Glossary

1.3 Basic Concepts of Oxidation and Reduction

3 min readjuly 23, 2024

and are key processes in electrochemistry. They involve the transfer of electrons between species, changing their oxidation states. Understanding these concepts is crucial for grasping how batteries work and how chemical reactions occur.

Oxidizing and reducing agents play vital roles in these electron transfers. Oxidizing agents accept electrons, while reducing agents donate them. Knowing how to identify and balance these reactions is essential for predicting and controlling chemical processes in various applications.

Oxidation and Reduction Fundamentals

Oxidation and reduction definitions

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  • Oxidation involves the loss of electrons from a species resulting in an increase in its
    • Occurs at the in an electrochemical cell (battery)
    • Examples: Fe2+Fe3++eFe^{2+} \rightarrow Fe^{3+} + e^-, 2ClCl2+2e2Cl^- \rightarrow Cl_2 + 2e^-
  • Reduction involves the gain of electrons by a species resulting in a decrease in its oxidation number
    • Occurs at the in an electrochemical cell
    • Examples: Cu2++2eCuCu^{2+} + 2e^- \rightarrow Cu, 2H++2eH22H^+ + 2e^- \rightarrow H_2
  • Mnemonic device OIL RIG helps remember Oxidation Is Loss of electrons and Reduction Is Gain of electrons

Oxidizing and reducing agents

  • Oxidizing agent (oxidant) is a species that accepts electrons causing the oxidation of another species and is reduced in the process
    • Examples: H2O2H_2O_2 in the reaction 2Fe2++H2O2+2H+2Fe3++2H2O2Fe^{2+} + H_2O_2 + 2H^+ \rightarrow 2Fe^{3+} + 2H_2O, MnO4MnO_4^- in the reaction 5Fe2++MnO4+8H+5Fe3++Mn2++4H2O5Fe^{2+} + MnO_4^- + 8H^+ \rightarrow 5Fe^{3+} + Mn^{2+} + 4H_2O
  • Reducing agent (reductant) is a species that donates electrons causing the reduction of another species and is oxidized in the process
    • Examples: NaNa in the reaction 2Na+Cl22NaCl2Na + Cl_2 \rightarrow 2NaCl, Sn2+Sn^{2+} in the reaction Sn2++2Fe3+Sn4++2Fe2+Sn^{2+} + 2Fe^{3+} \rightarrow Sn^{4+} + 2Fe^{2+}

Oxidation numbers in compounds

  • Rules for assigning oxidation numbers to elements in compounds:
    1. Free elements have an oxidation number of 0 (NaNa, H2H_2, O2O_2)
    2. Monatomic ions have an oxidation number equal to their charge (Na+Na^+ is +1, ClCl^- is -1)
    3. Hydrogen has an oxidation number of +1 except in metal hydrides where it is -1 (NaHNaH)
    4. Oxygen has an oxidation number of -2 except in peroxides where it is -1 (H2O2H_2O_2) and in compounds with fluorine (OF2OF_2)
    5. Fluorine always has an oxidation number of -1 (HFHF, SF6SF_6)
    6. In neutral compounds, the sum of oxidation numbers must equal 0 (KMnO4KMnO_4: +1 + +7 + 4(-2) = 0)
    7. In polyatomic ions, the sum of oxidation numbers must equal the charge of the ion (SO42SO_4^{2-}: +6 + 4(-2) = -2)

Balancing half-reactions

  • Half-reactions separate oxidation and reduction processes
    • Oxidation half-reaction shows the species losing electrons (ZnZn2++2eZn \rightarrow Zn^{2+} + 2e^-)
    • Reduction half-reaction shows the species gaining electrons (Cu2++2eCuCu^{2+} + 2e^- \rightarrow Cu)
  • Steps to balance half-reactions:
    1. Balance atoms other than H and O (Cr2O722Cr3+Cr_2O_7^{2-} \rightarrow 2Cr^{3+})
    2. Balance oxygen atoms by adding H2OH_2O (Cr2O72+14H+2Cr3++7H2OCr_2O_7^{2-} + 14H^+ \rightarrow 2Cr^{3+} + 7H_2O)
    3. Balance hydrogen atoms by adding H+H^+ ions (already balanced in the previous step)
    4. Balance charge by adding electrons (Cr2O72+14H++6e2Cr3++7H2OCr_2O_7^{2-} + 14H^+ + 6e^- \rightarrow 2Cr^{3+} + 7H_2O)
  • Combining half-reactions:
    1. Multiply half-reactions to equalize electrons transferred
    2. Add half-reactions together
    3. Cancel out common terms
    4. Verify that atoms and charges are balanced

Key Terms to Review (17)

Anode: The anode is the electrode where oxidation occurs in an electrochemical cell, serving as the site for the loss of electrons during the redox reaction. This term is crucial in understanding various electrochemical systems, as it plays a key role in the flow of electrons and the overall functioning of batteries and fuel cells.
Cathode: The cathode is the electrode in an electrochemical cell where reduction occurs, meaning it gains electrons. This process is essential for battery operation, fuel cells, and other electrochemical systems, as it directly impacts energy transfer and storage.
Cell Potential: Cell potential, also known as electromotive force (EMF), is the measure of the ability of an electrochemical cell to produce an electric current. It reflects the difference in potential energy between the oxidation and reduction reactions occurring within the cell, impacting the efficiency and direction of electron flow. A higher cell potential indicates a greater driving force for the electrochemical reaction, which is crucial in understanding the behavior and performance of various electrochemical systems.
Disproportionation Reaction: A disproportionation reaction is a specific type of redox reaction in which a single substance is simultaneously oxidized and reduced, resulting in two different products. This kind of reaction showcases the intricate balance between oxidation and reduction processes, where the same element undergoes a change in oxidation state, leading to distinct chemical species being formed from it.
Electron acceptor: An electron acceptor is a substance that gains electrons in a chemical reaction, typically during redox (reduction-oxidation) processes. In these reactions, the electron acceptor undergoes reduction as it receives electrons from an electron donor, facilitating the transfer of energy and enabling various biological and electrochemical processes.
Electron donor: An electron donor is a substance that loses electrons in a chemical reaction, typically during an oxidation-reduction (redox) process. This loss of electrons allows the electron donor to become oxidized while simultaneously providing electrons to another species, which is reduced. The concept is crucial in understanding redox reactions as it highlights the transfer of electrons between different chemical species.
Enthalpy Change: Enthalpy change refers to the amount of energy absorbed or released during a chemical reaction at constant pressure, usually measured in joules or kilojoules. It plays a crucial role in understanding energy transformations in electrochemical reactions, linking thermodynamics with electrochemistry. The concept helps explain how changes in enthalpy influence cell potentials and reaction spontaneity, especially when considering the Nernst equation and standard state conditions.
Faraday's Laws of Electrolysis: Faraday's Laws of Electrolysis describe the relationship between the amount of substance transformed during electrolysis and the quantity of electric charge passed through the system. These laws are foundational in understanding how electrochemical processes work, including the principles behind different electrochemical cells, redox reactions, and practical applications like electroplating and voltammetry.
Free Energy Change: Free energy change refers to the difference in energy available to do work during a chemical reaction, taking into account both enthalpy and entropy. It provides a measure of spontaneity for a reaction; if the free energy change is negative, the reaction can occur spontaneously, whereas a positive value indicates that the reaction is non-spontaneous under standard conditions. Understanding free energy change is crucial for predicting the behavior of oxidation and reduction processes.
Nernst Equation: The Nernst Equation is a fundamental relationship in electrochemistry that allows the calculation of the electromotive force (EMF) of an electrochemical cell under non-standard conditions. It connects the concentration of reactants and products to the cell potential, providing insights into how changes in concentration and temperature affect electrode potentials and overall cell behavior.
Oxidation: Oxidation is a chemical process where an atom, ion, or molecule loses electrons, resulting in an increase in oxidation state. This process plays a crucial role in various electrochemical reactions, linking to key concepts such as redox reactions, electrode potentials, and the transfer of energy in electrochemical cells.
Oxidation number: An oxidation number is a theoretical charge that an atom would have if all bonds to atoms of different elements were fully ionic. This concept helps in understanding redox reactions and determining how electrons are transferred in chemical processes. It is crucial in identifying which species are oxidized and reduced during reactions, thus playing a significant role in analyzing half-cell reactions and the overall electron flow.
Oxidation state: The oxidation state, also known as oxidation number, indicates the degree of oxidation of an atom in a chemical compound. It reflects the number of electrons an atom has gained, lost, or shared when forming chemical bonds, helping to identify the nature of reactions such as redox processes. This concept is crucial in understanding how substances react, particularly in distinguishing between oxidizing and reducing agents during reactions.
Potassium permanganate: Potassium permanganate is a chemical compound with the formula KMnO₄, known for its deep purple color and strong oxidizing properties. This compound is commonly used in various applications, including water treatment, disinfectants, and as a reagent in chemical reactions due to its ability to accept electrons during redox processes.
Redox Reaction: A redox reaction, short for reduction-oxidation reaction, is a chemical process in which the oxidation states of one or more species are changed through the transfer of electrons. In these reactions, one species is reduced (gains electrons) while another is oxidized (loses electrons), making them essential in various electrochemical applications.
Reduction: Reduction is a chemical process in which a substance gains electrons, resulting in a decrease in oxidation state. This concept is essential in various electrochemical processes, as it forms the basis of redox reactions, where reduction occurs alongside oxidation.
Sodium thiosulfate: Sodium thiosulfate is a chemical compound with the formula Na2S2O3, commonly used as a reducing agent in various chemical reactions. It plays a significant role in redox reactions, particularly where it can act as a source of thiosulfate ions, which can reduce other substances by donating electrons, thus connecting it to the core concepts of oxidation and reduction.
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