AN INTRODUCTION TO CARBOXYLIC ACIDS AND THEIR DERIVATIVES

1. AN INTRODUCTION TO CARBOXYLIC ACIDS AND THEIR DERIVATIVES 2008 SPECIFICATIONS KNOCKHARDY PUBLISHING

2. KNOCKHARDY PUBLISHING CARBOXYLIC ACIDS INTRODUCTION This Powerpoint show is one of several produced to help students understand selected topics at AS and A2 level Chemistry. It is based on the requirements of the AQA and OCR specifications but is suitable for other examination boards. Individual students may use the material at home for revision purposes or it may be used for classroom teaching if an interactive white board is available. Accompanying notes on this, and the full range of AS and A2 topics, are available from the KNOCKHARDY SCIENCE WEBSITE at... www.knockhardy.org.uk/sci.htm Navigation is achieved by... either clicking on the grey arrows at the foot of each page or using the left and right arrow keys on the keyboard

3. CARBOXYLIC ACIDS • CONTENTS • Structure of carboxylic acids • Nomenclature • Physical properties of carboxylic acids • Preparation of carboxylic acids • Chemical properties of carboxylic acids • Esters • Triglycerides and fats • Biofuels

4. CARBOXYLIC ACIDS • Before you start it would be helpful to… • Recall the definition of a covalent bond • Recall the difference types of physical bonding • Be able to balance simple equations • Be able to write out structures for simple organic molecules • Understand the IUPAC nomenclature rules for simple organic compounds • Recall the chemical properties of alkanes and alkenes

5. STRUCTURE OF CARBOXYLIC ACIDS • contain the carboxyl functional group COOH • the bonds are in a planar arrangement

6. STRUCTURE OF CARBOXYLIC ACIDS • contain the carboxyl functional group COOH • the bonds are in a planar arrangement • include a carbonyl (C=O) group and a hydroxyl (O-H) group

7. STRUCTURE OF CARBOXYLIC ACIDS • contain the carboxyl functional group COOH • the bonds are in a planar arrangement • include a carbonyl (C=O) group and a hydroxyl (O-H) group • are isomeric with esters :- RCOOR’

8. HOMOLOGOUS SERIES Carboxylic acids form a homologous series HCOOHCH3COOH C2H5COOH

9. HOMOLOGOUS SERIES Carboxylic acids form a homologous series HCOOHCH3COOH C2H5COOH With more carbon atoms, there can be structural isomers C3H7COOH (CH3)2CHCOOH

10. INFRA-RED SPECTROSCOPY IDENTIFYING CARBOXYLIC ACIDS USING INFRA RED SPECTROSCOPY DifferentiationCompound O-H C=O ALCOHOLYESNO CARBOXYLIC ACIDYESYES ESTERNOYES ALCOHOL CARBOXYLIC ACID ESTER O-H absorption O-H + C=O absorption C=O absorption

11. NAMING CARBOXYLIC ACIDS Acids are named according to standard IUPAC rules • select the longest chain of C atoms containing the COOH group; • remove the e and add oic acid after the basic name • number the chain starting from the end nearer the COOH group • as in alkanes, prefix with alkyl substituents • side chain positions are based on the C in COOH being 1 e.g. CH3 - CH(CH3) - CH2 - CH2 - COOH is called 4-methylpentanoic acid

12. NAMING CARBOXYLIC ACIDS Acids are named according to standard IUPAC rules • select the longest chain of C atoms containing the COOH group; • remove the e and add oic acid after the basic name • number the chain starting from the end nearer the COOH group • as in alkanes, prefix with alkyl substituents • side chain positions are based on the C in COOH being 1 METHANOIC ACID ETHANOIC ACID PROPANOIC ACID

13. NAMING CARBOXYLIC ACIDS Acids are named according to standard IUPAC rules • select the longest chain of C atoms containing the COOH group; • remove the e and add oic acid after the basic name • number the chain starting from the end nearer the COOH group • as in alkanes, prefix with alkyl substituents • side chain positions are based on the C in COOH being 1 BUTANOIC ACID 2-METHYLPROPANOIC ACID

14. NAMING CARBOXYLIC ACIDS Acids are named according to standard IUPAC rules Many carboxylic acids are still known under their trivial names, some having been called after characteristic properties or their origin. Formula Systematic name (trivial name) origin of name HCOOH methanoic acid formic acid latin for ant CH3COOH ethanoic acid acetic acid latin for vinegar C6H5COOH benzenecarboxylic acid benzoic acid from benzene

15. PHYSICAL PROPERTIES BOILING POINT Increases as size increases - due to increased van der Waals forces 101°C 118°C 141°C 164°C

16. PHYSICAL PROPERTIES BOILING POINT Increases as size increases - due to increased van der Waals forces 101°C 118°C 141°C 164°C Boiling point is higher for “straight” chain isomers. 164°C 154°C Greater branching = lower inter-molecular forces = lower boiling point

17. PHYSICAL PROPERTIES BOILING POINT Increases as size increases - due to increased van der Waals forces Carboxylic acids have high boiling points for their relative mass The effect of hydrogen bonding on the boiling point of compounds of similar mass Compound Formula Mr b. pt. (°C) Comments ethanoic acid CH3COOH 60 118 propan-1-ol C3H7OH 60 97 h-bonding propanal C2H5CHO 58 49 dipole-dipole butane C4H10 58 - 0.5 basic V der W

18. HYDROGEN BONDING PHYSICAL PROPERTIES BOILING POINT Increases as size increases - due to increased van der Waals forces Carboxylic acids have high boiling points for their relative mass • arises from inter-molecular hydrogen bonding due to polar O—H bonds AN EXTREME CASE... DIMERISATION • extra inter-molecular attraction = more energy to separate molecules

19. HYDROGEN BONDING PHYSICAL PROPERTIES SOLUBILITY • carboxylic acids are soluble in organic solvents • they are also soluble in water due to hydrogen bonding

20. HYDROGEN BONDING PHYSICAL PROPERTIES SOLUBILITY • carboxylic acids are soluble in organic solvents • they are also soluble in water due to hydrogen bonding • small ones dissolve readily in cold water • as mass increases, the solubility decreases • benzoic acid is fairly insoluble in cold but soluble in hot water

21. PREPARATION OF CARBOXYLIC ACIDS Oxidation of aldehydes RCHO + [O] ——> RCOOH Hydrolysis of esters RCOOR + H2O RCOOH + ROH Hydrolysis of acyl chlorides RCOCl + H2O ——> RCOOH + HCl Hydrolysis of nitriles RCN + 2 H2O ——> RCOOH + NH3 Hydrolysis of amides RCONH2 + H2O ——> RCOOH + NH3

22. CHEMICAL PROPERTIES ACIDITY weak acids RCOOH + H2O(l) RCOO¯(aq) + H3O+(aq) form salts RCOOH + NaOH(aq) ——> RCOO¯Na+(aq) + H2O(l) 2RCOOH + Mg(s) ——> (RCOO¯)2Mg2+(aq) + H2(g)

23. CHEMICAL PROPERTIES ACIDITY weak acids RCOOH + H2O(l) RCOO¯(aq) + H3O+(aq) form salts RCOOH + NaOH(aq) ——> RCOO¯Na+(aq) + H2O(l) 2RCOOH + Mg(s) ——> (RCOO¯)2Mg2+(aq) + H2(g) The acid can be liberated from its salt by treatment with a stronger acid. e.g. RCOO¯ Na+(aq) + HCl(aq) ——> RCOOH + NaCl(aq) Conversion of an acid to its water soluble salt followed by acidification of the salt to restore the acid is often used to separate acids from a mixture.

24. CHEMICAL PROPERTIES ACIDITY weak acids RCOOH + H2O(l) RCOO¯(aq) + H3O+(aq) form salts RCOOH + NaOH(aq) ——> RCOO¯Na+(aq) + H2O(l) 2RCOOH + Mg(s) ——> (RCOO¯)2Mg2+(aq) + H2(g) The acid can be liberated from its salt by treatment with a stronger acid. e.g. RCOO¯ Na+(aq) + HCl(aq) ——> RCOOH + NaCl(aq) Conversion of an acid to its water soluble salt followed by acidification of the salt to restore the acid is often used to separate acids from a mixture. QUALITATIVE ANALYSIS Carboxylic acids are strong enough acids to liberate CO2 from carbonates Phenols are also acidic but not are not strong enough to liberate CO2.

25. ESTERIFICATION Reagent(s) alcohol + strong acid catalyst (e.g. conc. H2SO4 ) Conditions reflux Product ester Equatione.g. CH3CH2OH(l) + CH3COOH(l) CH3COOC2H5(l) + H2O(l) ethanol ethanoic acid ethyl ethanoate

26. ESTERIFICATION Reagent(s) alcohol + strong acid catalyst (e.g. conc. H2SO4 ) Conditions reflux Product ester Equatione.g. CH3CH2OH(l) + CH3COOH(l) CH3COOC2H5(l) + H2O(l) ethanol ethanoic acid ethyl ethanoate NotesConc.H2SO4 is a dehydrating agent - it removes water causing the equilibrium to move to the right and thus increases the yield of the ester

27. ESTERIFICATION Reagent(s) alcohol + strong acid catalyst (e.g conc. H2SO4 ) Conditions reflux Product ester Equation e.g. CH3CH2OH(l) + CH3COOH(l) CH3COOC2H5(l) + H2O(l) ethanol ethanoic acid ethyl ethanoate Notes Conc. H2SO4 is a dehydrating agent - it removes water causing the equilibrium to move to the right and thus increases the yield of the ester Naming esters Named from the original alcohol and carboxylic acid CH3OH + CH3COOHCH3COOCH3+ H2O fromethanoic acidCH3COOCH3from methanol METHYLETHANOATE

28. CHLORINATION OF CARBOXYLIC ACIDS Chlorination involves replacing the OH with a Cl Product acyl chloride Reagent thionyl chloride SOCl2 Conditions DRY conditions EquationCH3COOH + SOCl2 ——> CH3COCl + SO2 + HCl Alternative method CH3COOH + PCl5 ——> CH3COCl + POCl3 + HCl phosphorus(V) chloride

29. ESTERS Structure Substitute an organic group for the H in carboxylic acids Nomenclature first part from alcohol, second part from acid e.g. methyl ethanoate CH3COOCH3 METHYL ETHANOATE ETHYL METHANOATE

30. ESTERS Structure Substitute an organic group for the H in carboxylic acids Nomenclature first part from alcohol, second part from acid e.g. methyl ethanoate CH3COOCH3 Preparation From carboxylic acids, acyl chlorides and acid anhydrides Reactivity Unreactive compared with acids and acyl chlorides METHYL ETHANOATE ETHYL METHANOATE

31. ESTERS Structure Substitute an organic group for the H in carboxylic acids Nomenclature first part from alcohol, second part from acid e.g. methyl ethanoate CH3COOCH3 Preparation From carboxylic acids, acyl chlorides and acid anhydrides Reactivity Unreactive compared with acids and acyl chlorides Isomerism Esters are structural isomers of carboxylic acids METHYL ETHANOATE ETHYL METHANOATE

32. STRUCTURAL ISOMERISM – FUNCTIONAL GROUP ClassificationCARBOXYLIC ACIDESTER Functional GroupR-COOHR-COOR NamePROPANOIC ACID METHYL ETHANOATE Physical propertiesO-H bond gives rise No hydrogen bonding to hydrogen bonding; insoluble in water get higher boiling point and solubility in water Chemical properties acidic fairly unreactive react with alcohols hydrolysed to acids

33. PREPARATION OF ESTERS - 1 Reagent(s) alcohol + carboxylic acid Conditions reflux with a strong acid catalyst (e.g. conc. H2SO4 ) Equatione.g. CH3CH2OH(l) + CH3COOH(l) CH3COOC2H5(l) + H2O(l) ethanol ethanoic acid ethyl ethanoate NotesConc.H2SO4 is a dehydrating agent - it removes water causing the equilibrium to move to the right and thus increases the yield of the ester For more details see under ‘Reactions of carboxylic acids’

34. PREPARATION OF ESTERS - 2 Reagent(s) alcohol + acyl chloride Conditions reflux under dry conditons Equatione.g. CH3OH(l) + CH3COCl(l)——> CH3COOCH3(l) + HCl(g) methanol ethanoyl methyl chloride ethanoate Notes Acyl chlorides are very reactive but must be kept dry as they react with water.

35. PREPARATION OF ESTERS - 3 Reagent(s) alcohol + acid anhydride Conditions reflux under dry conditons Equatione.g. CH3OH(l) + (CH3CO)2O(l)——> CH3COOCH3(l) + CH3COOH(l) methanol ethanoic methyl ethanoic anhydride ethanoate acid Notes Acid anhydrides are not as reactive as acyl chlorides so the the reaction is slower. The reaction is safer - it is less exothermic. Acid anhydrides are less toxic.

36. HYDROLYSIS OF ESTERS Hydrolysis is the opposite of esterification ESTER + WATER CARBOXYLIC ACID + ALCOHOL HCOOH + C2H5OH METHANOIC ETHANOL ACID ETHYL METHANOATE

37. HYDROLYSIS OF ESTERS Hydrolysis is the opposite of esterification ESTER + WATER CARBOXYLIC ACID + ALCOHOL HCOOH + C2H5OH METHANOIC ETHANOL ACID ETHYL METHANOATE METHYL ETHANOATE

38. HYDROLYSIS OF ESTERS Hydrolysis is the opposite of esterification ESTER + WATER CARBOXYLIC ACID + ALCOHOL HCOOH + C2H5OH METHANOIC ETHANOL ACID ETHYL METHANOATE CH3COOH + CH3OH ETHANOIC METHANOL ACID METHYL ETHANOATE

39. HYDROLYSIS OF ESTERS Hydrolysis is the opposite of esterification ESTER + WATER CARBOXYLIC ACID + ALCOHOL The products of hydrolysis depend on the conditions used... acidic CH3COOCH3 + H2O CH3COOH + CH3OH alkaline CH3COOCH3 + NaOH ——> CH3COO¯ Na+ + CH3OH

40. HYDROLYSIS OF ESTERS Hydrolysis is the opposite of esterification ESTER + WATER CARBOXYLIC ACID + ALCOHOL The products of hydrolysis depend on the conditions used... acidic CH3COOCH3 + H2O CH3COOH + CH3OH alkaline CH3COOCH3 + NaOH ——> CH3COO¯ Na+ + CH3OH If the hydrolysis takes place under alkaline conditions, the organic product is a water soluble ionic salt

41. HYDROLYSIS OF ESTERS Hydrolysis is the opposite of esterification ESTER + WATER CARBOXYLIC ACID + ALCOHOL The products of hydrolysis depend on the conditions used... acidic CH3COOCH3 + H2O CH3COOH + CH3OH alkaline CH3COOCH3 + NaOH ——> CH3COO¯ Na+ + CH3OH If the hydrolysis takes place under alkaline conditions, the organic product is a water soluble ionic salt The carboxylic acid can be made by treating the salt with HCl CH3COO¯ Na+ + HCl ——> CH3COOH + NaCl

42. USES OF ESTERS Despite being fairly chemically unreactive, esters are useful as ... • flavourings apple 2-methylbutanoate pear 3-methylbutylethanoate banana 1-methylbutylethanoate pineapple butylbutanoate rum 2-methylpropylpropanoate • solvents nail varnish remover - ethyl ethanoate • plasticisers

43. TRIGLYCERIDES AND FATS Triglycerides • are the most common component of edible fats and oils • are triesters of the alcohol glycerol, (propane-1,2,3-triol) and fatty acids glycerol a triglyceride

44. TRIGLYCERIDES AND FATS Triglycerides • are the most common component of edible fats and oils • are triesters of the alcohol glycerol, (propane-1,2,3-triol) and fatty acids Saponification • alkaline hydrolysis of triglycerol esters produces soaps • a simple soap is the salt of a fatty acid • as most oils contain a mixture of triglycerols, soaps are not compounds • the quality of a soap depends on the oils from which it is made

45. FATTY ACIDS Carboxylic acids that are obtained from natural oils and fats; they can be… Saturated CH3(CH2)16COOH octadecanoic acid (stearic acid)

46. FATTY ACIDS Carboxylic acids that are obtained from natural oils and fats; they can be… Saturated CH3(CH2)16COOH octadecanoic acid (stearic acid) 9 Unsaturated CH3(CH2)7CH=CH(CH2)7COOH octadec-9-enoic acid (oleic acid) cis (Z) isomer trans (E) isomer

47. FATTY ACIDS Carboxylic acids that are obtained from natural oils and fats; they can be… Saturated CH3(CH2)16COOH octadecanoic acid (stearic acid) 9 Unsaturated CH3(CH2)7CH=CH(CH2)7COOH octadec-9-enoic acid (oleic acid) cis (Z) isomer trans (E) isomer 12 9 CH3(CH2)4CH=CHCH2CH=CH(CH2)7COOH octadec-9,12-dienoic acid (linoleic acid)

48. FATTY ACIDS AND HEALTH Saturated • solids at room temperature • found in meat and dairy products • are bad for health • increase cholesterol levels - can lead to heart problems

49. FATTY ACIDS AND HEALTH Saturated • solids at room temperature • found in meat and dairy products • are bad for health • increase cholesterol levels - can lead to heart problems Mono unsaturated • contain just one C=C • thought to be neutral to our health • found in olives, olive oil, groundnut oil, nuts, avocados

50. FATTY ACIDS AND HEALTH Saturated • solids at room temperature • found in meat and dairy products • are bad for health • increase cholesterol levels - can lead to heart problems Mono unsaturated • contain just one C=C • thought to be neutral to our health • found in olives, olive oil, groundnut oil, nuts, avocados Poly unsaturated • are considered to be ‘good fats’ • contain more than one C=C bond • tend to be liquids at room temperature, eg olive oil. • can be split into two main types... Omega 3 - fatty acids Omega 6 - fatty acids