Question

What volume of ${\mathrm{F}}_2$ gas, at ${25}^{\circ }\mathrm{C}$ and 1.00 atm, is produced when molten KF is electrolyzed by a current of 10.0 A for $2.00\mathrm{h}?$ What mass of potassium metal is produced? At which electrode does each reaction occur?

Short answer

The volume of $F_2$ gas produced during the electrolysis of molten KF is 9.13 L, and the mass of potassium metal produced is 14.57 g. Potassium ions are reduced to potassium metal at the cathode, while fluoride ions are oxidized to form $F_2$ gas at the anode.

Step-by-step solution

Convert the time to seconds

Given that the current flows for 2.00 hours, we can convert this time to seconds by using the following conversion factor: $1hour=3600seconds$. Now, we can multiply 2.00 hours with the conversion factor: $$2.00hours\ast 3600\frac{seconds}{hour}=7200seconds$$

Calculate the total charge passed through the electrolyte

Now we need to find the total charge passed through the electrolyte during electrolysis. The given current is 10.0 A, and current is the rate of flow of electric charge. We can use the formula: $$Charge=Current\ast Time$$ Now we can plug in our values for current (10.0 A) and time (7200 s): $$Charge=10.0A\times 7200s=72000C$$

Determine the amount of F2 produced using Faraday's Law

We know that the formation of F2 gas involves two electrons because: $$2F^{-1}\to 1F_2+2e^{-}$$ Using Faraday's Law, which states that the amount of substance produced is directly proportional to the charge (in Columbs) passed through the electrolyte, we can determine the number of moles of produced F2. $$molesofF2=\frac{Charge}{2\times Farada{y}^{\prime }sconstant}$$ Faraday's constant is approximately 96485 C/mol. Now we can plug in our values for charge (72000 C) and Faraday's constant: $$molesofF2=\frac{72000C}{2\times 96485C/mol(e^{-})}=0.373moles$$

Calculate the volume of F2 gas produced using the Ideal Gas Law

Now, we can use the Ideal Gas Law to find the volume of F2 gas produced: $$PV=nRT$$ In this formula, $P$ is the pressure, $V$ is the volume, $n$ is the number of moles, $R$ is the gas constant, and $T$ is the temperature in Kelvin. We are given the pressure as 1.00 atm, the temperature as 25°C, and we've found the number of moles to be 0.373 moles. We need to convert the temperature to Kelvin by adding 273.15: $$T_K={25}^{\circ }\mathrm{C}+273.15=298.15K$$ The gas constant is 0.0821 L atm/mol K. Now we can plug in our values for pressure, moles, gas constant, and temperature into the Ideal Gas Law: $$1.00atm\times V=0.373moles\times 0.0821\frac{Latm}{molK}\times 298.15K$$ Solve for volume, V: $$V=\frac{0.373moles\times 0.0821Latm/molK\times 298.15K}{1.00atm}=9.13L$$

Calculate the mass of potassium metal produced

During the electrolysis of KF, potassium ions are reduced to potassium metal: $$K^{+}+e^{-}\to K$$ Moles of potassium metal produced will be the same as the moles of F2 produced, which is 0.373 moles. Since the molar mass of potassium is approximately 39.10 g/mol, we can calculate the mass of potassium metal produced: $$Massofpotassiummetal=molesofpotassium\times molarmass$$ Now plug in our values for moles of potassium metal (0.373 moles) and the molar mass of potassium: $$Massofpotassiummetal=0.373moles\times 39.10\frac{g}{mol}=14.57g$$

Identify the reaction at each electrode

In the electrolysis of molten KF, the following reduction half-reactions occur: At the cathode (negative electrode), potassium ions are reduced to potassium metal, while at the anode (positive electrode), fluoride ions are oxidized to form F2 gas. In conclusion: - The volume of ${\mathrm{F}}_2$ gas produced is 9.13 L - The mass of potassium metal produced is 14.57 g - Potassium ions are reduced to potassium metal at the cathode, while fluoride ions are oxidized to form F2 gas at the anode.

Key concepts

Understanding Faraday's Law in Electrolysis

Faraday's Law is pivotal in understanding electrolysis, a process used to induce chemical reactions through electricity. In the context of electrolyzing potassium fluoride (KF), this law helps us quantify the relationship between the electrical charge passed through the substance and the amount of product formed. To put it simply,