Electrolysis

Gbogbo ọrọ náà

Electrolysis is a fundamental topic in chemistry that delves into the study of chemical reactions triggered by the flow of electric current through an electrolyte. To grasp the concept of electrolysis, one must first distinguish between electrolytes and non-electrolytes. Electrolytes are substances that conduct electricity when dissolved in water or molten, while non-electrolytes do not conduct electricity under similar conditions.

Understanding the Faraday's laws of electrolysis is crucial in predicting and analyzing the outcomes of electrolysis reactions. Faraday's first law states that the amount of a substance produced during electrolysis is directly proportional to the quantity of electricity passed through the electrolyte. Meanwhile, Faraday's second law establishes the relationship between the amounts of different substances produced by the same quantity of electricity.

During electrolysis, various electrolytes can be subjected to the process, such as dilute sulfuric acid (H2SO4), aqueous copper sulfate (CuSO4), copper chloride (CuCl2), sodium chloride (NaCl) solutions in different concentrations, and fused sodium chloride (NaCl). Each electrolyte presents unique reactions at the electrodes, yielding specific products based on the discharge of ions.

Factors affecting the discharge of ions at the electrodes play a crucial role in determining the products of electrolysis. These factors include the nature of the electrolyte, concentration, temperature, and electrode material. The ability to specify the suitable electrodes for different electrolytes and predict the chemical reactions at the electrodes are vital skills in mastering electrolysis.

Electrolysis finds various practical applications, such as the purification of metals like copper and the production of essential elements and compounds like aluminum (Al), sodium (Na), oxygen (O2), chlorine (Cl2), and sodium hydroxide (NaOH). These applications highlight the significance of electrolysis in industrial processes and material synthesis.

Furthermore, the study of electrochemical cells provides insights into redox reactions, electrode potentials, and half-cell reactions involving a range of metals such as potassium (K), calcium (Ca), zinc (Zn), iron (Fe), copper (Cu), and silver (Ag). Simple calculations involving electrode potentials enable the determination of the feasibility of different cell reactions.

Corrosion, often viewed as an electrolytic process, poses significant challenges in maintaining the integrity of metals. Techniques like cathodic protection, painting, electroplating, and the application of grease or oil serve as effective methods to prevent iron from corrosion, ensuring the longevity and durability of metal structures.

In conclusion, the comprehensive study of electrolysis not only enhances our understanding of chemical reactions under electrical influence but also equips us with practical knowledge applicable in various industries and everyday scenarios.

Ebumnobi

  1. Identify Suitable Electrodes for Different Electrolytes
  2. Specify the Chemical Reactions at the Electrodes
  3. Perform Calculations Based on Faraday as a Mole of Electrons
  4. Identify the Factors that Affect the Products of Electrolysis
  5. Determine the Different Areas of Application of Electrolytic Processes
  6. Distinguish Between Electrolytes and Non-Electrolytes
  7. Identify Methods Used in Protecting Metals
  8. Identify the Various Electrochemical Cells
  9. Determine the Products at the Electrodes
  10. Specify the Different Areas of Application of Electrolysis
  11. Calculate Electrode Potentials Using Half-Cell Reaction Equations

Akọmọ Ojú-ẹkọ

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Ayẹwo Ẹkọ

Ekele diri gi maka imecha ihe karịrị na Electrolysis. Ugbu a na ị na-enyochakwa isi echiche na echiche ndị dị mkpa, ọ bụ oge iji nwalee ihe ị ma. Ngwa a na-enye ụdị ajụjụ ọmụmụ dị iche iche emebere iji kwado nghọta gị wee nyere gị aka ịmata otú ị ghọtara ihe ndị a kụziri.

Ị ga-ahụ ngwakọta nke ụdị ajụjụ dị iche iche, gụnyere ajụjụ chọrọ ịhọrọ otu n’ime ọtụtụ azịza, ajụjụ chọrọ mkpirisi azịza, na ajụjụ ede ede. A na-arụpụta ajụjụ ọ bụla nke ọma iji nwalee akụkụ dị iche iche nke ihe ọmụma gị na nkà nke ịtụgharị uche.

Jiri akụkụ a nke nyocha ka ohere iji kụziere ihe ị matara banyere isiokwu ahụ ma chọpụta ebe ọ bụla ị nwere ike ịchọ ọmụmụ ihe ọzọ. Ekwela ka nsogbu ọ bụla ị na-eche ihu mee ka ị daa mba; kama, lee ha anya dị ka ohere maka ịzụlite onwe gị na imeziwanye.

  1. What is the process of electrolysis? A. A chemical reaction involving the passage of an electric current through an electrolyte B. A physical change of state of matter C. A biological process in living organisms D. A mechanical separation of substances Answer: A. A chemical reaction involving the passage of an electric current through an electrolyte
  2. Which of the following is a non-electrolyte? A. NaCl B. H2SO4 C. C6H12O6 D. KOH Answer: C. C6H12O6
  3. What are the Faraday's laws of electrolysis mainly concerned with? A. Relationship between electrode potential and electrode materials B. Rate of reaction in electrolyte solutions C. Amount of substance produced or consumed during electrolysis D. The color changes that occur during electrolysis Answer: C. Amount of substance produced or consumed during electrolysis
  4. In the electrolysis of dilute H2SO4, what gas is evolved at the anode? A. Hydrogen gas B. Oxygen gas C. Sulfur dioxide gas D. Nitrogen gas Answer: B. Oxygen gas
  5. Which factor does not affect the products of electrolysis? A. Nature of the electrolyte B. Concentration of the electrolyte C. Temperature D. Size of the electrodes Answer: D. Size of the electrodes
  6. During the electrolysis of aqueous CuCl2 solution, what is discharged at the cathode? A. Copper metal B. Chlorine gas C. Copper ions D. Chloride ions Answer: A. Copper metal
  7. What is the main purpose of the purification of metals like copper using electrolysis? A. To increase the electrical conductivity of the metal B. To separate the metal from impurities C. To change the color of the metal D. To reduce the melting point of the metal Answer: B. To separate the metal from impurities
  8. In the electrolysis of fused NaCl, what gas is evolved at the anode? A. Hydrogen gas B. Oxygen gas C. Chlorine gas D. Sodium gas Answer: C. Chlorine gas
  9. Which of the following is not a use of electrolysis? A. Purification of metals B. Production of oxygen C. Production of salts D. Production of sodium hydroxide Answer: C. Production of salts
  10. What is the purpose of cathodic protection of metals against corrosion? A. To increase the rate of corrosion B. To form a barrier of non-conductive material on the metal surface C. To provide a sacrificial metal that corrodes instead of the protected metal D. To remove the metal from the corrosive environment Answer: C. To provide a sacrificial metal that corrodes instead of the protected metal

Àwọn Ìwé Tó Dáa Láti Kà

Chemistry: The Central Science
Chemistry: The Central Science
Ìkọ̀wé-àbáojú: Electrochemistry Section
Onkọwe atẹjade: Pearson
Afọ: 2020
ISBN: 9780134988533
Electrochemistry
Electrochemistry
Ìkọ̀wé-àbáojú: Fundamentals and Applications
Onkọwe atẹjade: Springer
Afọ: 2019
ISBN: 9783319239119

Àwọn Ìbéèrè Tó Ti Kọjá

Nna, you dey wonder how past questions for this topic be? Here be some questions about Electrolysis from previous years.

JAMB UTME - Chemistry - 2024

Ajụjụ 1 Ripọtì

Calculate the number of moles of Copper that will be deposited, if 2 Faraday of electricity is passed through the copper during the electrolysis of copper(II)tetraoxosulphate(VI) 

[1F = 96500C ]

Wo Idahun
WAEC SSCE - Chemistry - 2022

Ajụjụ 1 Ripọtì

Determine the quantity of electricity used when a current of 0.20 amperes is passed through an electrolytic cell for 60 minutes.

Wo Idahun