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Chapter 7: Problem 127

In your own words, define or explain the following terms or symbols: (a) \(\Delta H ;\) (b) \(P \Delta V ;\) (c) \(\Delta H_{f} ;\) (d) standard state; (e) fossil fuel.

Short Answer

Expert verified
The solution provides definitions or explanations of the terms or symbols: \(\Delta H\) is the change in enthalpy of a system, \(P \Delta V\) is the work done by a system when volume changes under constant pressure, \(\Delta H_{f}\) is the change in enthalpy in the formation of a compound from its elements in their standard states, standard state is the reference state for substances under specific conditions, and fossil fuels are natural fuels containing high percentages of carbon, which when burnt, are a major contributor to global warming.

Step by step solution

01

Define \(\Delta H\)

\(\Delta H\) represents the change in enthalpy in a system during a process. Enthalpy is a physical quantity used in the measurement of the heat energy in a thermodynamic system. It is typically used in chemistry to calculate the heat of reaction or a phase change. The \(\Delta\) symbol signifies a change in value.
02

Explain \(P \Delta V\)

\(P \Delta V\) represents the work done when the volume of a system changes under constant pressure. It is often used in the first law of thermodynamics, which states that the change in internal energy of a system is equal to the heat added to the system minus the work done by the system.
03

Define \(\Delta H_{f}\)

\(\Delta H_{f}\) represents the change in enthalpy that accompanies the formation of one mole of a compound from its elements in their standard states. It is often referred to as the standard enthalpy of formation.
04

Define standard state

Standard state refers to the reference state for substances under specific conditions. It's commonly used for substances in their pure form at a specific temperature (often set at 298.15 K) and a specific pressure (most commonly 1 atm or 100 kPa). It provides a baseline with which to compare the properties of other systems.
05

Explain fossil fuel

Fossil fuel refers to a natural fuel formed in the geological past from the remains of living organisms. It contains high percentages of carbon and includes coal, oil, and natural gas. Fossil fuels are the dominant source of global energy, but their burning is a major contributor to global warming.

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Key Concepts

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

\(\Delta H\)
Enthalpy change, denoted as \(\Delta H\), is a key concept in thermodynamics that indicates the amount of heat absorbed or released by a system during a chemical reaction or physical process at constant pressure. In simpler terms, if we consider a reaction happening inside a container that doesn't allow the pressure to change, \(\Delta H\) helps us understand whether the reaction gives off heat to the surroundings (exothermic) or absorbs heat from the surroundings (endothermic). This concept not only aids chemists in predicting how temperature affects reactions but also provides insight into the potential for a reaction to occur spontaneously.

Understanding \(\Delta H\) is crucial in fields like materials science, where the creation of new substances can involve complex heat exchanges. Additionally, enthalpy changes are also important in environmental science, particularly when considering the heat produced by various processes, including the combustion of fossil fuels.
P \(\Delta V\)
The term \(P \Delta V\) is a formula that represents the mechanical work involved when the volume, \(V\), of a system changes in the context of constant pressure, \(P\). It's an expression derived from the first law of thermodynamics, which is essentially a statement about the conservation of energy. Whenever a system changes volume, such as when a gas expands in a piston, work is being done either by or on the system, and this formula gives us a clear mathematical way to express that work.

Understanding \(P \Delta V\) work is crucial in engineering and environmental studies. For example, when considering the efficiency of an internal combustion engine or the energy balance in the Earth's atmosphere, knowing the work done during volume changes is essential. This concept connects closely with the broader implications of energy transformations and conservation, which are principles at the heart of many modern technological and environmental challenges.
\(\Delta H_f\)
The symbol \(\Delta H_f\) stands for the standard enthalpy of formation, which is the change in enthalpy when one mole of a compound is formed from its constituent elements in their standard states. In practical terms, it tells us the amount of energy that's either absorbed or released when a substance is created from the most basic materials we can find in nature, at a set standard conditions (usually 1 atmosphere of pressure and 298.15 Kelvin).

For anyone studying chemistry, \(\Delta H_f\) values are vital. They serve as the 'building blocks' to calculate the enthalpy changes for various chemical reactions by using Hess's law, which is a way of adding up stepwise reaction enthalpies to find the overall reaction enthalpy. Knowing the standard enthalpy of formation allows scientists and engineers to predict the stability of compounds and their propensity to react, which has direct applications in the development of new materials and energy sources.
Thermodynamics
Thermodynamics is a fundamental branch of physics that deals with heat, work, temperature, and energy. It explores how energy transfers within systems and to their surroundings and lays out the laws that dictate energy conversion processes. The most well-known aspects of thermodynamics include the three laws: the first law (conservation of energy), the second law (entropy and the direction of energy transfers), and the third law (the absolute zero temperature concept).

Studying thermodynamics is indispensable for a wide range of scientific and engineering fields including chemistry, mechanical engineering, environmental science, and even economics. It's the theoretical framework that underpins our understanding of processes such as engines and refrigerators, and it's critical in evaluating the sustainability and environmental impact of our energy use, especially with regard to fossil fuels and alternative energy sources.
Standard State
The standard state of a substance is a reference point used in thermodynamics to report properties such as enthalpy, entropy, and Gibbs free energy. It's defined for a specific temperature and pressure, commonly 298.15 K (25°C) and 1 atmosphere of pressure. The standard state allows for a consistent basis of comparison for these properties across different substances.

Understanding the standard state is essential for chemists and engineers who use it daily to calculate reaction behaviors and environmental scientists who need to compare pollution metrics at a common baseline. When handling data on the energy content of materials or the environmental impact of chemical processes, referencing them to a standard state ensures clarity and uniformity in reporting.
Fossil Fuels
Fossil fuels—comprising coal, oil, and natural gas—are concentrated sources of energy that have formed from the buried remains of plants and animals that lived millions of years ago. They are integral to modern civilization as they power our vehicles, heat our homes, and are used in the production of electricity. However, the combustion of fossil fuels releases carbon dioxide, a greenhouse gas, which contributes significantly to the anthropogenic climate change we are battling today.

Understanding the role of fossil fuels in global energy production is critical for students of environmental science, energy policies, and sustainable design. Researchers and policy-makers are seeking to reduce our reliance on fossil fuels by developing renewable energy sources and designing more energy-efficient technologies, which rely heavily on thermodynamic principles to optimize performance and minimize the environmental footprint.

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Most popular questions from this chapter

Thermite mixtures are used for certain types of welding, and the thermite reaction is highly exothermic. $$\begin{array}{r} \mathrm{Fe}_{2} \mathrm{O}_{3}(\mathrm{s})+2 \mathrm{Al}(\mathrm{s}) \longrightarrow \mathrm{Al}_{2} \mathrm{O}_{3}(\mathrm{s})+2 \mathrm{Fe}(\mathrm{s}) \\ \Delta H^{\circ}=-852 \mathrm{kJ} \end{array}$$ \(1.00 \mathrm{mol}\) of granular \(\mathrm{Fe}_{2} \mathrm{O}_{3}\) and \(2.00 \mathrm{mol}\) of granular Al are mixed at room temperature \(\left(25^{\circ} \mathrm{C}\right),\) and a reaction is initiated. The liberated heat is retained within the products, whose combined specific heat over a broad temperature range is about \(0.8 \mathrm{Jg}^{-1}\) \(^{\circ} \mathrm{C}^{-1} .\) (The melting point of iron is \(1530^{\circ} \mathrm{C} .\) ) Show that the quantity of heat liberated is more than sufficient to raise the temperature of the products to the melting point of iron.

There are other forms of work besides \(\mathrm{P}-\mathrm{V}\) work. For example, electrical work is defined as the potential \(x\) change in charge, \(w=\phi d q\). If a charge in a system is changed from \(10 \mathrm{C}\) to \(5 \mathrm{C}\) in a potential of \(100 \mathrm{V}\) and \(45 \mathrm{J}\) of heat is liberated, what is the change in the internal energy? (Note: \(1 \mathrm{V}=1 \mathrm{J} / \mathrm{C})\).

The following substances undergo complete combustion in a bomb calorimeter. The calorimeter assembly has a heat capacity of \(5.136 \mathrm{kJ} /^{\circ} \mathrm{C} .\) In each case, what is the final temperature if the initial water temperature is \(22.43^{\circ} \mathrm{C} ?\) \(\begin{array}{lllll}\text { (a) } 0.3268 & \text { g caffeine, } & \mathrm{C}_{8} \mathrm{H}_{10} \mathrm{O}_{2} \mathrm{N}_{4} & \text { (heat of }\end{array}\) combustion \(=-1014.2 \mathrm{kcal} / \mathrm{mol} \text { caffeine })\) (b) \(1.35 \mathrm{mL}\) of methyl ethyl ketone, \(\mathrm{C}_{4} \mathrm{H}_{8} \mathrm{O}(1)\) \(d=0.805 \mathrm{g} / \mathrm{mL}\) (heat of combustion \(=-2444 \mathrm{kJ} / \mathrm{mol}\) methyl ethyl ketone).

Determine \(\Delta H^{\circ}\) for this reaction from the data below. \(\mathrm{N}_{2} \mathrm{H}_{4}(1)+2 \mathrm{H}_{2} \mathrm{O}_{2}(1) \longrightarrow \mathrm{N}_{2}(\mathrm{g})+4 \mathrm{H}_{2} \mathrm{O}(1)\) $$\begin{array}{r} \mathrm{N}_{2} \mathrm{H}_{4}(\mathrm{l})+\mathrm{O}_{2}(\mathrm{g}) \longrightarrow \mathrm{N}_{2}(\mathrm{g})+2 \mathrm{H}_{2} \mathrm{O}(\mathrm{l}) \\ \Delta H^{\circ}=-622.2 \mathrm{kJ} \end{array}$$ $$\mathrm{H}_{2}(\mathrm{g})+\frac{1}{2} \mathrm{O}_{2}(\mathrm{g}) \longrightarrow \mathrm{H}_{2} \mathrm{O}(\mathrm{l}) \quad \Delta H^{\circ}=-285.8 \mathrm{kJ}$$ $$\mathrm{H}_{2}(\mathrm{g})+\mathrm{O}_{2}(\mathrm{g}) \longrightarrow \mathrm{H}_{2} \mathrm{O}_{2}(1) \quad \Delta H^{\circ}=-187.8 \mathrm{kJ}$$

A \(1.00 \mathrm{g}\) sample of \(\mathrm{Ne}(\mathrm{g})\) at 1 atm pressure and \(27^{\circ} \mathrm{C}\) is allowed to expand into an evacuated vessel of \(2.50 \mathrm{L}\) volume. Does the gas do work? Explain.
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