Difference between revisions of "Template:Concentration and density"

Latest revision as of 00:01, 21 October 2020

Concentration and density in different formats

Concentration is an extensive quantity divided by volume V, or a count divided by volume V. The elementary entities X (or B) or the sample type s have to be specified in the text or indicated by a subscript or in parentheses. Examples: cell-count concentration C_ce; count concentration of protons C_H⁺; molar concentration of protons c_H⁺. Density is not only 'mass density ρ, but is used for many extensive quantities divided by volume or area.

Concentration	Symbol	Definition	Unit	Note
Count concentration	C_X	= N_X·V^-1	[x·L^-1]	The IUPAC term 'number concentration' should be replaced by 'count concentration' (or 'number of entities concentration').
Amount concentration	c_B	= n_B·V^-1	[mol·L^-1]	Amount concentration is a counting concentration, converting the elementary unit [x] into moles [mol] using the Avogadro constant.
Charge concentration	C_{Q_X}	= Q_X·V^-1	[C·L^-1]	Charge concentration is a counting concentration, converting the elementary unit [x] into coulombs C using the elementary charge, or converting moles [mol] into coulombs [C] using the Faraday constant. Charge density in electricity is 'charge per volume'.
Mass concentration of X	C_{m_X}	= m_X·V^-1	[kg·L^-1]	Mass concentration C_{m_X} is mass of entities X per volume V of the mixture.
Mass density of S	ρ_S	= m_S·V_S^-1	[kg·L^-1]	Mass density ρ_S is mass of the pure sample S per volume V_S of the pure sample; ρ_S is the reciprocal of specific volume.
Volume concentration of X	C_{V_X}	= V_X·V^-1	[L·L^-1]	Volume concentration C_{V_X} is the volume of entities X per volume V of the mixture.
Volume density	Φ_X	= V_X·V^-1	[L·L^-1]	Volume density is equivalent to the volume fraction.

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 | [[Amount]] concentration || ''c''<sub>B</sub> || = ''n''<sub>B</sub>·''V''<sup>-1</sup> || [mol·L<sup>-1</sup>] || Amount concentration is a counting concentration, converting the elementary unit [x] into moles [mol] using the [[Avogadro constant]].
 |-
-| [[Charge]] density  || ''ρ<sub>e</sub>'' || = ''Q''<sub>X</sub>·''V''<sup>-1</sup> || [C·L<sup>-1</sup>] || Charge density in electricity is charge per volume. Charge density is a counting concentration, converting the elementary unit [x] into coulombs [[C]] using the [[elementary charge]], or converting moles [mol] into coulombs [C] using the [[Faraday constant]].
+| [[Charge]] concentration  || ''C<sub>Q<sub>X</sub></sub>'' || = ''Q''<sub>X</sub>·''V''<sup>-1</sup> || [C·L<sup>-1</sup>] || Charge concentration is a counting concentration, converting the elementary unit [x] into coulombs [[C]] using the [[elementary charge]], or converting moles [mol] into coulombs [C] using the [[Faraday constant]]. Charge density in electricity is 'charge per volume'.
 |-
-| Mass density of s || ''ρ''<sub>s</sub> || = ''m''<sub>s</sub>·''V''<sup>-1</sup> || [kg·L<sup>-1</sup>] || Mass density ''ρ''<sub>s</sub> is mass of sample s per volume ''V'' of the mixture.
+| Mass concentration of ''X'' || ''C''<sub>''m''<sub>''X''</sub></sub> || = ''m''<sub>''X''</sub>·''V''<sup>-1</sup> || [kg·L<sup>-1</sup>] || Mass concentration ''C''<sub>''m''<sub>''X''</sub></sub> is mass of entities ''X'' per volume ''V'' of the mixture.
 |-
 | Mass density of S || ''ρ''<sub>S</sub> || = ''m''<sub>S</sub>·''V''<sub>S</sub><sup>-1</sup> || [kg·L<sup>-1</sup>] || Mass density ''ρ''<sub>S</sub> is mass of the pure sample S per volume ''V''<sub>S</sub> of the pure sample; ''ρ''<sub>S</sub> is the reciprocal of specific volume.
 |-
-| Volume density || ''Φ''<sub>X</sub> || = ''V''<sub>X</sub>·''V''<sup>-1</sup> || [L·L<sup>-1</sup>] || Volume density is equivalent to the [[volume fraction]].
+| Volume concentration of ''X'' || ''C''<sub>''V''<sub>''X''</sub></sub> || = ''V''<sub>''X''</sub>·''V''<sup>-1</sup> || [L·L<sup>-1</sup>] || Volume concentration ''C''<sub>''V''<sub>''X''</sub></sub> is the volume of entities ''X'' per volume ''V'' of the mixture.
-|}
-<big>'''Density of the pure sample'''</big>
-:::: {| class="wikitable"
-|-
-! Concentration !! Symbol !! Definition !! Unit !! Note
-|-
-| [[Count]] concentration || ''C<sub>X</sub>'' || = ''N<sub>X</sub>''·''V''<sup>-1</sup> || [x·L<sup>-1</sup>] || The IUPAC term 'number concentration' should be replaced by 'count concentration' (or 'number of entities concentration').
-|-
-| [[Amount]] concentration || ''c''<sub>B</sub> || = ''n''<sub>B</sub>·''V''<sup>-1</sup> || [mol·L<sup>-1</sup>] || Amount concentration is a counting concentration, converting the elementary unit [x] into moles [mol] using the [[Avogadro constant]].
-|-
-| [[Charge]] density  || ''ρ<sub>e</sub>'' || = ''Q''<sub>X</sub>·''V''<sup>-1</sup> || [C·L<sup>-1</sup>] || Charge density in electricity is charge per volume. Charge density is a counting concentration, converting the elementary unit [x] into coulombs [[C]] using the [[elementary charge]], or converting moles [mol] into coulombs [C] using the [[Faraday constant]].
-|-
-| Mass density of s || ''ρ''<sub>s</sub> || = ''m''<sub>s</sub>·''V''<sup>-1</sup> || [kg·L<sup>-1</sup>] || Mass density ''ρ''<sub>s</sub> is mass of sample s per volume ''V'' of the mixture.
-|-
-| Mass density of S || ''ρ''<sub>S</sub> || = ''m''<sub>S</sub>·''V''<sub>S</sub><sup>-1</sup> || [kg·L<sup>-1</sup>] || Mass density ''ρ''<sub>S</sub> is mass of the pure sample S per volume ''V''<sub>S</sub> of the pure sample; ''ρ''<sub>S</sub> is the reciprocal of specific volume.
 |-
 | Volume density || ''Φ''<sub>X</sub> || = ''V''<sub>X</sub>·''V''<sup>-1</sup> || [L·L<sup>-1</sup>] || Volume density is equivalent to the [[volume fraction]].
 |}