![]() ![]() This difference is independent of the path we choose to get from the first floor to the third floor. Consider the difference in elevation between the first floor and the third floor of a building. The concept of a state function is somewhat analogous to the idea of elevation. H, which we call the enthalpy, is a state function, since its value depends only on the state of the materials under consideration, that is, the temperature, pressure and composition of these materials. We choose this function, H, so that the change in the function, ΔH = H products - H reactants, is equal to the heat of reaction q under constant pressure conditions. Likewise, the value of this energy function in the product state is independent of how the products are prepared. Were this not the case, we could endlessly produce unlimited quantities of energy by following the circuitous path which continually reproduces the initial reactants.īy this reasoning, we can define an energy function whose value for the reactants is independent of how the reactant state was prepared. Therefore, we cannot extract any energy from the reactants by a process which simply recreates the reactants. This is a statement of the conservation of energy: the energy in the reactant state does not depend upon the processes which produced that state. ![]() We discover that the net heat transferred (again provided that all reactions occur under constant pressure) is exactly zero. A consequence of our observation of Hess's Law is therefore that the net heat evolved or absorbed during a reaction is independent of the path connecting the reactant to product (this statement is again subject to our restriction that all reactions in the alternative path must occur under constant pressure conditions).Ī slightly different view of figure 1 results from beginning at the reactant box and following a complete circuit through the other boxes leading back to the reactant box, summing the net heats of reaction as we go. ![]()
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