After an intense research reading documents and Q&A, I am still very confused about the concept Enthalpy.
Etymology says: "to warm in". [ἐνθάλπω (enthálpō, “to warm in”)]
I interpret: "to put warmth (same as heat) into something." (i. e. warmth transfer = heat?)
[1] Some will say: "Enthalpy is a measure of heat transfer".
I will wonder: "Being heat[-flow] already a concept involving transference, what's the point of defining a concept that refers to a transfer-transference?"
[2] Some will say: "Enthalpy is a state function to correct the fact that heat is not a state function".
I will wonder: "Okay, but how and why?".
[3] Some will say: "Enthalpy is Internal energy plus Pressure times Volume".
I will wonder: "Looks just like a brother-concept to what I learned as heat. Still I see no point in it.".
I would like to understand not only what enthalpy is, but where can I visualize enthalpy in for example a cup of coffee that is chilling on a balcony, in contact with the atmosphere.
Answer
One the main advantages of enthalpy is that it allows you to work out compression and expansion work done during constant pressure thermodynamic processes in an easier form.
Rather than think of the energy content of a system, we could include the work done to make room for the system in the first place.
You need to do work to create space for a system, and this work can be estimated using PV, which is the volume occupied by the system multiplied by the pressure of the environment in which the system is to be created.
So taking U as the total internal energy of a system, then we can define H = PV plus U.
So H is the total energy required to construct the system and also make room for it.
To reverse the idea, if you completely destroy a system, you would recover not only the internal energy of the system, as well as the work done by the environment (atmosphere), as it rushes in to fill the vacuum.
There are only two causes for an increase in the enthalpy of any particular system, either the system expands and it does work on the environment to create space for this expansion, or the internal energy of the system increases.
We can say $\Delta H = Q + W_0$, where $W_0$ is any other type of work and Q is the amount oF heat added to the system.
Where can I visualize enthalpy in for example a cup of coffee that is chilling on a balcony, in contact with the atmosphere
Enthalpy is a measure of the work done to move air out of the way to give space to your coffee cup (PV) plus the internal energy (U) of the hot coffee inside the cup.
To sum up, the enthalpy change is produced solely by work, in various forms, and heat. So this eliminates the calculations involved in compression expansion themodynamic processes.
$\Delta H $ in a direct indication of the heat added to the system, as long as no other types of work is being done.
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