Friday, November 22, 2019
Laws of Thermochemistry and Enthalpy Equations
Laws of Thermochemistry and Enthalpy Equations Thermochemical equations are just like other balanced equations except they also specify the heat flow for the reaction. The heat flow is listed to the right of the equation using the symbol ÃâH. The most common units are kilojoules, kJ. Here are two thermochemical equations: H2 (g) à ½ O2 (g) ââ â H2O (l); ÃâH -285.8 kJ HgO (s) ââ â Hg (l) à ½ O2 (g); ÃâH 90.7 kJ Writing Thermochemical Equations When you write thermochemical equations, be sure to keep the following points in mind: Coefficients refer to the number of moles. Thus, for the first equation, -282.8 kJ is the ÃâH when 1 mol of H2O (l) is formed from 1 mol H2 (g) and à ½ mol O2.Enthalpy changes for a phase change, so the enthalpy of a substance depends on whether is it is a solid, liquid, or gas. Be sure to specify the phase of the reactants and products using (s), (l), or (g) and be sure to look up the correct ÃâH from theà heat of formation tables. The symbol (aq) is used for species in water (aqueous) solution.ââ¬â¹The enthalpy of a substance depends upon temperature. Ideally, you should specify the temperature at which a reaction is carried out. When you look at a table of heats of formation, notice that the temperature of the ÃâH is given. For homework problems, and unless otherwise specified, theà temperature is assumed to be 25à °C. In the real world, ââ¬â¹theà temperature may be different and thermochemical calculations can be more difficult. Properties of Thermochemical Equations Certain laws or rules apply when using thermochemical equations: ÃâH is directly proportional to the quantity of a substance that reacts or is produced by a reaction. Enthalpy is directly proportional to mass. Therefore, if you double the coefficients in an equation, then the value of ÃâH is multiplied by two. For example:H2 (g) à ½ O2 (g) ââ â H2O (l); ÃâH -285.8 kJ2 H2 (g) O2 (g) ââ â 2 H2O (l); ÃâH -571.6 kJÃâH for a reaction is equal in magnitude but opposite in sign to ÃâH for the reverse reaction. For example:HgO (s) ââ â Hg (l) à ½ O2 (g); ÃâH 90.7 kJHg (l) à ½ O2 (l) ââ â HgO (s); ÃâH -90.7 kJThis law is commonly applied to phase changes, although it is true when you reverse any thermochemical reaction.ÃâH is independent of the number of steps involved. This rule is called Hesss Law. It states that ÃâH for a reaction is the same whether it occurs in one step or in a series of steps. Another way to look at it is to remember that ÃâH is a state property, so it must be independent of the path of a reaction.If Reaction (1) Reaction (2) Reaction (3), then ÃâH3 ÃâH1 ÃâH2
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