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Chapter 9: Problem 49

When 2.50 g of methane burns in oxygen, 125 kJ of heat is produced. What is the enthalpy of combustion per mole of methane under these conditions?

Short Answer

Expert verified
The enthalpy of combustion per mole of methane under these conditions is approximately 802.31 kJ/mol.

Step by step solution

01

Identify the given information

First, determine the given information from the exercise. The mass of methane that was burned is 2.50 g, and the energy released is 125 kJ.
02

Calculate moles of methane

Calculate the number of moles of methane burned using the molar mass of methane (CH4), which is approximately 16.04 g/mol. This is done by dividing the mass of methane by its molar mass: number of moles = \( \frac{mass}{molar\ mass} \) = \( \frac{2.50\ g}{16.04\ g/mol} \).
03

Determine the enthalpy of combustion per mole

With the amount of heat released and the number of moles of methane calculated, find the enthalpy of combustion per mole of methane by dividing the energy released by the number of moles: \( \Delta H \) per mole = \( \frac{Energy\ released}{Number\ of\ moles} \).
04

Perform the calculations

Perform the actual calculations from the previous steps: number of moles = \( \frac{2.50}{16.04} \) = 0.1558 mol (rounded to 4 decimal places). Then calculate the enthalpy of combustion per mole: \( \Delta H \) per mole = \( \frac{125\ kJ}{0.1558\ mol} \) = 802.31 kJ/mol (rounded to 2 decimal places).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Stoichiometry
Understanding stoichiometry is fundamental when exploring chemical reactions and, in particular, when calculating the enthalpy of combustion. Stoichiometry refers to the calculation of reactants and products in chemical reactions. It is the 'recipe' for a chemical reaction, dictating the proportionate amounts of substances needed.

For instance, when burning methane (CH4), stoichiometry helps us determine how much methane reacts with oxygen to produce carbon dioxide and water, releasing energy. In the textbook exercise, we saw the importance of stoichiometry when the mass of methane (2.50 g) was converted to moles. Without stoichiometry, we wouldn't know how that mass relates to the energy released.

It's like baking: knowing the exact amount of each ingredient necessary to achieve the desired outcome. Similarly, in stoichiometry, our 'ingredients' are the masses and moles of reactants and products; our 'desired outcome' is understanding the reaction's energetics, in this case, the enthalpy of combustion.
Chemical Thermodynamics
Chemical thermodynamics is the branch of science that deals with the relationship between heat and other forms of energy in chemical processes. It's crucial for interpreting the enthalpy of combustion—a key thermodynamic quantity that reflects the total heat exchanged in a chemical reaction when substances burn in an environment at constant pressure.

In our example, when 2.50 g of methane is burned, the energy released is quantified as 125 kJ. Chemical thermodynamics tells us that this 'heat content' change, as gases react with oxygen, is the reaction's enthalpy change, denoted as \( \Delta H \).

Unraveling this part of chemical thermodynamics allows us to connect the dots between the microscopic (molecular) level and the macroscopic phenomena we can measure, like temperature change and heat production, making it indispensable for understanding energy flow in reactions.
Energy in Chemical Reactions
When we discuss energy in chemical reactions, we're chiefly talking about how energy is transferred during the process of breaking and forming chemical bonds. All chemical reactions involve changes in energy, and these are generally categorized as either exothermic (releasing heat) or endothermic (absorbing heat).

The combustion of methane is an exemplary exothermic reaction, turning chemical potential energy stored in methane's bonds into kinetic energy, which we detect as heat and light. The 'enthalpy of combustion' is a specific term for the energy change that occurs when a substance combusts in oxygen.

In the example, a known mass of methane (2.50 g) combusted to release 125 kJ of energy. By understanding how to relate mass to moles (stoichiometry), and considering the principles of chemical thermodynamics, we can express this energy release on a per-mole basis, which is vital for chemists to compare the energy profiles of different reactions and fuels.

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Most popular questions from this chapter

Calculate \(\Delta H^{\circ}\) for the process \(\mathrm{Zn}(s)+\mathrm{S}(s)+2 \mathrm{O}_{2}(g) \longrightarrow \mathrm{ZnSO}_{4}(s)\) from the following information: \(\mathrm{Zn}(s)+\mathrm{S}(s) \longrightarrow \mathrm{ZnS}(s) \quad \Delta H^{\circ}=-206.0 \mathrm{kJ}\) \(\mathrm{ZnS}(s)+2 \mathrm{O}_{2}(g) \longrightarrow \mathrm{ZnSO}_{4}(s) \quad \Delta H^{\circ}=-776.8 \mathrm{kJ}\)

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During a recent winter month in Sheboygan, Wisconsin, it was necessary to obtain 3500 kWh of heat provided by a natural gas furnace with \(89 \%\) efficiency to keep a small house warm (the efficiency of a gas furnace is the percent of the heat produced by combustion that is transferred into the house). (a) Assume that natural gas is pure methane and determine the volume of natural gas in cubic feet that was required to heat the house. The average temperature of the natural gas was \(56^{\circ} \mathrm{F} ;\) at this temperature and a pressure of \(1 \mathrm{atm}\) natural gas has a density of 0.681 g/L. (b) How many gallons of LPG (liquefied petroleum gas) would be required to replace the natural gas used? Assume the LPG is liquid propane \(\left[\mathrm{C}_{3} \mathrm{H}_{8}:\right.\) density, \(0.5318 \mathrm{g} / \mathrm{mL}\); enthalpy of combustion, \(2219 \mathrm{kJ} / \mathrm{mol}\) for the formation of \(\left.\mathrm{CO}_{2}(g) \text { and } \mathrm{H}_{2} \mathrm{O}(l)\right]\) and the furnace used to burn the LPG has the same efficiency as the gas furnace. (c) What mass of carbon dioxide is produced by combustion of the methane used to heat the house? (d) What mass of water is produced by combustion of the methane used to heat the house? (e) What volume of air is required to provide the oxygen for the combustion of the methane used to heat the house? Air contains \(23 \%\) oxygen by mass. The average density of air during the month was \(1.22 \mathrm{g} / \mathrm{L}\). (f) How many kilowatt-hours \(\left(1 \mathrm{kWh}=3.6 \times 10^{6} \mathrm{J}\right)\) of electricity would be required to provide the heat necessary to heat the house? Note electricity is \(100 \%\) efficient in producing heat inside a house. (g) Although electricity is 100\% efficient in producing heat inside a house, production and distribution of electricity is not \(100 \%\) efficient. The efficiency of production and distribution of electricity produced in a coal- fired power plant is about 40\%. A certain type of coal provides 2.26 kWh per pound upon combustion. What mass of this coal in kilograms will be required to produce the electrical energy necessary to heat the house if the efficiency of generation and distribution is 40\%?

Which of the following compounds requires the most energy to convert one mole of the solid into separate ions? (a) \(\mathrm{K}_{2} \mathrm{S}\) (b) \(\mathrm{K}_{2} \mathrm{O}\) (c) CaS (d) \(\mathrm{Cs}_{2} \mathrm{S}\) (e) CaO

A serving of a breakfast cereal contains 3 g of protein, 18 g of carbohydrates, and 6 g of fat. What is the Calorie content of a serving of this cereal if the average number of Calories for fat is 9.1 Calories/g, for carbohydrates is 4.1 Calories/g, and for protein is 4.1 Calories/g?
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