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For a given material or [[chemical substance|substance]], the standard state is the '''reference state''' for the material's thermodynamic state properties such as [[enthalpy]], [[entropy]], [[Gibbs free energy]], and for many other material standards. The [[Standard enthalpy change of formation|standard enthalpy of formation]] for an element in its standard state is 0.
For a given material or [[chemical substance|substance]], the standard state is the '''reference state''' for the material's thermodynamic state properties such as [[enthalpy]], [[entropy]], [[Gibbs free energy]], and for many other material standards. The [[Standard enthalpy change of formation|standard enthalpy of formation]] for an element in its standard state is 0.


When the standard state is referred to in a [[chemical reaction]], it also includes the condition that the [[concentration]]s of all [[solution]]s are at unity in whatever measure of concentration is specified. If that is [[molarity]] that would be 1 [[Mole (unit)|mol]]·[[Decimetre|dm]]<sup>-3</sup> and for [[molality]] 1 [[Mole (unit)|mol]]·[[kg]]<sup>-1</sup>. If [[mole fraction]] is used, the pure liquid or solid is the standard state (x=1). As it is possible (and in principle legitimate) to take a different unit for each of the species in the reaction, the nature of the standard state needs to be '''''specified''''' when reporting or tabulating. Although a definition involving 1 [[Mole (unit)|mol]]/[[Litre|L]] (molarity at unity) of A in combination with pure B (mole fraction at unity) is clearly a condition that can never be met, such a non-existent standard state nevertheless leads to a consistent system of tabulated values, provided it is used consistently by all. Of course these values are ''different'' from those where a different standard state is adopted.
When the standard state is referred to in a [[chemical reaction]], it also includes the condition that the [[concentration]]s of all [[solution]]s are at unity (or another designated quantity) for whatever measure of concentration is specified. If that is [[molarity]] that would be 1 [[Mole (unit)|mol]]·[[Decimetre|dm]]<sup>-3</sup> and for [[molality]] 1 [[Mole (unit)|mol]]·[[kg]]<sup>-1</sup>. If [[mole fraction]] is used, the pure liquid or solid is the standard state (x=1). As it is possible (and in principle legitimate) to take a different unit for each of the species in the reaction, the nature of the standard state needs to be '''''specified''''' when reporting or tabulating. Although a definition involving 1 [[Mole (unit)|mol]]/[[Litre|L]] (molarity at unity) of A in combination with pure B (mole fraction at unity) is clearly a condition that can never be met, such a non-existent standard state nevertheless leads to a consistent system of tabulated values, provided it is used consistently by all. Of course these values are ''different'' from those where a different standard state is adopted.


In the time of their development (the 19th century) the [[Plimsoll]] - symbol was adopted as a superscript <sup><s>o</s></sup> to indicate the non-zero nature of the chosen reference state. For typographic reasons this symbol is often abridged to a rather misleading zero superscript <sup>o</sup> in later texts.
In the time of their development (the 19th century) the [[Plimsoll]] - symbol was adopted as a superscript <sup><s>o</s></sup> to indicate the non-zero nature of the chosen reference state. For typographic reasons this symbol is often abridged to a rather misleading zero superscript <sup>o</sup> in later texts.

Revision as of 20:29, 23 July 2007

The plimsoll symbol as used in shipping

In chemistry, the standard state of a material is its state at 1 bar (100 kilopascals exactly). This pressure was changed from 1 atm (101.325 kilopascals) by IUPAC in 1990[1]. The standard state of a material can be defined at any given temperature, most commonly 25 degrees Celsius, although quite a few texts (especially in related disciplines such as physics and engineering) use 0 degrees Celsius for Standard Temperature and Pressure (STP).

It should be noted that the standard state is an arbitrarily chosen non-zero value, not a natural zero point.

For a given material or substance, the standard state is the reference state for the material's thermodynamic state properties such as enthalpy, entropy, Gibbs free energy, and for many other material standards. The standard enthalpy of formation for an element in its standard state is 0.

When the standard state is referred to in a chemical reaction, it also includes the condition that the concentrations of all solutions are at unity (or another designated quantity) for whatever measure of concentration is specified. If that is molarity that would be 1 mol·dm-3 and for molality 1 mol·kg-1. If mole fraction is used, the pure liquid or solid is the standard state (x=1). As it is possible (and in principle legitimate) to take a different unit for each of the species in the reaction, the nature of the standard state needs to be specified when reporting or tabulating. Although a definition involving 1 mol/L (molarity at unity) of A in combination with pure B (mole fraction at unity) is clearly a condition that can never be met, such a non-existent standard state nevertheless leads to a consistent system of tabulated values, provided it is used consistently by all. Of course these values are different from those where a different standard state is adopted.

In the time of their development (the 19th century) the Plimsoll - symbol was adopted as a superscript o to indicate the non-zero nature of the chosen reference state. For typographic reasons this symbol is often abridged to a rather misleading zero superscript o in later texts.

See also

Notes