Electrolysis | Jamb Chemistry
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The table of content below will guide you on the related topics pertaining to "Electrolysis"
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Table of Contents
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Jamb chemistry key points on Electrolytes and non-electrolytes; Faraday’s laws of electrolysis etc
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Electrolytes and Non-Electrolytes
- Electrolytes conduct electricity in molten or aqueous states.
- Examples include acids (HCl), bases (NaOH), and salts (NaCl).
- Electrolytes dissociate into ions in solution.
- Non-electrolytes do not conduct electricity.
- Examples of non-electrolytes are glucose and urea.
- Strong electrolytes fully dissociate into ions.
- Weak electrolytes partially dissociate into ions.
- Non-electrolytes dissolve as neutral molecules.
- Electrolyte strength determines conductivity.
- Conductivity tests differentiate electrolytes from non-electrolytes.
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Faraday’s Laws of Electrolysis
- First Law: The mass of a substance deposited is proportional to the charge passed.
- Second Law: The masses of substances deposited are proportional to their equivalent weights.
- Mathematically: .
- is charge in coulombs, is Faraday’s constant, is molar mass, is valency.
- 1 Faraday equals .
- The number of moles of electrons is .
- Faraday’s laws apply to industrial electrolysis.
- Electrochemical equivalents guide production rates.
- The laws predict deposition amounts in electroplating.
- They are essential for accurate electrolysis calculations.
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Electrolysis of Various Solutions
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Dilute H₂SO₄
- At the cathode: .
- At the anode: .
- Products are hydrogen () and oxygen ().
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Aqueous CuSO₄ (Inert Electrodes)
- Cathode: .
- Anode: .
- Products are copper () and oxygen ().
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Aqueous CuSO₄ (Copper Electrodes)
- Anode: .
- Cathode: .
- Copper is transferred from anode to cathode.
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Aqueous CuCl₂
- Cathode: .
- Anode: .
- Products are copper () and chlorine gas ().
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Dilute NaCl
- Cathode: .
- Anode: .
- Products are hydrogen () and oxygen ().
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Concentrated NaCl
- Cathode: .
- Anode: .
- Products are hydrogen () and chlorine ().
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Fused NaCl
- Cathode: .
- Anode: .
- Products are sodium () and chlorine ().
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Factors Affecting Discharge of Ions
- Ion concentration influences discharge.
- Electrode material determines product formation.
- Lower ions in the electrochemical series discharge preferentially.
- Overvoltage can affect ion discharge sequence.
- Presence of complexing agents modifies ion discharge.
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Calculations Based on Faraday
- Charge is calculated as , where is current, is time.
- Moles of electrons are .
- Amount of product is proportional to moles of electrons.
- determines deposited mass.
- For , per mole of copper.
- Faraday’s constant () relates charge to substance.
- Time for electrolysis is .
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Suitable Electrodes for Different Electrolytes
- Inert electrodes like platinum and graphite are non-reactive.
- Active electrodes like copper participate in reactions.
- Graphite is suitable for NaCl and H₂SO₄ electrolysis.
- Copper electrodes are ideal for CuSO₄ electrolysis.
- Nickel electrodes are used for electroplating.
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Chemical Reactions at the Electrodes
- Cathode reactions are reductions (e.g., ).
- Anode reactions are oxidations (e.g., ).
- Hydrogen gas evolves at cathodes in water-based solutions.
- Oxygen forms at anodes from water oxidation.
- Chlorine forms at the anode from chloride ions.
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Determination of Products at Electrodes
- Ion type determines electrode products.
- The electrochemical series predicts discharge.
- Concentration affects which ions are discharged.
- Water may compete with ions for discharge in aqueous solutions.
- Overvoltage alters predicted products.
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Uses of Electrolysis
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Purification of Metals
- Electrolysis purifies copper in refining processes.
- Impure copper acts as the anode.
- Pure copper is deposited at the cathode.
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Production of Elements
- Electrolysis of NaCl produces sodium and chlorine.
- Water electrolysis yields hydrogen and oxygen.
- Alumina electrolysis produces aluminum.
- Brine electrolysis produces chlorine, hydrogen, and NaOH.
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Electroplating
- Electrolysis deposits thin metal layers on objects.
- The object to be plated is the cathode.
- Electroplating enhances durability and appearance.
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Battery Technology
- Rechargeable batteries use electrolysis for energy storage.
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Corrosion Protection
- Cathodic protection uses electrolysis to prevent rust.
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Industrial Applications
- Hydrogen is produced for fuel cells.
- Chlorine gas is essential for PVC production.
- Sodium hydroxide is used in soaps and detergents.
- Aluminum production uses the Hall-Héroult process.
- Water purification employs electrolysis.
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Biological and Environmental Relevance
- Electrolysis purifies water in desalination plants.
- It plays a role in wastewater treatment.
- Renewable energy powers eco-friendly electrolysis.
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Experimental Observations
- Bubble formation at electrodes indicates gas production.
- Color changes reveal ion movement.
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Miscellaneous
- Faraday’s laws are fundamental in electrochemistry.
- Electrolysis confirms the electrolyte’s activity.
- Conductivity depends on ion presence.
- Industrial electrolysis enhances resource efficiency.
- Electrolysis is key in chemical synthesis.
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Predicting and Testing
- Conductivity tests identify electrolytes.
- Ion migration depends on electrode polarity.
- The electrochemical series guides discharge predictions.
- Electrode material affects reaction type and efficiency.
- Understanding electrolysis is essential for practical applications in chemistry.
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Jamb chemistry Key points on Electrochemical cells; Corrosion as an electrolytic process
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Electrochemical Cells
- Electrochemical cells convert chemical energy into electrical energy.
- They consist of two electrodes: the anode and the cathode.
- Oxidation occurs at the anode, releasing electrons.
- Reduction occurs at the cathode, accepting electrons.
- The flow of electrons creates an electric current.
- A salt bridge maintains charge balance by allowing ion flow between half-cells.
- A galvanic cell is a type of electrochemical cell that generates electricity spontaneously.
- In a Daniell cell, zinc is oxidized (), and copper is reduced ().
- The cell potential is the difference in electrode potentials between the two half-cells.
- Standard conditions for cell operation are 1 M concentration, 25°C, and 1 atm pressure.
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Electrochemical Series
- The electrochemical series ranks elements by their electrode potentials.
- Elements at the top (e.g., ) are strong reducing agents.
- Elements at the bottom (e.g., ) are strong oxidizing agents.
- Potassium () has the most negative electrode potential and is highly reactive.
- Gold () has the most positive electrode potential and is least reactive.
- Metals above hydrogen can displace gas from acids.
- Metals below hydrogen (e.g., ) cannot displace gas.
- The position in the series determines a metal’s reactivity in redox reactions.
- Zinc reacts with dilute acids, as it is above hydrogen in the series.
- Copper does not react with dilute acids, as it is below hydrogen.
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Simple Calculations on Half-Cell Reactions and Electrode Potentials**
- The cell potential () is calculated as:
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- A positive indicates a spontaneous reaction.
- Electrode potential is measured against the standard hydrogen electrode (SHE).
- For and in a Daniell cell:
paragraph - If , the cell can generate electricity.
- Standard electrode potentials help predict redox reaction feasibility.
- The Nernst equation calculates potentials under non-standard conditions:
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- Half-cell reactions are balanced for mass and charge to determine .
- Gibbs free energy is related to cell potential:
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- A negative indicates a thermodynamically favorable reaction.
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Corrosion as an Electrolytic Process
- Corrosion is the deterioration of metals due to chemical reactions with the environment.
- It involves electrochemical reactions where the metal acts as an anode.
- At the anodic site, metal oxidizes to ions (e.g., ).
- At the cathodic site, oxygen is reduced ().
- Moisture and electrolytes accelerate corrosion.
- Iron forms rust () due to reaction with oxygen and water.
- Corrosion weakens metal structures and reduces their lifespan.
- High humidity, salts, and acids exacerbate corrosion.
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Cathodic Protection of Metals
- Cathodic protection prevents corrosion by making the metal act as a cathode.
- Sacrificial anodes (e.g., ) corrode in place of the protected metal.
- The sacrificial anode donates electrons to the protected metal.
- Impressed current systems use an external power source to supply electrons.
- Cathodic protection is widely used for pipelines and ship hulls.
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Painting, Electroplating, and Coating with Grease or Oil to Prevent Corrosion
- Painting creates a barrier, protecting metal from air and moisture.
- Paint coatings are used in automotive and construction industries.
- Electroplating coats metals with a thin protective layer (e.g., chrome or zinc).
- Electroplating improves corrosion resistance and aesthetic appeal.
- Grease and oil act as temporary barriers against moisture.
- Lubricants protect moving parts from rusting.
- These methods enhance metal durability and reduce maintenance costs.
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Applications of Electrolytic Processes
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Industrial Applications
- Electrolysis is used to produce metals like aluminum (Hall-Héroult process).
- Sodium is obtained via electrolysis of molten NaCl.
- Electrolysis of brine produces chlorine, hydrogen, and NaOH.
- Purification of copper involves electrolysis in electrolytic refining.
- Zinc is purified using electrolytic methods.
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Electroplating
- Electroplating enhances durability and corrosion resistance.
- Jewelry is electroplated with gold or silver for aesthetic value.
- Chromium plating provides a shiny, hard surface.
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Water Treatment
- Electrolysis purifies water by breaking down contaminants.
- Desalination plants use electrolytic processes for fresh water production.
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Energy Storage
- Electrolytic cells are used in rechargeable batteries (e.g., -ion batteries).
- Hydrogen fuel cells involve electrolysis to produce for clean energy.
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Electrochemical Sensors
- Electrochemical cells detect gases like oxygen and carbon dioxide.
- Glucose sensors for diabetes monitoring use electrochemical principles.
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Biological and Environmental Applications
- Electrochemical processes help in wastewater treatment.
- Electrolysis removes heavy metals from industrial effluents.
- It is used in the electrochemical remediation of polluted soil.
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Experimental and Laboratory Uses
- Electrolysis demonstrates redox reactions in educational experiments.
- Electrochemical cells measure thermodynamic properties of reactions.
- Electrolysis confirms the presence of electrolytes in solutions.
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Corrosion Prevention Beyond Cathodic Protection
- Alloying metals like stainless steel reduces corrosion susceptibility.
- Anodization forms a protective oxide layer on aluminum.
- Galvanizing coats steel with zinc for corrosion resistance.
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Advanced Electrochemical Applications
- Electrochemical processes synthesize chemicals like hydrogen peroxide.
- Electrolysis produces industrial gases like oxygen and chlorine.
- Electrochemical machining shapes metals with precision.
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Miscellaneous
- Electrochemical series predicts reactivity trends in metals.
- Understanding half-cell reactions optimizes battery efficiency.
- Corrosion control saves industries billions annually.
- Electrochemical applications are vital in sustainable energy solutions.
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- Jamb Chemistry Key Points on Energy Changes
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This is all we can take on "Jamb Chemistry Key Points on Electrolysis"
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