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AQA GCSE Chemistry Notes

4.1.2 Electrolysis Products and Observations

Molten Lead(II) Bromide

Introduction

Molten lead(II) bromide undergoes electrolysis to produce lead metal and bromine gas. This process vividly demonstrates the fundamental principles of electrolysis.

Observations

  • Colour Change: Initially, lead(II) bromide appears as a solid with an orange hue. Upon heating, it transitions into a clear, molten state.
  • Electrode Reactions: At the anode, a noticeable emission of brown bromine gas occurs. At the cathode, the reduction of lead ions results in the formation of silvery droplets of lead.

Products

  • At the Anode (Positive Electrode): Bromine gas (Br2) is produced, evident from its distinct colour and odour.
  • At the Cathode (Negative Electrode): Metallic lead (Pb) is deposited, identifiable by its characteristic silvery appearance.

Chemical Equations

  • Anode: 2Br⁻ → Br2 + 2e⁻ (Oxidation)
  • Cathode: Pb²⁺ + 2e⁻ → Pb (Reduction)
Molten lead(II) bromide electrolysis

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Concentrated Aqueous Sodium Chloride

Introduction

The electrolysis of concentrated sodium chloride solution, commonly known as brine, results in the production of chlorine gas, hydrogen gas, and sodium hydroxide.

Observations

  • Gas Evolution: Evident bubbling at both electrodes indicates gas production.
  • Colour Change: The solution remains largely clear, with a possible yellow tinge near the anode due to chlorine gas.

Products

  • At the Anode: Chlorine gas (Cl2), with its distinctive greenish-yellow colour and pungent odour, is liberated.
  • At the Cathode: Hydrogen gas (H2) is formed, alongside hydroxide ions (OH⁻), contributing to the formation of sodium hydroxide (NaOH) in the solution.

Chemical Equations

  • Anode: 2Cl⁻ → Cl2 + 2e⁻ (Oxidation)
  • Cathode: 2H₂O + 2e⁻ → H2 + 2OH⁻ (Reduction)
Electrolysis of brine

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Dilute Sulfuric Acid with Inert Electrodes

Introduction

Electrolysing dilute sulfuric acid demonstrates the production of oxygen and hydrogen gases, embodying the principle of water electrolysis.

Observations

  • Gas Release: The generation of gas at both electrodes is a key observation.
  • Solution Change: The solution remains clear, but its conductivity gradually decreases, indicating the consumption of ions.

Products

  • At the Anode: Oxygen gas (O2), which is crucial in various industrial processes, is produced.
  • At the Cathode: Hydrogen gas (H2), a potential clean fuel, is liberated.

Chemical Equations

  • Anode: 4OH⁻ → O2 + 2H2O + 4e⁻ (Oxidation)
  • Cathode: 2H⁺ + 2e⁻ → H2 (Reduction)
Electrolysis of Dilute Sulfuric Acid

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Aqueous Copper(II) Sulfate with Inert and Copper Electrodes

With Inert Electrodes

Observations

  • Colour Change: The characteristic blue colour of the solution fades, indicating the depletion of copper ions.
  • Electrode Changes: Copper metal deposits on the cathode, while oxygen gas evolves at the anode.

Products

  • At the Anode: Oxygen gas (O2), a byproduct of water electrolysis in this context.
  • At the Cathode: Copper metal (Cu), which appears as a reddish deposit.

Chemical Equations

  • Anode: 4OH⁻ → O2 + 2H2O + 4e⁻ (Oxidation)
  • Cathode: Cu²⁺ + 2e⁻ → Cu (Reduction)

With Copper Electrodes

Observations

  • Cathode Change: The cathode experiences a gain in mass as copper is deposited.
  • Anode Change: The anode gradually loses mass due to the dissolution of copper into the solution.

Products

  • At the Anode: Copper ions (Cu²⁺) are released into the solution, maintaining the concentration of the electrolyte.
  • At the Cathode: Copper metal (Cu) is deposited, enhancing the cathode's mass.

Chemical Equations

  • Anode: Cu → Cu²⁺ + 2e⁻ (Oxidation)
  • Cathode: Cu²⁺ + 2e⁻ → Cu (Reduction)
Electrolysis of Aqueous Copper(II) Sulfate with Copper Electrodes

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This detailed examination of electrolysis products and observations in various scenarios provides a comprehensive understanding of the processes involved. From the decomposition of molten lead(II) bromide to the complex reactions in aqueous copper(II) sulfate solutions, these reactions not only reinforce core concepts in electrochemistry but also showcase the practical applications of these phenomena in numerous industrial and technological domains. Understanding the intricacies of these reactions is pivotal for students aspiring to excel in IGCSE Chemistry.

FAQ

During the electrolysis of aqueous copper(II) sulfate with inert electrodes, complex molecular-level interactions occur. At the cathode, copper ions (Cu²⁺) in the solution gain electrons and are reduced to copper metal, which deposits on the electrode. This reduction is represented by the equation Cu²⁺ + 2e⁻ → Cu. At the anode, water molecules are oxidised rather than sulfate ions due to their lower ionization energy. This oxidation of water produces oxygen gas (O2) and hydrogen ions (H⁺), with the reaction being 4OH⁻ → O2 + 2H2O + 4e⁻. The hydrogen ions released contribute to the acidity of the solution. Meanwhile, the sulfate ions (SO4²⁻) remain largely as spectator ions, not undergoing any chemical change. This process demonstrates the selective discharge of ions, where the ions with lower electrode potential are discharged preferentially at the electrodes.

Molten lead(II) bromide is required for electrolysis because in its solid state, the ions are in a fixed lattice and cannot move freely. Electrolysis relies on the movement of ions towards the electrodes: cations towards the cathode and anions towards the anode. In the molten state, lead(II) bromide dissociates into lead ions (Pb²⁺) and bromide ions (Br⁻), which are free to move in the liquid. This mobility allows the ions to conduct electricity and participate in the redox reactions at the electrodes. In contrast, in the solid state, the ions are not mobile, and therefore, the substance cannot conduct electricity, making electrolysis impossible. The requirement for a substance to be in a molten or dissolved state for electrolysis is a fundamental principle in electrochemistry, as it ensures ion mobility which is crucial for the process.

The concept of 'overvoltage' or 'overpotential' is significant in the electrolysis of dilute sulfuric acid, particularly at the anode where oxygen is produced. Overvoltage refers to the extra voltage required beyond the theoretical voltage to drive a chemical reaction at the electrode. In the case of dilute sulfuric acid, the theoretical potential for oxygen evolution is lower than the actual potential observed. This discrepancy is due to several factors, including the nature of the electrode material, the concentration of the electrolyte, and the formation of a gas at the electrode surface. Oxygen evolution has a high overvoltage, which means that more energy is required to generate oxygen gas than predicted by standard electrode potentials. This is due to the slow kinetics of the four-electron transfer process involved in the oxidation of water to oxygen. The overvoltage phenomenon is important in electrochemical processes as it affects the efficiency and energy consumption of electrolytic reactions.

Inert platinum is used as an electrode material in the electrolysis of dilute sulfuric acid due to its chemical stability and high conductivity. Platinum is inert, meaning it does not react with the electrolyte or the products of electrolysis. This is crucial because the electrode material must remain unchanged during the electrolytic process to ensure consistent results. Additionally, platinum's excellent conductivity allows for efficient electron transfer during the redox reactions occurring at the electrodes. This efficiency is vital for the production of hydrogen and oxygen gases at the cathode and anode, respectively. Using an inert electrode like platinum ensures that the electrolysis process is not contaminated by the electrode material, which might otherwise introduce unwanted chemical reactions and affect the purity of the products.

During the electrolysis of concentrated aqueous sodium chloride, sodium hydroxide (NaOH) concentration increases in the solution due to the reactions occurring at the cathode. When water molecules are reduced at the cathode, they gain electrons to form hydrogen gas (H2) and hydroxide ions (OH⁻). These hydroxide ions remain in the solution. Concurrently, sodium ions (Na⁺) from the sodium chloride are not reduced (they are spectator ions in this process) and remain in the solution. As a result, the solution becomes progressively richer in sodium ions and hydroxide ions, forming sodium hydroxide. This increase in NaOH concentration is a significant aspect of the chlor-alkali process used industrially to produce chlorine gas, hydrogen gas, and sodium hydroxide.

Practice Questions

Describe the products at the anode and the cathode during the electrolysis of concentrated aqueous sodium chloride using inert electrodes. Explain why these particular products are formed.

During the electrolysis of concentrated aqueous sodium chloride, at the anode, chlorine gas is produced. This occurs because chloride ions (Cl⁻) are oxidised, losing electrons to form chlorine gas (Cl2). The presence of chloride ions in high concentration favours their oxidation over water. At the cathode, hydrogen gas is formed. This is a result of the reduction of water molecules, as they gain electrons to form hydrogen gas (H2) and hydroxide ions (OH⁻). The formation of hydroxide ions also contributes to the production of sodium hydroxide in the solution. This process exemplifies the preferential discharge of ions in electrolysis.

In the electrolysis of dilute sulfuric acid using inert electrodes, what are the products at each electrode and why are these particular products formed?

In the electrolysis of dilute sulfuric acid, at the anode, oxygen gas is produced. This is because water is oxidised, splitting into oxygen, hydrogen ions, and electrons. The production of oxygen gas is evident from the generation of bubbles. At the cathode, hydrogen gas is formed through the reduction of hydrogen ions present in the sulfuric acid. They gain electrons to form hydrogen gas. The reason for these specific products is the nature of the ions present in dilute sulfuric acid and their relative ease of discharge based on their electrode potentials. The process is a classic example of the electrolysis of an aqueous solution.

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