Deducing Organic Structures (Edexcel International A Level Chemistry): Revision Note

Author

Richard Boole

Last updated

9 January 2025

Combined Techniques

You will be expected to deduce the empirical, molecular and structural formulae of compounds from data such as:
- Combustion analysis
- Elemental percentage composition - also known as calculating empirical formulae
- Characteristic reactions of functional groups - this can include test-tube reactions as well as interconversions
- Infrared (IR) spectra
- Mass spectra (MS)
- Nuclear magnetic resonance (NMR) spectra
The normal progression for the analysis of a compound is:
1. Find the empirical formula
2. Determine the molecular formula
3. Identify the functional groups / structural components present
4. Deduce the overall structure

Combustion analysis

Sometimes combustion analysis is performed on an unknown compound to determine the elemental percentage composition
The elemental percentage composition is then used to calculate the empirical formula
In combustion analysis, a known mass of the compound is burned in an excess of dry oxygen
The mass of carbon dioxide and water are then used to determine the percentage content of carbon, hydrogen and oxygen in the compound
- This can also be applied to include sulfur and nitrogen, although you are not expected to do this, at this level
To convert combustion analysis data to elemental percentage composition:
1. Calculate the mass of carbon in the sample from the combustion analysis results
2. Calculate the percentage of carbon in the sample
3. Calculate the mass of hydrogen in the sample from the combustion analysis results
4. Calculate the percentage of hydrogen in the sample
5. Use the percentage of carbon and hydrogen to deduce the percentage of oxygen in the sample

Worked Example

Combustion analysis was performed on 2.90 g of an unknown carbohydrate, A.

6.60 g of carbon dioxide and 2.70 g of water were produced.

Calculate the carbohydrates percentage composition.

Answer

Step 1: Calculate the mass of carbon in the sample

Mass of carbon = $\frac{mass of carbon}{molecular mass of carbon dioxide} \times mass of carbon dioxide produced$
- Mass of carbon = $= \frac{12.0}{44.0} \times 6.60 = 1.80 g$

Step 2: Calculate the percentage of carbon in the sample

Percentage carbon = $\frac{mass of carbon in sample}{mass of sample} \times 100$
- Percentage carbon $= \frac{1.80}{2.90} \times 100 = 62.1 %$

Step 3: Calculate the mass of hydrogen in the sample

Mass of hydrogen = $\frac{TOTAL mass of hydrogen}{molecular mass of water} \times mass of water produced$
- Mass of hydrogen = $= \frac{2.0}{18.0} \times 2.70 = 0.30 g$

Step 4: Calculate the percentage of hydrogen in the sample

Percentage hydrogen = $\frac{mass of hydrogen in sample}{mass of sample} \times 100$
- Percentage hydrogen $= \frac{0.30}{2.90} \times 100 = 10.3 %$

Step 5: Calculate the percentage of oxygen in the sample

Percentage oxygen = 100 - percentage of carbon - percentage of hydrogen
- Percentage oxygen = 100 - 62.1 - 10.3 = 27.6%
- Therefore, the percentage composition of the carbohydrate is 62.1% carbon, 10.3% hydrogen and 27.6% oxygen

Examiner Tips and Tricks

Don't forget to use 2.0 g for the mass of hydrogen as there are two hydrogen atoms in a water molecule

Worked Example

Calculate the empirical formula for the unknown carbohydrate, A

Answer

The percentage composition of the unknown carbohydrate, A, is 62.1% carbon, 10.3% hydrogen and 27.6% oxygen

Empirical formula = C₃H₆O

Characteristic reactions of functional groups

For deducing structures, these will typically be the test-tube reactions, including (but not limited to):
- Bromine: C=C bond
- Acidified potassium dichromate(VI) solution: primary and secondary alcohols
- Fehling's or Tollens': aldehydes and ketones
- 2,4-dinitrophenylhydrazine (2,4-DNPH): C=O bond
- Sodium carbonate: carboxylic acids
- Iodoform: Methyl groups next to C=O

Spectral analysis

These will include:
- Infrared spectroscopy: to identify functional groups and certain bond types
- Mass spectrometry: to identify molecular formula and fragments
- Carbon-13 (¹³C) nuclear magnetic resonance: to identify compound structure
- Proton (¹H) nuclear magnetic resonance: to identify compound structure

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Previous:Characteristic Behaviour of Amino AcidsNext:Planning Reaction Schemes

Deducing Organic Structures (Edexcel International A Level Chemistry): Revision Note

Combined Techniques

Combustion analysis

Characteristic reactions of functional groups

Spectral analysis

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1. Structure, Bonding & Introduction to Organic Chemistry

Formulae & Equations

Formulae & Mass

Avogadro & the Mole

Full & Ionic Equations

Calculating Formulae

Amount of Substance

Concentration Calculations

Reacting Mass Calculations

Reacting Volume Calculations

Calculations of Product

Atomic Structure

Sub-Atomic Particles

Isotopes & Mass Spectra

Electrons & Ions

Endothermic Ionisation Energy

Electronic Structures

Shapes of Orbitals

Electronic Configurations & Chemical Properties

The Periodic Table

Periodicity - Ionisation Energy

Periodicity - Thermal Trends

Ionic & Metallic Bonding & Structure

Evidence of Ions

Ionic Bonding & Structures

Ionic Bond Strength

Polarisation

Metallic Bonding & Lattices

Covalent Bonding & Structure

Evidence of Covalent Bonding

Covalent Bonding

Carbon Allotropes

Electronegativity

VSEPR Theory

Predicting Shapes & Angles

Introductory Organic Chemistry

Hazards & Risks

Functional Groups & Homologous Series

Nomenclature & Classification

Isomers - Structural

Alkanes

Alkanes - Introduction

Alkanes as Fuels

Combustion of Alkanes

Alternative Fuels

Free Radicals & Fission

The Free Radical Substitution Mechanism

Alkenes

Alkenes - Introduction

Isomers - Geometric

Reactions of Alkenes

Saturation Test

Electrophilic Addition - Mechanism

Addition Polymerisation

Polymer Disposal

2. Energetics, Group Chemistry, Halogenoalkanes & Alcohols

Energetics

Enthalpy Level Diagrams

Enthalpy Change - Definitions

Using Calorimetry

Using Hess Cycles

Bond Enthalpies

Intermolecular Forces

Intermolecular Forces - Introduction

Hydrogen Bonding

Physical Properties

Solvent Choice

Redox Chemistry & Acid-Base Titrations

Oxidation Numbers - Introduction

Oxidation & Reduction

Disproportionation Reactions

Ionic Equations