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In [[thermodynamics]], '''enthalpy''' is the sum of the [[internal energy]] ''U'' of a system and the product of pressure ''p'' and ''V'' of the system,
{{subpages}}
In [[thermodynamics]], '''enthalpy''' is the sum of the [[internal energy]] ''U'' and the product of [[pressure]] ''p'' and volume ''V'' of a system,
:<math>
:<math>
H = U + pV \,  
H = U + pV \,  
</math>
</math>
Enthalpy used to be called "heat content", which is why it is conventionally indicated by ''H''.
The characteristic function (also known as thermodynamic potential) "enthalpy" used to be called "heat contents", which is why it is conventionally indicated by ''H''. The term "enthalpy" was coined by the Dutch physicist [[Heike Kamerling Onnes]].<ref>Alfred W. Porter, (in: ''The Generation and Utilisation of Cold. A general discussion'',
Transactions Faraday Society, 1922, vol. '''18''',  pp. 139&ndash;143
[http://dx.doi.org/DOI:10.1039/TF9221800139 DOI]) gives credit to Kamerling Onnes and proposes the letter ''H'', either standing for "Heat contents", or capital eta as in Hνθαλπος (Enthalpos), although the Greek word starts with capital epsilon. See also Irmgard K. Howard, ''H Is for Enthalpy, Thanks to Heike Kamerlingh Onnes and Alfred W. Porter'',  Journal Chemical Education, 2002, vol. '''79''', pp. 697&ndash;698 [http://jchemed.chem.wisc.edu/Journal/Issues/2002/jun/abs697.html online]
</ref>


The work term ''pV'' has dimension energy, in [[SI]] units joule, and ''H'' has the same dimension. Enthalpy is a state function, a property of the state of the thermodynamic system
The internal energy ''U'' and the [[work (Physics)|work]] term ''pV'' have dimension of energy, in [[SI]] units this is [[joule (unit)|joule]];  the extensive (linear in size) quantity ''H'' has the same dimension.  
and its value is determined entirely by the temperature ''T'', pressure ''p'', and composition ''N''<sub>A</sub>,  ''N''<sub>B</sub>, ... (molar amounts of substances A, B, ... ) of the system and not by its history.  


==Internal energy==
Enthalpy (as the extensive property mentioned above) has corresponding intensive (size-independent) properties for pure materials.  A corresponding intensive property is '''specific enthalpy''', which is enthalpy per mass of substance involved.  Specific enthalpy is denoted by a lower case ''h'', with dimension of energy per mass  (SI unit: joule/kg).  If a [[molecular mass]] or number of moles involved can be assigned, then another corresponding intensive property is '''molar enthalpy''', which is enthalpy per [[Mole (chemistry)|mole]] of the compound involved, or alternatively specific enthalpy times molecular mass.  There is no universally agreed upon symbol for molar properties, and molar enthalpy has been at times confusingly symbolized by ''H'', as in extensive enthalpy.  The dimensions of molar enthalpy are energy per number of moles  (SI unit: joule/mole). 
Often one considers a system with thermal conducting walls, so that (small) amounts of [[heat]] &Delta;''Q'' can go through the wall in either direction: if &Delta;''Q'' > 0, heat enters the system and if &Delta;''Q'' < 0 heat leaves the system. Also one usually considers one manner
 
of performing (small) amount of work &Delta;''W'' by or on the system:  
In terms of intensive properties, specific enthalpy can be correspondingly defined as follows:
:<math>h = u + p v\,</math>
where
:h = specific enthalpy
:u = [[specific internal energy]]
:p = pressure (as before)
:v = [[specific volume]] = reciprocal of [[density]]
 
Enthalpy is a function depending on the independent variables that describe the state of the thermodynamic system.  Most commonly one considers systems that have three forms of energy contact with their surroundings, namely the reversible and infinitesimal gain of [[heat]],<ref>Capital ''D'' is written to distinguish the small amount of heat ''DQ'' from an exact differential ''df'' (lowercase ''d'') of a function ''f'' of one or more variables.</ref> ''DQ'' = ''TdS'', loss of [[Energy_(science)#Work|energy]] by mechanical work done by the system &minus;''pdV'', and acquiring of substance, &mu; ''dn''. The states of  systems with three energy contacts are determined by three independent variables.  Although a fairly arbitrary choice of three variables is possible, it is most convenient to consider ''H(S,p,n)'', that is,  to describe ''H'' as  function of its "natural variables" [[entropy (thermodynamics)|entropy]] ''S'',  pressure ''p'', and amount of substance ''n''.<ref> If more than one substance is present ''n'' must be replaced by ''n''<sub>A</sub>,  ''n''<sub>B</sub>, ... (molar amounts of substances A, B, ... ).</ref>
 
In thermodynamics one usually works with differentials. In this case
:<math>
dH = dU + pdV + Vdp \,
</math>
The internal energy ''dU''  and the corresponding enthalpy ''dH'' are
:<math>
:<math>
\Delta W = p dV \,
dU = TdS - pdV + \mu dn \;\Longrightarrow\; dH = TdS + Vdp +\mu dn
</math>
</math>
If ''dV'' > 0 the volume of the system increases and work is performed ''by'' the system, if ''dV'' <0, work is performed ''on'' the system, hence the internal energy increase of the system by the work  term obtains a minus sign:
The rightmost side is an  equation for the ''characteristic function H'' in terms of the ''natural variables'' ''S'', ''p'', and ''n''.
 
The [[first law of thermodynamics]] can be written&mdash;for a system with constant amount of substance&mdash;as
:<math>
:<math>
dU = \Delta Q -\Delta W \, \quad\quad\quad\ (1)
DQ = dU + pdV \,
</math>
</math>
Notes:
If we keep ''p'' constant (an isobaric process) and integrate from state 1 to state 2, we find
*Other forms of work are possible, for instance [[magnetization]] &Delta;''W'' = '''H'''•d'''M''', inner product of magnetic field (a vector) '''H'''&mdash;not to be confused with enthalpy ''H''&mdash;with small change in molar magnetization ''d''<b>M</b> (also a vector).
:<math>
* The symbol &Delta; indicates a small quantity (sometimes called an inexact differential), not necessarily a differential. The symbol ''d'' indicates a [[differential]] of a differentiable function
\int_1^2 DQ = \int_1^2 dU + \int_1^2 pdV \;\Longrightarrow\;
::<math>
Q = U_2 - U_1 + p(V_2-V_1) = (U_2 +pV_2) - (U_1 + pV_1) = H_2 - H_1 = \int_1^2 dH,
dF(x_0) \equiv \lim_{x\rightarrow 0} \frac{F(x_0+x)-F(x_0)}{x} x
</math>
</math>
* Remarkable about equation (1) is that the sum of two small quantities (inexact differentials)  
where symbolically the total amount of heat absorbed by the system, ''Q'', is written as an integral.
gives a differential of a state function. This is why equation (1) is the first fundamental law (postulate) of thermodynamics
The other integrals have the usual definition of [[integral]]s of functions. The final equation (valid for an isobaric process) is
:<math>
H_2-H_1 = Q. \,
</math>
In other words, if the only work done is a change of volume at constant pressure, ''W'' = ''p''(''V''<sub>2</sub> &minus; ''V''<sub>1</sub>), the enthalpy change ''H''<sub>2</sub> &minus; ''H''<sub>1</sub> is exactly equal to the heat ''Q'' transferred to the system.
 
As with other thermodynamic energy functions, it is neither convenient nor necessary to determine absolute values of enthalpy. For each substance, the zero-enthalpy state can be some convenient reference state.


'''To be continued'''
==Notes==
<!--
<references />[[Category:Suggestion Bot Tag]]
According to the law of energy conservation, the change in internal energy is equal to the heat transferred to, less the work done by, the system. If the only work done is a change of volume at constant pressure, the enthalpy change is exactly equal to the heat transferred to the system. As with other energy functions, it is neither convenient nor necessary to determine absolute values of enthalpy. For each substance, the zero-enthalpy state can be some convenient reference state.
--->

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In thermodynamics, enthalpy is the sum of the internal energy U and the product of pressure p and volume V of a system,

The characteristic function (also known as thermodynamic potential) "enthalpy" used to be called "heat contents", which is why it is conventionally indicated by H. The term "enthalpy" was coined by the Dutch physicist Heike Kamerling Onnes.[1]

The internal energy U and the work term pV have dimension of energy, in SI units this is joule; the extensive (linear in size) quantity H has the same dimension.

Enthalpy (as the extensive property mentioned above) has corresponding intensive (size-independent) properties for pure materials. A corresponding intensive property is specific enthalpy, which is enthalpy per mass of substance involved. Specific enthalpy is denoted by a lower case h, with dimension of energy per mass (SI unit: joule/kg). If a molecular mass or number of moles involved can be assigned, then another corresponding intensive property is molar enthalpy, which is enthalpy per mole of the compound involved, or alternatively specific enthalpy times molecular mass. There is no universally agreed upon symbol for molar properties, and molar enthalpy has been at times confusingly symbolized by H, as in extensive enthalpy. The dimensions of molar enthalpy are energy per number of moles (SI unit: joule/mole).

In terms of intensive properties, specific enthalpy can be correspondingly defined as follows:

where

h = specific enthalpy
u = specific internal energy
p = pressure (as before)
v = specific volume = reciprocal of density

Enthalpy is a function depending on the independent variables that describe the state of the thermodynamic system. Most commonly one considers systems that have three forms of energy contact with their surroundings, namely the reversible and infinitesimal gain of heat,[2] DQ = TdS, loss of energy by mechanical work done by the system −pdV, and acquiring of substance, μ dn. The states of systems with three energy contacts are determined by three independent variables. Although a fairly arbitrary choice of three variables is possible, it is most convenient to consider H(S,p,n), that is, to describe H as function of its "natural variables" entropy S, pressure p, and amount of substance n.[3]

In thermodynamics one usually works with differentials. In this case

The internal energy dU and the corresponding enthalpy dH are

The rightmost side is an equation for the characteristic function H in terms of the natural variables S, p, and n.

The first law of thermodynamics can be written—for a system with constant amount of substance—as

If we keep p constant (an isobaric process) and integrate from state 1 to state 2, we find

where symbolically the total amount of heat absorbed by the system, Q, is written as an integral. The other integrals have the usual definition of integrals of functions. The final equation (valid for an isobaric process) is

In other words, if the only work done is a change of volume at constant pressure, W = p(V2V1), the enthalpy change H2H1 is exactly equal to the heat Q transferred to the system.

As with other thermodynamic energy functions, it is neither convenient nor necessary to determine absolute values of enthalpy. For each substance, the zero-enthalpy state can be some convenient reference state.

Notes

  1. Alfred W. Porter, (in: The Generation and Utilisation of Cold. A general discussion, Transactions Faraday Society, 1922, vol. 18, pp. 139–143 DOI) gives credit to Kamerling Onnes and proposes the letter H, either standing for "Heat contents", or capital eta as in Hνθαλπος (Enthalpos), although the Greek word starts with capital epsilon. See also Irmgard K. Howard, H Is for Enthalpy, Thanks to Heike Kamerlingh Onnes and Alfred W. Porter, Journal Chemical Education, 2002, vol. 79, pp. 697–698 online
  2. Capital D is written to distinguish the small amount of heat DQ from an exact differential df (lowercase d) of a function f of one or more variables.
  3. If more than one substance is present n must be replaced by nA, nB, ... (molar amounts of substances A, B, ... ).