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1. Intro to General Chemistry3h 48m
2. Atoms & Elements4h 16m
3. Chemical Reactions4h 10m
4. BONUS: Lab Techniques and Procedures1h 38m
5. BONUS: Mathematical Operations and Functions48m
6. Chemical Quantities & Aqueous Reactions3h 53m
7. Gases3h 49m
8. Thermochemistry2h 37m
9. Quantum Mechanics2h 58m
10. Periodic Properties of the Elements3h 9m
11. Bonding & Molecular Structure3h 29m
12. Molecular Shapes & Valence Bond Theory1h 57m
13. Liquids, Solids & Intermolecular Forces2h 23m
14. Solutions3h 1m
15. Chemical Kinetics2h 53m
16. Chemical Equilibrium2h 29m
17. Acid and Base Equilibrium5h 1m
18. Aqueous Equilibrium4h 47m
19. Chemical Thermodynamics1h 50m
20. Electrochemistry2h 42m
21. Nuclear Chemistry2h 36m
22. Organic Chemistry5h 7m
23. Chemistry of the Nonmetals2h 39m
24. Transition Metals and Coordination Compounds3h 16m

20. Electrochemistry

Standard Reduction Potentials

20. Electrochemistry

Standard Reduction Potentials: Videos & Practice Problems

Video Lessons Practice Worksheet

Topic summary

Oxidation and reduction are chemical processes where oxidation refers to the loss of electrons, and reduction is the gain of electrons. The tendency for these reactions to occur can be measured using standard reduction potentials (E°), which are determined under standard conditions (25°C, 1 atmosphere, 1 M concentration, pH 7). A higher E° value indicates a greater likelihood of reduction. The standard hydrogen electrode (SHE), with an E° of zero, serves as a reference point. Elements with E° values above zero are strong oxidizing agents, as they readily gain electrons, whereas those with E° values below zero are strong reducing agents, more likely to lose electrons. This concept is crucial for understanding the electrochemical behavior of elements and compounds, predicting the direction of redox reactions, and identifying the role substances play as either oxidizing or reducing agents in chemical processes.

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Standard Reduction Potentials

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Standard Reduction Potentials Video Summary

Oxidation and reduction are fundamental concepts in chemistry, where oxidation refers to the loss of electrons and reduction signifies the gain of electrons. These processes are crucial in various chemical reactions, particularly in redox (reduction-oxidation) reactions. A key aspect of understanding these reactions is the concept of standard reduction potential, denoted as $ E^\circ_{\text{red}} $. This value indicates the tendency of a species to gain electrons under standard conditions.

Standard conditions are defined as a temperature of 25 degrees Celsius, a pressure of 1 atmosphere, a concentration of 1 molarity, and a pH of 7. The standard reduction potential is measured under these conditions, allowing for consistent comparisons between different species. A higher standard reduction potential value indicates a greater likelihood for reduction to occur, meaning that the species is more inclined to gain electrons.

When comparing various elements and compounds, their standard reduction potentials can provide insight into their reactivity and the direction of electron flow in redox reactions. Understanding these potentials is essential for predicting the outcomes of chemical reactions and for applications in electrochemistry, such as in batteries and electrolysis.

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Comparing Standard Reduction Potentials

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Comparing Standard Reduction Potentials Video Summary

In electrochemistry, standard reduction potentials are crucial for understanding the tendency of different elements to undergo reduction. Each element's potential is represented as a half-reaction, indicating the gain of electrons. For instance, in the case of fluorine (F₂), its transition from a neutral state (oxidation number 0) to a charged state (oxidation number -1) signifies a reduction process, as the oxidation number decreases. A key mnemonic to remember is that when electrons are reactants in a half-reaction, it indicates reduction, linking the letter 'R' in reduction with 'R' in reactants.

The standard reduction potential of fluorine is notably high, making it the strongest oxidizing agent among the elements listed. In contrast, lithium exhibits the lowest standard reduction potential, indicating a greater likelihood of oxidation. The standard hydrogen electrode (SHE), which has a potential of 0 V, serves as a reference point for comparing other elements. Elements with reduction potentials above 0 V are more likely to be reduced, while those below 0 V are more inclined to undergo oxidation.

As one moves up the list of standard reduction potentials, the ability of an element to be reduced increases, thereby enhancing its strength as an oxidizing agent. Conversely, moving down the list indicates a decrease in reduction potential, making oxidation more likely and increasing the strength of the element as a reducing agent. This relationship is essential for predicting the behavior of elements in redox reactions, where the oxidizing agent is reduced and the reducing agent is oxidized.

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Standard Reduction Potentials Example

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Standard Reduction Potentials Example Video Summary

When determining which species is least likely to donate an electron, we are essentially identifying the one that is least likely to undergo oxidation. Oxidation involves the loss of electrons, meaning that a species donating an electron is being oxidized. In this context, the species that is least likely to be oxidized is the one that is more likely to be reduced, which can be assessed through its standard reduction potential.

The standard reduction potential is a measure of the tendency of a chemical species to acquire electrons and thereby be reduced. A higher standard reduction potential indicates a greater likelihood of reduction and a lower likelihood of oxidation. In this case, we compare the standard reduction potentials of the following species:

H₂ (0 volts)
Br₂ (1.09 volts)
Zn²⁺ (0.76 volts)
Cl₂ (1.36 volts)
Li⁺ (-3.04 volts)

Among these, chlorine (Cl₂) has the highest standard reduction potential at 1.36 volts, making it the species most likely to be reduced and, consequently, the least likely to be oxidized. Therefore, the answer to the question is that Cl₂ is the species that will least likely donate an electron.

Problem

Rank the given metal ions in order of increasing strength as an oxidizing agent.
Pb²⁺ (-0.13 V), Mn²⁺ (-1.18 V), Cu²⁺ (+0.16 V), Co³⁺ (+1.82 V), Fe³⁺(+0.77 V)

Pb2+ < Cu2+ < Mn2+ < Co3+ < Fe3+

Co3+ < Fe3+ < Cu2+ < Pb2+ < Mn2+

Mn2+ < Pb2+ < Cu2+ < Fe3+ < Co3+

Mn2+ < Pb2+ < Cu2+ < Co3+ < Fe3+

Problem

Determine which species can oxidize Br₂.

Fe3+

Ni2+

H+

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Standard Reduction Potentials definitions
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Which statement is true about standard reduction potentials?

Standard reduction potentials (SRPs) are values that reflect the tendency of a chemical species to gain electrons and thereby be reduced. A positive standard reduction potential indicates that a species is more likely to be reduced (gain electrons), and it is a stronger oxidizing agent. Conversely, a negative standard reduction potential suggests that the species is less likely to gain electrons and is a stronger reducing agent. These potentials are measured under standard conditions, which are 25 degrees Celsius, a 1 M concentration for each ion participating in the reaction, and a pressure of 1 atmosphere for any gases involved. SRPs are tabulated with reference to the standard hydrogen electrode (SHE), which is assigned a potential of 0 volts. By comparing the SRPs of different half-reactions, you can predict the direction of electron flow in a redox reaction and determine which species will be oxidized and which will be reduced.

Given the standard electrode reduction potentials, which reaction will occur spontaneously?

To determine if a reaction will occur spontaneously based on standard electrode potentials (also known as standard reduction potentials), you need to compare the potentials of the two half-reactions involved.

A spontaneous reaction in electrochemistry is one that has a positive cell potential, $E_{cell}$ . The cell potential is calculated using the formula:

E_{cell} = E_{cathode} - E_{anode}

Here, $E_{cathode}$ is the reduction potential of the cathode (where reduction occurs), and $E_{anode}$ is the reduction potential of the anode (where oxidation occurs). However, since the anode is actually being oxidized, you need to reverse the sign of its standard reduction potential when you use it in the equation.

If the difference $(E_{cathode} - E_{anode})$ is positive, the reaction will proceed spontaneously. If it is negative, the reaction is non-spontaneous under standard conditions. Remember that standard conditions mean all solutes are at 1 M concentration, all gases are at 1 atm pressure, and the temperature is 298 K (25°C).

Which statements are true regarding standard reduction potentials? Which ones should be selected?

Standard reduction potentials (E°) are a measure of the tendency of a chemical species to be reduced, and are measured in volts. Here are some true statements about standard reduction potentials:

Standard reduction potentials are measured under standard conditions, which are 25°C, 1 M concentration for each ion participating in the reaction, a pressure of 1 atm for any gases involved, and a pure solid or liquid for each pure substance.
A positive standard reduction potential indicates that a species has a greater tendency to gain electrons and be reduced, while a negative value suggests it is less likely to gain electrons.
The more positive the reduction potential, the stronger the oxidizing agent. Conversely, the more negative the reduction potential, the stronger the reducing agent.
The standard hydrogen electrode (SHE) has a standard reduction potential of 0 volts by definition, and it serves as the reference electrode against which all other electrode potentials are measured.
Standard reduction potentials can be used to predict the direction of a redox reaction; a spontaneous reaction will have a positive cell potential when the potentials are combined.
When using standard reduction potentials to determine the feasibility of a reaction, the species with the higher reduction potential will be reduced, and the one with the lower reduction potential will be oxidized.