13.2 Halogenoalkanes

HALOGENOALKANES
Organic Chemistry
05 March 2024
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ChemistrySecondary EducationAge 12,13

This lesson contains 33 slides, with interactive quizzes and text slides.

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HALOGENOALKANES
Organic Chemistry
05 March 2024

Slide 1 - Slide

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  • apply the SN1 and SN2 mechanisms in halogenoalkane reactions to show how nucleophilic addition occurs
  • create a quick slide presentation to describe the chosen reaction that halogenoalkanes undergo
  • orally present the created slides to describe how halogenoalkanes react with different reagents
  • accurately respond to the given question in the 3-question sheet
Learning expectations

Slide 2 - Slide

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HALOGENOALKANES
Organic Chemistry
05 March 2024

Slide 3 - Slide

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 Illustrate the following:

  • (a) a halogenoalkane
  • (b) a nucleophile
  • (c) nucleophilic addition
Picture me this!
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5:00

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  • substitution of an atom by a nucleophile
  • possible due to the polarity of the carbon-halogen bond
  • two mechanisms, the SN1 or SN2 mechanism
Nucleophilic Substitution

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HALOGENOALKANES
Organic Chemistry
05 March 2024

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Polarisation of carbon-halide bond

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What's happened to the molecule?

Slide 9 - Open question

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  • Primary halogenoalkanes will use SN2.
  • Tertiary halogenoalkans will use SN1.
  • Secondary halogenoalkanes will use both.
Two Mechanisms of Nucleophilic Substitution

Slide 10 - Slide

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  • The 'S' stands for substitution, the 'N' stands for nucleophilic and the '2' stands for the initial step (rate-determining step) 
  • involves two species(the halogenoalkane and the nucleophile)
SN2 MECHANISM

Slide 11 - Slide

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How to write the mechanism in exams

Slide 12 - Slide

What do you notice about the orientation of the atoms?
It is crucial to get the orientation of the atoms right, the molecule has been
inverted at the end of the reaction. This is called the inversion of configuration(product has a configuration opposite to the reactant).


Is it possible for a tertiary halogenoalkane to react by SN2 mechanism?
THINK ABOUT:

Slide 13 - Poll

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  • It is unlikely for tertiary halogenoalkanes to react by the SN2 mechanism. This is because SN2 mechanism involves the nucleophile approaching and forming bond from the opposite side of the halogen. In the case of tertiary halogenoalkane, it is unlikely because the opposite of the halogen is cluttered with CH3 group(s).
EXPLANATION

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  • The '1' stands for the initial step(rate-determining step).
  • involves one species only(the halogenoalkane)
SN1 MECHANISM

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i. The reaction happens in two stages. In the first stage, a small proportion of
the halogenoalkane ionises to give a carbocation and a bromide ion.

ii. Once the carbocation is formed, it will react immediately when it comes into contact with a nucleophile, Nu−. The lone pair of the nucleophile is strongly attracted towards the positive carbon, and moves towards it to create a new bond.


Why do secondary halogenoalkanes react using both SN1 and SN2 mechanisms?
THINK ABOUT:
A
The opposite of the halogen is uncluttered by CH3 groups.
B
There is no other way than both SN1 and SN2.
C
The second-degree carbocation formed is more stable.
D
Both A and C.

Slide 16 - Quiz

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HALOGENOALKANES
Organic Chemistry
05 March 2024

Slide 18 - Slide

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  Goal and Expected Output: Make and share a quick diagram presentation about:

  • Team 1 (Vathana and Romnea) - Substitution reaction with NaOH(aq) and heat to produce an alcohol
  • Team 2 (Kosoma and Vinisa) - Substitution reaction with KCN in ethanol and heat to produce a nitrile
  • Team 3 (Kanika and Paulika) - Substitution reaction with NH3 in ethanol heated under pressure to produce an amine
  • Team 4 (Malika) - Reaction with aqueous silver nitrate in ethanol as a method of identifying the halogen present as exemplified by bromoethane
Classwork 4
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15:00

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USES OF HALOGENOALKANES
Organic Chemistry
29 February 2024

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Uses of CFCs
  • chlorofluorocarbons, compounds containing carbon with chlorine and fluorine atoms attached. Two common CFCs are CFC-11(CCl3F) and CFC-12(CCl2F2).

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Effects of CFCs to the environment
  • destruction of the ozone layer (O3)

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REACTIONS OF HALOGENOALKANES
Organic Chemistry
29 February 2024

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  • Substitution with hydroxide ions, OH.
  • Substitution with cyanide ions, CN.
  • Substitution with ammonia, NH3.
  • Elimination
Halogenoalkanes reactions

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Substitution with hydroxide ions, OH (Hydrolysis)
  • Reagent: Aqueous sodium hydroxide, NaOH or water
  • Condition: Heat under reflux
  • Product: Alcohols

Slide 30 - Slide

it can also happen with water molecule as a nucleophile
Substitution with cyanide ions, CN
  • Reagent: Potassium cyanide, KCN in ethanol (ethanolic KCN)
  • Condition: Heat under reflux
  • Product: Nitriles
  • The nitrile produced can be converted to carboxylic acid by heating under reflux with acid or alkali (hydrolysis reaction).
  • (CH3)3CN + 2H2O + H+ → (CH3)3COOH + NH4+ 
  • (CH3)3CN + H2O + OH → (CH3)3COO + NH3

Slide 31 - Slide

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Substitution with ammonia, NH3
  • Reagent: Excess ammonia, NH3 in ethanol
  • Condition: Heat in a sealed tube
  • Product: Amines

Slide 32 - Slide

it can also happen with water molecule as a nucleophile
Elimination
  • Reagent: Sodium hydroxide, NaOH in ethanol
  • Condition: Heat under reflux
  • Product: Alkenes

Slide 33 - Slide

it can also happen with water molecule as a nucleophile