Skip to main content
Chemistry LibreTexts

Chapter 16.5: Comparing Thermodynamics and Kinetics

  • Page ID
    42150
  • \( \newcommand{\vecs}[1]{\overset { \scriptstyle \rightharpoonup} {\mathbf{#1}} } \) \( \newcommand{\vecd}[1]{\overset{-\!-\!\rightharpoonup}{\vphantom{a}\smash {#1}}} \)\(\newcommand{\id}{\mathrm{id}}\) \( \newcommand{\Span}{\mathrm{span}}\) \( \newcommand{\kernel}{\mathrm{null}\,}\) \( \newcommand{\range}{\mathrm{range}\,}\) \( \newcommand{\RealPart}{\mathrm{Re}}\) \( \newcommand{\ImaginaryPart}{\mathrm{Im}}\) \( \newcommand{\Argument}{\mathrm{Arg}}\) \( \newcommand{\norm}[1]{\| #1 \|}\) \( \newcommand{\inner}[2]{\langle #1, #2 \rangle}\) \( \newcommand{\Span}{\mathrm{span}}\) \(\newcommand{\id}{\mathrm{id}}\) \( \newcommand{\Span}{\mathrm{span}}\) \( \newcommand{\kernel}{\mathrm{null}\,}\) \( \newcommand{\range}{\mathrm{range}\,}\) \( \newcommand{\RealPart}{\mathrm{Re}}\) \( \newcommand{\ImaginaryPart}{\mathrm{Im}}\) \( \newcommand{\Argument}{\mathrm{Arg}}\) \( \newcommand{\norm}[1]{\| #1 \|}\) \( \newcommand{\inner}[2]{\langle #1, #2 \rangle}\) \( \newcommand{\Span}{\mathrm{span}}\)\(\newcommand{\AA}{\unicode[.8,0]{x212B}}\)

    Edited Logo.png

    Prince George's Community College
    General Chemistry for Engineering
    CHM 2000

    clipboard_e3097cdd7680f8988012b6fdbbbbe1b37.png
    Unit I: Atoms      Unit II: Molecules     Unit III: States of Matter     Unit IV: Reactions     Unit V: Kinetics & Equilibrium
    Unit VI: Thermo & Electrochemistry
         Unit VII: Nuclear Chemistry

    Learning Objective

    • To understand the differences between the information that thermodynamics and kinetics provide about a system.

    Because thermodynamics deals with state functions, it can be used to describe the overall properties, behavior, and equilibrium composition of a system. It is not concerned with the particular pathway by which physical or chemical changes occur, however, so it cannot address the rate at which a particular process will occur. Although thermodynamics provides a significant constraint on what can occur during a reaction process, it does not describe the detailed steps of what actually occurs on an atomic or a molecular level.

    Note the Pattern

    Thermodynamics focuses on the energetics of the products and the reactants, whereas kinetics focuses on the pathway from reactants to products.

    Table 16.5.1 gives the numerical values of the equilibrium constant (K) that correspond to various approximate values of ΔG°. Note that ΔG° ≥ +10 kJ/mol or ΔG° ≤ −10 kJ/mol ensures that an equilibrium lies essentially all the way to the left or to the right, respectively, under standard conditions, corresponding to a reactant-to-product ratio of approximately 10,000:1 (or vice versa). Only if ΔG° is quite small (±10 kJ/mol) are significant amounts of both products and reactants present at equilibrium. Most reactions that we encounter have equilibrium constants substantially greater or less than 1, with the equilibrium strongly favoring either products or reactants. In many cases, we will encounter reactions that are strongly favored by thermodynamics but do not occur at a measurable rate. In contrast, we may encounter reactions that are not thermodynamically favored under standard conditions but nonetheless do occur under certain nonstandard conditions.

    Table 16.5.1 The Relationship between K and ΔG° at 25°C

    ΔG° (kJ/mol) K Physical Significance
    500 3 × 10−88 For all intents and purposes, the reaction does not proceed in the forward direction: only reactants are present at equilibrium.
    100 3 × 10−18
    10 2 × 10−2 Both forward and reverse reactions occur: significant amounts of both products and reactants are present at equilibrium.
    0 1
    −10 60
    −100 3 × 1017 For all intents and purposes, the forward reaction proceeds to completion: only products are present at equilibrium.
    −500 4 × 1087

    A typical challenge in industrial processes is a reaction that has a large negative value of ΔG° and hence a large value of K but that is too slow to be practically useful. In such cases, mixing the reactants results in only a physical mixture, not a chemical reaction. An example is the reaction of carbon tetrachloride with water to produce carbon dioxide and hydrochloric acid, for which ΔG° is −232 kJ/mol:

    \( CCl_{4}\left ( l \right ) + 2H_{2}O\left ( l \right ) \rightleftharpoons CO_{2} \left ( g \right )+ 2 HCl\left ( g \right ) \tag{16.5.1}\)

    The value of K for this reaction is 5 × 1040 at 25°C, yet when CCl4 and water are shaken vigorously at 25°C, nothing happens: the two immiscible liquids form separate layers, with the denser CCl4 on the bottom. In comparison, the analogous reaction of SiCl4 with water to give SiO2 and HCl, which has a similarly large equilibrium constant, occurs almost explosively. Although the two reactions have comparable thermodynamics, they have very different kinetics!

    There are also many reactions for which ΔG° << 0 but that do not occur as written because another possible reaction occurs more rapidly. For example, consider the reaction of lead sulfide with hydrogen peroxide. One possible reaction is as follows:

    \( PbS\left ( s \right ) + 4H_{2}O_{2}\left ( l \right ) \rightleftharpoons PbO_{2} \left ( s \right )+ SO_{2}\left ( g \right ) + 4H_{2}O\left ( l \right ) \tag{16.5.2}\)

    for which ΔG° is −886 kJ/mol and K is 10161. Yet when lead sulfide is mixed with hydrogen peroxide, the ensuing vigorous reaction does not produce PbO2 and SO2. Instead, the reaction that actually occurs is as follows:

    \( PbS\left ( s \right ) + 4H_{2}O_{2}\left ( l \right ) \rightleftharpoons PbSO_{4} \left ( s \right )+ 4H_{2}O\left ( l \right ) \tag{16.5.3}\)

    This reaction has a ΔG° value of −1181 kJ/mol, within the same order of magnitude as the reaction in Equation 16.5.2, but it occurs much more rapidly.

    Now consider reactions with ΔG° > 0. Thermodynamically, such reactions do not occur spontaneously under standard conditions. Nonetheless, these reactions can be made to occur under nonstandard conditions. An example is the reduction of chromium(III) chloride by hydrogen gas:

    \( CrCl_{3}\left ( s \right ) + \dfrac{1}{2}H_{2}\left ( g \right ) \rightleftharpoons CrCl_{2} \left ( s \right )+ HCl\left ( g \right ) \tag{16.5.4}\)

    At 25°C, ΔG° = 35 kJ/mol and Kp = 7 × 10−7. However, at 730°C, ΔG° = −52 kJ/mol and Kp = 5 × 102; at this elevated temperature, the reaction is a convenient way of preparing chromium(II) chloride in the laboratory. Moreover, removing HCl gas from the system drives the reaction to completion, as predicted by Le Châtelier’s principle. Although the reaction is not thermodynamically spontaneous under standard conditions, it becomes spontaneous under nonstandard conditions.

    There are also cases in which a compound whose formation appears to be thermodynamically prohibited can be prepared using a different reaction. The reaction for the preparation of chlorine monoxide from its component elements, for example, is as follows:

    \( \dfrac{1}{2}O_{2}\left ( g \right ) + Cl_{2}\left ( g \right ) \rightleftharpoons Cl_{2}O \left ( g \right ) \tag{16.5.5}\)

    for which ΔGf° is 97.9 kJ/mol. The large positive value of ΔGf° for this reaction indicates that mixtures of chlorine and oxygen do not react to any extent to form Cl2O. Nonetheless, Cl2O is easily prepared using the reaction

    \( HgO\left ( s \right ) + 2Cl_{2}\left ( g \right ) \rightleftharpoons Cl_{2}O \left ( g \right ) +HgCl_{2}\left ( s \right ) \tag{16.5.6}\)

    which has a ΔG° of −22.2 kJ/mol and a Kp of approximately 1 × 104.

    Finally, the ΔG° values for some reactions are so positive that the only way to make them proceed in the desired direction is to supply external energy, often in the form of electricity. Consider, for example, the formation of metallic lithium from molten lithium chloride:

    \( LiCl\left ( s \right ) \rightleftharpoons Li \left ( l \right ) +\dfrac{1}{2}Cl_{2}\left ( s \right ) \tag{16.5.7}\)

    Even at 1000°C, ΔG is very positive (324 kJ/mol), and there is no obvious way to obtain lithium metal using a different reaction. Hence in the industrial preparation of metallic lithium, electrical energy is used to drive the reaction to the right, as described in Chapter 17 .

    Note the Pattern

    A reaction that does not occur under standard conditions can be made to occur under nonstandard conditions, such as by driving the reaction to completion using Le Châtelier’s principle or by providing external energy.

    Often reactions that are not thermodynamically spontaneous under standard conditions can be made to occur spontaneously if coupled, or connected, in some way to another reaction for which ΔG° << 0. Because the overall value of ΔG° for a series of reactions is the sum of the ΔG° values for the individual reactions, virtually any unfavorable reaction can be made to occur by chemically coupling it to a sufficiently favorable reaction or reactions. In the preparation of chlorine monoxide from mercuric oxide and chlorine (Equation 16.5.6), we have already encountered one example of this phenomenon of coupled reactions, although we did not describe it as such at the time. We can see how the chemical coupling works if we write Equation 16.5.6 as the sum of three separate reactions:

    \( \begin{matrix}
    \cancel{\dfrac{1}{2}O_{2}\left ( g \right )} + Cl_{2}\left ( g \right ) & \rightleftharpoons Cl_{2}O \left ( g \right )& \Delta G^{o} &=97.9\;kJ/mol & \left ( 1 \right )\\
    & & & & \\
    HgO\left ( s \right ) &\rightleftharpoons \cancel{Hg\left ( l \right )}+ \cancel{\dfrac{1}{2}O_{2}\left ( g \right )} & \Delta G^{o} & =58.5\; kJ/mol &\left ( 2 \right ) \\
    & & & & \\
    \cancel{Hg\left ( l \right )}+ Cl_{2}\left ( g \right ) & \rightleftharpoons HgCl_{2}\left ( s \right ) & \Delta G^{o} & =-178.6\; kJ/mol & \left (3 \right )\\
    & & & & \\
    HgO\left ( s \right ) + 2Cl_{2}\left ( g \right ) & \rightleftharpoons Cl_{2}O + HgCl_{2}\left ( s \right ) & \Delta G^{o} & =-22.2\; kJ/mol &
    \end{matrix} \)

    Comparing the ΔG° values for the three reactions shows that reaction 3 is so energetically favorable that it more than compensates for the other two energetically unfavorable reactions. Hence the overall reaction is indeed thermodynamically spontaneous as written.

    Note the Pattern

    By coupling reactions, a reaction that is thermodynamically nonspontaneous can be made spontaneous.

    Example 16.5.1

    Bronze Age metallurgists were accomplished practical chemists who unknowingly used coupled reactions to obtain metals from their ores. Realizing that different ores of the same metal required different treatments, they heated copper oxide ore in the presence of charcoal (carbon) to obtain copper metal, whereas they pumped air into the reaction system if the ore was copper sulfide. Assume that a particular copper ore consists of pure cuprous oxide (Cu2O). Using the ΔGf° values given for each, calculate

    1. ΔG° and Kp for the decomposition of Cu2O to metallic copper and oxygen gas
      ΔGf°(Cu2O)= -146.0 kJ/mol
    2. ΔG° and Kp for the reaction of Cu2O with carbon to produce metallic copper and carbon monoxide
      ΔGf°(CO)= -137.2 kJ/mol

    Given: reactants and productsΔGf°and Kp values for Cu2O and CO, and temperature

    Asked for: ΔG° and Kp for the formation of metallic copper from Cu2O in the absence and presence of carbon

    Strategy:

    A Write the balanced equilibrium equation for each reaction. Using the “products minus reactants” rule, calculate ΔG° for the reaction.

    B Substitute appropriate values into Equation 16.4.9 to obtain Kp.

    Solution:

    1. A The chemical equation for the decomposition of cuprous oxide is as follows:

      \( Cu_{2}O\left ( s \right ) \rightleftharpoons 2Cu\left ( s \right ) + \dfrac{1}{2}O_{2}\left ( g \right ) \)

      The substances on the right side of this equation are pure elements in their standard states, so their ΔGf° values are zero. ΔG° for the reaction is therefore

      \( \Delta G^{o}= \left [ 2 \Delta G_{f}^{o} \left ( Cu \right ) + \dfrac{1}{2} \Delta G_{f}^{o} \left ( O_{2} \right ) \right ] - \Delta G_{f}^{o} \left (Cu_{2}O \right ) \)
      \( =\left [ \left ( 2\;\cancel{mol} \right )\left ( 0\; kJ/\cancel{mol} \right ) + \left ( \dfrac{1}{2} \;\cancel{mol} \right )\left ( 0\; kJ/\cancel{mol} \right ) \right ] - \left ( 1\;\cancel{mol} \right )\left ( -146.0\; kJ/\cancel{mol} \right )\)
      \( = 146\; kJ\)
    2. B Rearranging and substituting the appropriate values into Equation 16.4.9,

      \( ln\;K_{p}= -\dfrac{\Delta G^{o}}{RT}=-\dfrac{146.0\cancel{kJ}\left ( 1000\;\cancel{J}/\cancel{kJ} \right )}{\left (8.314\;\cancel{J}/\cancel{K} \right )\left ( 298.15\;\cancel{K} \right )}=-58.90 \)
    3. \( K_{p}=2.6\times 10^{-26} \)

      This is a very small number, indicating that Cu2O does not spontaneously decompose to a significant extent at room temperature.

    4. A The O2 produced in the decomposition of Cu2O can react with carbon to form CO:

      \( \dfrac{1}{2}O_{2}\left ( g \right ) + C\left ( s \right ) \rightleftharpoons CO\left ( g \right ) \)

      Because ΔG° for this reaction is equal to <ΔGf° for CO (−137.2 kJ/mol), it is energetically more feasible to produce metallic copper from cuprous oxide by coupling the two reactions:

      \( \begin{matrix}
      Cu_{2}O\left ( s \right ) & \rightleftharpoons 2Cu \left ( s \right ) + \cancel{\dfrac{1}{2}O_{2}\left ( g \right )} & \Delta G^{o} &=146.0\;kJ/mol & \left ( 1 \right )\\
      & & & & \\
      \cancel{\dfrac{1}{2}O_{2}\left ( g \right )} + C\left ( s \right ) &\rightleftharpoons CO\left ( g \right ) & \Delta G^{o} & =-137.2\; kJ/mol &\left ( 2 \right ) \\
      & & & & \\
      Cu_{2}O\left ( s \right ) + Cl\left ( s \right ) & \rightleftharpoons 2Cu\left ( s \right ) + CO\left ( g \right ) & \Delta G_{f}^{o} & =8.8\; kJ/mol &
      \end{matrix} \)

      B We can find the corresponding value of Kp:

      \( ln\;K_{p}= -\dfrac{\Delta G^{o}}{RT}=-\dfrac{8.8\cancel{kJ}\left ( 1000\;\cancel{J}/\cancel{kJ} \right )}{\left (8.314\;\cancel{J}/\cancel{K} \right )\left ( 298.15\;\cancel{K} \right )}=-3.6 \)
      \( K_{p}=-0.03 \)

      Although this value is still less than 1, indicating that reactants are favored over products at room temperature, it is about 24 orders of magnitude greater than Kp for the production of copper metal in the absence of carbon. Because both ΔH° and ΔS° are positive for this reaction, it becomes thermodynamically feasible at slightly elevated temperatures (greater than about 80°C). At temperatures of a few hundred degrees Celsius, the reaction occurs spontaneously, proceeding smoothly and rapidly to the right as written and producing metallic copper and carbon monoxide from cuprous oxide and carbon.

    Exercise

    Use the ΔGf° values given to calculate ΔG° and Kp for each reaction.

    1. the decomposition of cuprous sulfide to copper metal and elemental sulfur
      ΔGf°(Cu2S)= -86.2 kJ/mol
    2. the reaction of cuprous sulfide with oxygen gas to produce sulfur dioxide and copper metal
      ΔGf°(SO2(g))= -300.1 kJ/mol

    Answer:

    1. ΔG° = 86.2 kJ/mol; Kp = 7.90 × 10−16
    2. ΔG° = −213.9 kJ/mol; Kp = 2.99 × 1037

    Summary

    Thermodynamics describes the overall properties, behavior, and equilibrium composition of a system; kinetics describes the rate at which a particular process will occur and the pathway by which it will occur. Whereas thermodynamics tells us what can occur during a reaction process, kinetics tells us what actually occurs on an atomic or a molecular level. A reaction that is not thermodynamically spontaneous under standard conditions can often be made to occur spontaneously by varying the reaction conditions; using a different reaction to obtain the same product; supplying external energy, such as electricity; or coupling the unfavorable reaction to another reaction for which ΔG° << 0.

    Key Takeaway

    • Thermodynamics describes the overall properties, behavior, and equilibrium composition of a system, whereas kinetics describes the particular pathway by which a physical or a chemical change actually occurs.

    Conceptual Problem

    1. You are in charge of finding conditions to make the reaction A(l) + B(l) → C(l) + D(g) favorable because it is a critical step in the synthesis of your company’s key product. You have calculated that ΔG° for the reaction is negative, yet the ratio of products to reactants is very small. What have you overlooked in your scheme? What can you do to drive the reaction to increase your product yield?

    Contributors

    • Anonymous

    Modified by Joshua Halpern (Howard University), Scott Sinex, and Scott Johnson (PGCC)

    Thumbnail from Wikimedia


    Chapter 16.5: Comparing Thermodynamics and Kinetics is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by LibreTexts.

    • Was this article helpful?