What voltage can theoretically be achieved in a battery in which lithium metal is oxidized and fluorine gas is reduced, and why might such a battery be difficult to produce?

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Identify the half-reactions for the oxidation and reduction processes. For lithium, the oxidation half-reaction is: \( \text{Li} \rightarrow \text{Li}^+ + \text{e}^- \). For fluorine, the reduction half-reaction is: \( \text{F}_2 + 2\text{e}^- \rightarrow 2\text{F}^- \).

Look up the standard reduction potentials for each half-reaction. The standard reduction potential for \( \text{Li}^+ + \text{e}^- \rightarrow \text{Li} \) is approximately -3.04 V, and for \( \text{F}_2 + 2\text{e}^- \rightarrow 2\text{F}^- \) is approximately +2.87 V.

Calculate the standard cell potential (\( E^\circ_{\text{cell}} \)) by using the formula: \( E^\circ_{\text{cell}} = E^\circ_{\text{cathode}} - E^\circ_{\text{anode}} \). Substitute the values: \( E^\circ_{\text{cell}} = 2.87 \text{ V} - (-3.04 \text{ V}) \).

Discuss why such a battery might be difficult to produce. Consider factors like the reactivity of lithium metal, which is highly reactive and can pose safety risks, and the handling of fluorine gas, which is corrosive and toxic.

Conclude by considering the practical challenges in manufacturing and safely operating a battery with such reactive materials, despite the high theoretical voltage.

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Electrochemical Cells

Electrochemical cells convert chemical energy into electrical energy through redox reactions. In a battery, oxidation occurs at the anode and reduction at the cathode. The voltage produced by a battery is determined by the difference in reduction potentials of the two half-reactions involved, which can be calculated using standard electrode potentials.

Standard Electrode Potentials

Standard electrode potentials are measured under standard conditions and indicate the tendency of a species to be reduced. The more positive the potential, the greater the species' ability to gain electrons. For lithium and fluorine, lithium has a very negative standard reduction potential, while fluorine has a very positive one, leading to a high theoretical voltage when combined in a battery.

Practical Challenges in Battery Production

While the theoretical voltage of a lithium-fluorine battery is high, practical challenges arise in its production. Lithium is highly reactive, and fluorine is extremely corrosive and toxic, making safe handling and containment difficult. Additionally, the formation of lithium fluoride during the reaction can hinder the battery's performance and longevity, complicating the design of a viable battery.

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