydes?

Answer 15

From least volatile to most volatile:

carboxylic acid < alcohol < ketone < aldehyde < halogenoalkane < alkane

Question 16

Desribe the solubility in water of alcohols, halogenoalkanes, carboxylic acids, ketones, alkanes, and aldehydes

Answer 16

• Depends on the polarity of the functional group and on the chain length
• The lower members are all water soluble
• As the length of the non-polar hydrocarbon chain increases the solubility in water decreases

Question 17

Why do alkanes have low reactivity?

Answer 17

1. The C–C and C–H bonds have high bond enthalpies and are relatively strong
2. The C–C and C–H bonds are non-polar

Question 18

Describe, with example equations, the complete and incomplete combustion of alkanes

Answer 18

1. Complete combustion of alkanes produces carbon dioxide and water:

C₃H₈(g) + 5 O₂(g) → 3 CO₂(g) + 4 H₂O(g)

2. Incomplete combustion produces carbon monoxide and water:

2 C₃H₈(g) + 7 O₂(g) → 6 CO(g) + 8 H₂O(g)

3. Incomplete combustion when oxygen is extremely limited produces carbon and water:

C₃H₈(g) + 2 O₂(g) → 3 C(s) + 4 H₂O(g)

Question 19

What is a free radical?

Answer 19

An atom that contains an unpaired electron (no net charge) and is very reactive

Question 20

What is a substitution reaction?

Answer 20

When another reactant takes the place of a hydrogen atom in the alkane

Question 21

What is homolytic fission?

Answer 21

An event in which a bond breaks by splitting the shared pair of electrons between the two products producing two free radicals:

X:X → X· + X·

Question 22

What is the reaction between chlorine and methane?

Answer 22

CH₄(g) + Cl₂(g) → CH₃Cl(g) + HCl(g)

UV light is the required catalyst

Question 23

What are the three steps in the reaction mechanism?

Answer 23

1. Initiation
2. Propagation
3. Termination

Question 24

What happens in the initiation process of the reaction mechanism?

Answer 24

• Homolytic fission occurs
• Occurs in the presence of UV light

Question 25

What happens in the propagation process in the reaction mechanism?

Answer 25

• Free radicals are used and produced, allowing the reaction to continue (chain reaction)

Question 26

What happens in the termination process of the reaction mechanism?

Answer 26

• Free radicals are removed from the mixture by reacting them together and pair up electrons

Question 27

What are addition reactions?

Answer 27

A reaction in which a double bond is broken to add two hydrogens to a compound.

Question 28

Describe, with an equation, the reaction of alkenes with hydrogen

Answer 28

• Called hydrogenation
• Alkene goes through addition reaction
• Nickel catalyst and at 150°C

CH₃CHCH₂ + H₂ → CH₃CH₂CH₃

Question 29

Describe, using an equation the reaction of alkenes with halogens

Answer 29

• Forms dihalogeno compounds
• Happen quickly at room temperature
• Loss of colour of the halogen

CH₃CHCH₂ + Br₂ → CH₃CHBrCH₂Br

Question 30

Describe, using an equation, the reaction of alkenes with hydrogen halides

Answer 30

• Form halogenoalkanes
• React rapidly at room temperature

CH₂CH₂ + HCl → CH₃CH₂Cl

Question 31

Describe, using an equation, the reaction of alkenes with water

Answer 31

• Called hydration
• Converts the alkene into an alcohol
• Involves an intermediate
• Heat with steam and catalyst of concentrated H₂SO₄

CH₂CH₂ → CH₃CH₂(HSO₄) → CH₃CH₂OH + H₂SO₄

^{H₂SO₄catalyst H₂O}

Question 32

How can alkanes and alkenes be distinguished by using bromine water?

Answer 32

• Alkene mixed together with bromine water forms a clear compound, the brown colour disappears
• Alkane mixed with bromine water stays brown coloured

Question 33

What is the repeating unit in polymers?

Answer 33

–(–CH₂–CH₂–)_n–

Question 34

What are three examples of polymers?

Answer 34

1. Polyethene
2. Polychrloroethene
3. Polypropene

Question 35

How are polymers created?

Answer 35

The double bond of alkanes is broken down and many alkane molecules are put together in a long chain

Question 36

What are the economic advantages of the reactions of alkanes?

Answer 36

• Hydrogenation is used to manufacture margarines from oils
• Hydration is used to form ethanol
• Polymerisation is used to form plastics

Question 37

Describe, using an example, the complete combustion of alcohols

Answer 37

• Burns to produce CO₂ and water

2 CH₂OH(l) + 3 O₂(g) → 2 CO₂(g) + 4 H₂O(g)

Question 38

What is formed when primary alcohols are oxidised?

Answer 38

First aldehydes and if further oxidised, carboxylic acid

Question 39

What is the product of oxidation of secondary alcohols?

Answer 39

Ketone

Question 40

Are tertiary alcohols readily oxidised?

Answer 40

No.

Question 41

How is aldehyde obtained from the oxidation reaction of primary alcohols?

Answer 41

By distilling the product off as it forms

Question 42

How is carboxylic acid obtained from the oxidation of primary alcohols?

Answer 42

By heating it under reflux

Question 43

What is a nucleophile?

Answer 43

An electron-rich species that is attracted to parts of molecules that are electron deficient

Question 44

What are halogenoalkanes?

Answer 44

Saturated alkanes that contain an atom of fluorine, chlorine, bromine, or iodine bonded to the carbon skeleton

Question 45

What is meant by an electron deficient atom?

Answer 45

An atom in a polar covalent bond which loses its electrons to a more electronegative atom

Question 46

What is heterolytic fission?

Answer 46

Breaking a bond where both the shared electrons go to one of the products. Two oppositely charged ions are produced:

X:X → X⁺ + X:^–

Question 47

What are curly arrows used for?

Answer 47

Representing the motion of an electron pair: the tail of the arrow shows there the pair comes from and the head shows where it is going

Question 48

What determines the product in a nucleophilic substitution reaction?

Answer 48

The nucleophile used to replace the halogen

Question 49

Explain the S_N2 nucleophilic substitution mechanism

Answer 49

• For primary halogenoalkanes
• The carbon atom is relatively open to attack by the nucleophile
• An unstable transition state is formed in which the carbon is weakly bonded to both the halogen and the nucleophile
• The carbon-halogen bond then breaks heterolytically, releasing Cl^– and forming the alcohol product

CH₃Cl + OH^– → CH₃OH + Cl^–

Question 50

What is the rate of a S_N2 substitution mechanism dependent on?

Answer 50

The concentration of both the halogenoalkane and the hydroxide ion (bimolecular reaction)

Question 51

Explain the stages in S_N1 nucleophilic substitution

Answer 51

• Tertiary halogenoalkanes
• Three alkyl groups make it difficult for the nucleophile to attack the carbon atom
• The first step involves the halogenoalkane ionising by breaking its carbon-halogen bond heterolytically
• The carbon atom has a temporary positive charge (carbocation)
• The carbocation is attacked by the nucleophile, forming a new bond
• The alkyl groups have an electron-donating (positive inductive) effect which make the carbocation stable for long enough for the new bond to form

CH₃C(CH₃)ClCH₃ + OH^– → CH₃C(CH₃)OHCH₃ + Cl^–

Question 52

Which substitution mechanism do secondary halogenoalkanes go through?

Answer 52

A mixture of both S_N1 and S_N2 mechanisms

Question 53

Draw a diagram of the reaction pathways between organic molecules

Answer 53

* = mechanism required

red arrow = oxidation

purple = reduction/addition of H₂

green = substitution

yellow = addition

grey = elimination

blue = condensation

Question 54

Why is the hydroxide ion a better nucleophile than water?

Answer 54

Because OH^– has a negative charge, H₂O doesn’t

Question 55

What does the rate of nucleophilic substitution reactions depend on?

Answer 55

1. The class of the halogenoalkane
   - Tertiary is the fastest and primary the slowest
2. The identity of the halogen
   - Rate increases down Group 7 from the fluoroalkane to the iodoalkane

Question 56

Describe, using equations, the substitution reaction of halogenoalkane with ammonia

Answer 56

• NH₃ is a nucleophile due to the lone pair of electrons on the nitrogen atom
• S_N2
• The substitution reaction yields in an amine:

C₂H₅Br + NH₃ → C₂H₅NH₂ + HBr

CH₃CHBrCH₃+ NH₃ → CH₃CH(NH₂)CH₃ + HBr

(CH₃)₃CBr + NH₃ → (CH₃)₃CNH₂ + HBr

• Amines can further behave as nucleophiles

Question 57

Describe, using equations, the substitution reaction of halogenoalkane with potassium cyanide

Answer 57

• CN ion is a nucleophile as it contains a lone pair and a negative charge on the carbon
• S_N2
• The substitution yields in a nitrile compound

C₂H₅Br + KCN → C₂H₅CN + KBr

Question 58

Describe the reduction of nitriles using hydrogen and nickel

Answer 58

• Introduction of the nitrile group is an easy way to increase the length of the carbon chain in a molecule
• Reduction occurs using hydrogen and nickel catalyst
• Nitrile is converted into a primary amine

C₂H₅CN + 2 H₂ → C₂H₅CH₂NH₂

• Nitriles are very useful intermediates (reaction pathways)

Question 59

What is an elimination reaction?

Answer 59

A reaction in which a small molecule is removed from a larger molecule, leading to the formation of an unsaturated product

Question 60

What kind of bond is often formed in an elimination reaction?

Answer 60

A carbon–carbon double bond

Question 61

Describe, using an equation, the elimination of HBr from bromoalkanes

Answer 61

CH₃CH₂CH₂Br + NaOH → CH₃CH=CH₂ + NaBr + H₂O

• A hot alcoholic solvent is used

Question 62

What are the two possible mechanisms for elimination?

Answer 62

E2 (elimination bimolecular)

E1 (elimination unimolecular)

Question 63

Explain the E2 elimination mechanism for the elimination of bromine

Answer 63

• One-step mechanism
• Bimolecular
• OH^– ion acts as a base and accepts a proton, from the molecule
• The carbon–bromine bond breaks heterolytically, electrons going to the bromide ion
• The electrons from the carbon–hydrogen bond form the new bond of the double bond

Question 64

Explain the E1 elimination mechanism for bromine

Answer 64

• Unimolecular
• Two-step process
• (1) Ionisation of the halogenoalkane
• (2) Formation of the double bond
• Rate-determining step depends on the concentration of the halogenoalkane

Question 65

What is the use of esters?

Answer 65

Food flavourings and perfumes

(also plasticisers to make plastics more flexible)

Question 66

What happens in a condensation reaction?

Answer 66

Two molecules react to form a product with the loss of a small molecule

(formation of polymers)

Question 67

What is the requirement for a condensation reaction to occur?

Answer 67

Each reactant must have a functional group that reacts with the functional group on the other molecule

Question 68

Describe the condensation reaction between carboxylic acids and alcohols

Answer 68

carboxylic acid + alcohol ⇔ ester water

CH₃COOH + CH₃OH ⇔ CH₃COOCH₃ + H₂O

• Esterification occurs
• Formed by warming a mixture of the carboxylic acid and alcohol in the presence of concentrated sulfuric acid
• The sulfuric acid acts as a catalyst and may also improve the yield

Question 69

What are the chemical properties of esters?

Answer 69

• They do not have free –OH groups so they cannot form hydrogen bonds
• They are more volatile and less soluble in water

Question 70

Describe the condensation reaction between carboxylic acids and amines

Answer 70

carboxylic acid + primary amine → secondary amide + water

CH₃COOH + CH₃NH₂ → CH₃CONH(CH₃) + H₂O

• Secondary amines react to form tertiary amides

Question 71

How are polyesters formed?

Answer 71

• When the acid has two –COOH groups and the alcohol two –OH groups
• The chain extends in both directions forming a polyester

Question 72

How are polyamides (polypeptides) formed?

Answer 72

• Condensation reaction of two amino acids
• An amide link (peptide bond) is formed between the acids
• A free –NH₂ group on one end and a free –COOH gorup on the other allow the continuing the reaction by condensation to form polypeptides and ultimately proteins

Question 73

What is the economic importance of condensation reactions?

Answer 73

Esters

• Used as food flavourings and perfumes
• Used as plasticisers, helping to soften plastics and make them more flexible
• Naturally occurring fats and oils are examples of esters (product of glycerol and fatty acids)
• PET is used in synthetic fibres and the production of plastic bottles

Polyamides

• Polypeptides form proteins
• Synthetic polyamides include plastics such as nylon and kevlar, used in clothing, carpets, machine parts, tyre cords, ropes

Question 74

What are stereoisomers?

Answer 74

Compounds with the same structural formula but with different arrangement of atoms in space

Question 75

What kind of isomerism is present in non-cyclic alkenes?

Answer 75

• Called geometric isomers (cis-trans isomers)
• Restricted free rotation of the bonded groups (double bond)
• Cis = same side
• Trans = opposite sides

Question 76

What are geometric isomers?

Answer 76

Cis-trans isomers

Question 77

Which factors affect the physical properties of geometrical isomers?

Answer 77

1. Polarity of the molecules
2. The shape or symmetry of the molecules

Question 78

How does the polarity of the molecule affect the physical properties of geometrical isomers?

Answer 78

• Affects the boiling points as it determines the strength of the intermolecular forces

Question 79

How does the symmetry of the molecule affect the physical properties of geometrical isomers?

Answer 79

• Affects the melting point as it affects the packing in the solid state
• Trans-isomers are able to pack more closely due to their greater symmetry → the melting point is higher

Question 80

Describe the chemical properties of geometric isomers

Answer 80

• Generally very similar
• Exception is butenedioic acid:
• when cis-isomer is heated it condenses
• when trans-isomer is heated it sublimes but no chemical change occurs

Question 81

What are other types of geometrical isomers except for linear molecules?

Answer 81

Cyclic molecules

• Cyclopropane and cyclobutane
• The substituted groups do not have to be on adjacent carbon atoms
• The ring prevents rotation around the carbon atoms

Dichloro derivatives:

Question 82

What is a chiral (asymmetric) carbon?

Answer 82

A carbon that is bonded to four different atoms or groups to form a tetrahedral, or a molecule with such arrangement

Question 83

What are enantiomers?

Answer 83

The two isomers of molecules that show optical isomerism

Question 84

What is a racemic mixture?

Answer 84

A mixture that contains equal amounts of both enantiomers

Question 85

What is meant by non-superimposable molecules?

Answer 85

Molecules that have no plane of symmetry and do not line up when put on top of each other

Question 86

What are two examples of molecules that show optical isomerism?

Answer 86

1. butan-2-ol
2. 2-chlorobutane

Question 87

What are the properties of optical isomers?

Answer 87

Isomers have identical physical and chemical properties with two exceptions:

1. Optical activity
2. Reactivity with other chiral molecules

Question 88

What is meant by optical activity?

Answer 88

Optical isomers’ property of polarising light.

Question 89

How is a polarimeter used to distinguish between optical isomers?

Answer 89

• When a beam of plane-polarised light passes through a solution of optical isomers, they rotate the plane of polarisation
  1. The sample of isomers is placed in the sample tube
  2. Plane-polarised light is passed through the sample tube
  3. Rotation of the polarisation plane occurs in the tube
  4. The light passes through a second polariser called the analyser
  5. The analyser has been rotated until the light passes through it
  6. The extent and direction of rotation brought about by the sample can be deduced from the analyser
• Enantiomers of the same concentration rotate plane-polarised light in equal amounts but in opposite directions
• A racemic mixture does not rotate the light because the enantiomers cancel out and the solution is said to be optically inactive

Question 90

What is a resolution? (optical isomerism)

Answer 90

A method of separating two enantiomers from a racemic mixture by reacting them with another chiral compound

Question 91

What happens when a racemic mixture is reacted with a signle enantiomer of another chiral compound?

Answer 91

• The enantiomers produce two different products
• Products have distinct chemical and physical properties and can be separated easily