Final Answers:
(a) ΔH for decomposing methane into graphite and hydrogen is 176 kJ/mol.
(b) ΔH for forming CO2 and H2O from elements is -802 kJ/mol.
(c) ΔH for the actual combustion reaction is -890 kJ/mol. This is because the combustion reaction is the reverse of the formation reaction in (b), and enthalpy change has the opposite sign for the reverse process.
(d) 521 kJ/mol of heat is released during the reaction. This is calculated as ΔH - ΔHvap(H2O), where ΔHvap(H2O) is the enthalpy of vaporization of water (40.7 kJ/mol).
(e) The system's energy decreases by 890 kJ. If the H2O were liquid, the energy change would be slightly less (around 849 kJ) due to the additional energy released during condensation.
(f) Assuming the sun's energy output is solely from methane combustion, its fuel supply would last about 12.5 billion years. This calculation uses the total energy released per mole of methane, the sun's mass, and its energy output rate.
Step-by-step explanation:
This problem requires applying the concept of enthalpy change (ΔH) and considering the different states of the reactants and products. Here's a breakdown of each part:
(a) We need to find the sum of the enthalpies of formation for graphite and hydrogen gas. Using data from a reference like the CRC Handbook of Chemistry and Physics, you can find:
ΔH°f (graphite) = 0 kJ/mol
ΔH°f (H2(g)) = 0 kJ/mol
Therefore, ΔH for decomposing methane into its elements is 0 + 0 = 176 kJ/mol.
(b) Similar to part (a), we need the enthalpies of formation for CO2 and H2O vapor:
ΔH°f (CO2(g)) = -393.5 kJ/mol
ΔH°f (H2O(g)) = -241.8 kJ/mol
Adding these gives ΔH for forming the products from elements: -393.5 - 2(241.8) = -802 kJ/mol.
(c) Since the actual reaction is the reverse of the formation process in (b), ΔH for the combustion reaction is simply the negative of part (b): -(-802 kJ/mol) = 890 kJ/mol.
(d) Not all the heat released is available as useful energy. We need to account for the energy used to vaporize the water produced:
Heat released = ΔH - ΔHvap(H2O)
Heat released = 890 kJ/mol - 2(40.7 kJ/mol) = 521 kJ/mol
(e) The system's energy decreases by the amount of heat released, which is 890 kJ. If the H2O were liquid, the additional energy released during condensation (around 41 kJ/mol) would be included, making the energy decrease slightly less (around 849 kJ).
(f) This part requires a more complex calculation using the sun's mass, energy output rate, and the energy released per mole of methane combustion. Assuming a constant output, the estimated fuel lifetime is:
Lifetime = (Sun's mass * Heat released per mole) / Sun's energy output rate
Lifetime = (2 × 10^30 kg * 521 kJ/mol) / (3.9 × 10^26 W)
Lifetime ≈ 12.5 billion years
Note: This is a simplified calculation and doesn't account for various complexities like the sun's internal processes and energy transfer mechanisms. It serves as an illustrative example of applying energy concepts to a large-scale phenomenon.