Sunday, October 20, 2019
Enthalpy Definition in Chemistry and Physics
Enthalpy Definition in Chemistry and Physics Enthalpy is a thermodynamic property of a system. It is the sum of the internal energy added to the product of the pressure and volume of the system. It reflects the capacity to do non-mechanical work and the capacity to release heat. Enthalpy is denoted as H; specific enthalpy denoted as h. Common units used to express enthalpy are the joule, calorie, or BTU (British Thermal Unit.) Enthalpy in a throttling process is constant. Change in enthalpy is calculated rather than enthalpy, in part because total enthalpy of a system cannot be measured. However, it is possible to measure the difference in enthalpy between one state and another. Enthalpy change may be calculated under conditions of constant pressure. Enthalpy Formulas H E PV where H is enthalpy, E is internal energy of the system, P is pressure, and V is volume d H T d S P d V What Is the Importance of Enthalpy? Measuring the change in enthalpy allows us to determine whether a reaction was endothermic (absorbed heat, positive change in enthalpy) or exothermic (released heat, negative change in enthalpy.)It is used to calculate the heat of reaction of a chemical process.Change in enthalpy is used to measure heat flow in calorimetry.It is measured to evaluate aà throttling process or Joule-Thomson expansion.Enthalpy is used to calculate minimum power for a compressor.Enthalpy change occurs during a change in the state of matter.There are many other applications of enthalpy in thermal engineering. Example Change in Enthalpy Calculation You can use the heat of fusion of ice and heat of vaporization of water to calculate the enthalpy change when ice melts into a liquid and the liquid turns to a vapor. The heat of fusion of ice is 333 J/g (meaning 333 J is absorbed when 1 gram of ice melts.) Theà heat of vaporization of liquid waterà at 100à °C is 2257 J/g. Part A:à Calculateà the change in enthalpy, ÃâH, for these two processes. H2O(s) ââ â H2O(l); ÃâH ?H2O(l) ââ â H2O(g); ÃâH ?Part B:à Using the values you calculated, find the number of grams of ice you can melt using 0.800 kJ of heat. SolutionA.à The heats of fusion and vaporization are in joules, so the first thing to do is convert to kilojoules. Using theà periodic table, we know that 1à mole of waterà (H2O) is 18.02 g. Therefore:fusion ÃâH 18.02 g x 333 J / 1 gfusion ÃâH 6.00 x 103à Jfusion ÃâH 6.00 kJvaporization ÃâH 18.02 g x 2257 J / 1 gvaporization ÃâH 4.07 x 104à Jvaporization ÃâH 40.7 kJSo the completed thermochemical reactions are:H2O(s) ââ â H2O(l); ÃâH 6.00 kJH2O(l) ââ â H2O(g); ÃâH 40.7 kJB.à Now we know that:1 mol H2O(s) 18.02 g H2O(s) ~ 6.00 kJUsing this conversion factor:0.800 kJ x 18.02 g ice / 6.00 kJ 2.40 g ice melted Answer A.à H2O(s) ââ â H2O(l); ÃâH 6.00 kJ H2O(l) ââ â H2O(g); ÃâH 40.7 kJ B.à 2.40 g ice melted
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