jfizzix said:They mean standard enthalpy of products. Since we can't measure absolute enthalpy, we measure enthalpy relative to a standard state, in this case, pure elements. We can measure changes of enthalpy though, because at contant pressure, that's just the net heat of reaction.
Speedking96 said:I'm not sure I follow.
Chestermiller said:To elaborate on what jfizzix said, the enthalpy of the elements that comprise a given compound under standard conditions of temperature and pressure (usually 298K and 1 atm) are each taken to be zero. The enthalpy of the particular compound under standard conditions is then the heat of formation of the compound (change in enthalpy at constant standard temperature and pressure) when the elements react to form the compound. These heat of formation (enthalpy) values for many, many, compounds are tabulated in many references. The standard heat of reaction for reactions involving a group of reactant compounds is equal to the sum of the enthalpies of the products minus the sum of the enthalpies of the reactants (weighted in terms of the stoichiometric coefficients). If the reaction occurs at a different temperature, the enthalpies of the reacting and product compounds have to be modified using the heat capacity for each compound to get the enthalpy at temperature. Stuff like this is discussed in much greater detail in virtually all books that treat chemical thermodynamics.
Not exactly. The enthalpies of all compounds and elements are referenced to the same standard state of temperature and pressure. The enthalpies of the elements in this standard state are taken to be zero (with no loss of generality), and the enthalpies of compounds are equal to the amounts of heat that must be added in forming the compound from its elements at the standard temperature and pressure. So compounds like water that are formed by an exothermic reaction between elemental hydrogen (actually molecular H2 is assigned zero enthalpy) and elemental oxygen (actually molecular O2 is assigned zero enthalpy) has a negative enthalpy at standard conditions.ThatDude said:So basically, because it is not possible to measure absolute enthalpy, we "assign" a standard state enthalpy of 0 to each element. The heat released by that element during a reaction is then taken to be its "enthalpy", correct?
General entropy question refers to a concept in thermodynamics that measures the degree of disorder or randomness in a system. It is often used to describe the tendency of a system to move towards a state of maximum disorder.
The Second Law of Thermodynamics states that the total entropy of a closed system will always increase over time. This means that the disorder or randomness in a system will always increase unless energy is put into the system. General entropy question is directly related to this law as it measures the amount of disorder in a system.
General entropy question is calculated using the formula S = k ln W, where S represents entropy, k is the Boltzmann constant, and W is the number of possible microstates of a system. This formula is often used to calculate the change in entropy of a system before and after a process.
There are several factors that can affect general entropy question. One of the main factors is the number of particles in a system, as a larger number of particles can lead to a greater number of possible microstates, resulting in a higher entropy. Temperature and pressure can also affect entropy, as well as the energy input into a system.
General entropy question has many applications in various fields such as physics, chemistry, and biology. It can be used to understand the behavior of complex systems, such as chemical reactions, and to predict the direction of spontaneous processes. It also plays a crucial role in the development of efficient energy systems and in understanding the flow of energy in living organisms.