Defining equation (physical chemistry) explained

See main article: Physical chemistry.

In physical chemistry, there are numerous quantities associated with chemical compounds and reactions; notably in terms of amounts of substance, activity or concentration of a substance, and the rate of reaction. This article uses SI units.

Introduction

Theoretical chemistry requires quantities from core physics, such as time, volume, temperature, and pressure. But the highly quantitative nature of physical chemistry, in a more specialized way than core physics, uses molar amounts of substance rather than simply counting numbers; this leads to the specialized definitions in this article. Core physics itself rarely uses the mole, except in areas overlapping thermodynamics and chemistry.

Notes on nomenclature

Entity refers to the type of particle/s in question, such as atoms, molecules, complexes, radicals, ions, electrons etc.

Conventionally for concentrations and activities, square brackets [] are used around the chemical molecular formula. For an arbitrary atom, generic letters in upright non-bold typeface such as A, B, R, X or Y etc. are often used.

No standard symbols are used for the following quantities, as specifically applied to a substance:

the mass of a substance m,
the number of moles of the substance n,
partial pressure of a gas in a gaseous mixture p (or P),
some form of energy of a substance (for chemistry enthalpy H is common),
entropy of a substance S
the electronegativity of an atom or chemical bond χ.

Usually the symbol for the quantity with a subscript of some reference to the quantity is used, or the quantity is written with the reference to the chemical in round brackets. For example, the mass of water might be written in subscripts as m_H2O, m_water, m_aq, m_w (if clear from context) etc., or simply as m(H₂O). Another example could be the electronegativity of the fluorine-fluorine covalent bond, which might be written with subscripts χ_F-F, χ_FF or χ_F-F etc., or brackets χ(F-F), χ(FF) etc.

Neither is standard. For the purpose of this article, the nomenclature is as follows, closely (but not exactly) matching standard use.

For general equations with no specific reference to an entity, quantities are written as their symbols with an index to label the component of the mixture - i.e. q_i. The labeling is arbitrary in initial choice, but once chosen fixed for the calculation.

If any reference to an actual entity (say hydrogen ions H⁺) or any entity at all (say X) is made, the quantity symbol q is followed by curved brackets enclosing the molecular formula of X, i.e. q(X), or for a component i of a mixture q(X_i). No confusion should arise with the notation for a mathematical function.

Quantification

General basic quantities

Quantity (Common Name/s)	(Common) Symbol/s	SI Units	Dimension
Number of molecules	N	dimensionless	dimensionless
Mass	m	kg	[M]
Number of moles, amount of substance, amount	n	mol	[N]
Volume of mixture or solvent, unless otherwise stated	V	m³	[L]³

General derived quantities

See main article: Concentration.

Quantity (Common Name/s)

(Common) Symbol/s

Defining Equation

SI Units

Dimension

Relative atomic mass of an element

A_r, A, m_ram

A_r\left({\rmX}\right)=

	\langlem\left({\rmX
	\right

)\rangle}{m\left(¹²{\rmC}\right)/12}

The average mass

\langlem\left({\rmX}\right)\rangle

is the average of the T masses m_i(X) corresponding the T isotopes of X (i is a dummy index labelling each isotope):

\langlem\left({\rmX}\right)\rangle=

	1
	T

	T
\sum
	i

m\left({\rmX}_i\right)

dimensionless

Relative formula mass of a compound, containing elements X_j

M_r, M, m_rfm

M_r\left({\rmY}\right)=\sum_jN\left({\rmX}_j\right)A_r\left({\rmX}_j\right)=

	\sum_jN\left({\rmX
	_j

\right)\langlem\left({\rmX}_j\right)\rangle}{m\left(¹²{\rmC}\right)/12}

j = index labelling each element,
N = number of atoms of each element X_i.

dimensionless

Molar concentration, concentration, molarity of a component i in a mixture

c_i, [X<sub>''i''</sub>]

c_i=\left[{\rmX}_i\right]=

	dn_i
	dV

mol dm⁻³ = 10⁻³ mol m⁻³

[N] [L]⁻³

Molality of a component i in a mixture

b_i, b(X_i)

b_i=

	n_i
	m_\rm

where solv = solvent (liquid solution).

mol kg⁻¹

[N] [M]⁻¹

Mole fraction of a component i in a mixture

x_i, x(X_i)

x_i=

	n_i
	n_\rm

where Mix = mixture.

dimensionless

Partial pressure of a gaseous component i in a gas mixture

p_i, p(X_i)

p\left({\rmX}_i\right)=x_ip\left({\rmmix}\right)

where mix = gaseous mixture.

Pa = N m⁻²

[M][T][L]⁻¹

Density, mass concentration

ρ_i, γ_i, ρ(X_i)

\rho=m_i/V

kg m⁻³

[M] [L]³

Number density, number concentration

C_i, C(X_i)

C_i=N_i/V

m^{− 3}

[L]^{− 3}

Volume fraction, volume concentration

ϕ_i, ϕ(X_i)

\phi_i=

	V_i
	V_\rm

dimensionless

Mixing ratio, mole ratio

r_i, r(X_i)

r_i=

	n_i
	n_\rm-n_i

dimensionless

Mass fraction

w_i, w(X_i)

w_i=m_i/m_\rm

m(X_i) = mass of X_i

dimensionless

Mixing ratio, mass ratio

ζ_i, ζ(X_i)

\zeta_i=

	m_i
	m_\rm-m_i

m(X_i) = mass of X_i

dimensionless

Kinetics and equilibria

The defining formulae for the equilibrium constants K_c (all reactions) and K_p (gaseous reactions) apply to the general chemical reaction:

+ + \cdots + \nu_\mathit X_\mathit <=> + + \cdots + \eta_\mathit _\mathit

and the defining equation for the rate constant k applies to the simpler synthesis reaction (one product only):

+ + \cdots + \nu_\mathit X_\mathit -> \eta

where:

i = dummy index labelling component i of reactant mixture,
j = dummy index labelling component i of product mixture,
X_i = component i of the reactant mixture,
Y_j = reactant component j of the product mixture,
r (as an index) = number of reactant components,
p (as an index) = number of product components,
ν_i = stoichiometry number for component i in product mixture,
η_j = stoichiometry number for component j in product mixture,
σ_i = order of reaction for component i in reactant mixture.

The dummy indices on the substances X and Y label the components (arbitrary but fixed for calculation); they are not the numbers of each component molecules as in usual chemistry notation.

The units for the chemical constants are unusual since they can vary depending on the stoichiometry of the reaction, and the number of reactant and product components. The general units for equilibrium constants can be determined by usual methods of dimensional analysis. For the generality of the kinetics and equilibria units below, let the indices for the units be;

$S_1 = \sum_^p \eta_j - \sum_^r \nu_i \,,\quad\, S_2 = 1-\sum_^ \sigma_i\,.$

For the constant K_c;

Substitute the concentration units into the equation and simplify:,

$\beginK_c & = \frac \\\left[K_c\right] & = \frac \\ & = \frac \\ & = \frac \\ & = [\ce M]^\end\ (\ce)$

The procedure is exactly identical for K_p.

For the constant k

$\begink & = \frac \\\left[k\right] & = \frac \\ & = \frac \\ & = [\ce M]^ s^\end$

Quantity (Common Name/s)

(Common) Symbol/s

Defining Equation

SI Units

Dimension

Reaction progress variable, extent of reaction

\xi

dimensionless

Stoichiometric coefficient of a component i in a mixture, in reaction j (many reactions could occur at once)

ν_i

\nu_ij=

	dN_i
	d\xi_j

where N_i = number of molecules of component i.

dimensionless

Chemical affinity

A=-\left(

	\partialG
	\partial\xi

\right)_P,T

[M][L]²[T]⁻²

Reaction rate with respect to component i

r, R

R_i=

	1
	\nu_i

	d\left[X_i\right]
	dt

mol dm⁻³ s⁻¹ = 10⁻³ mol m⁻³ s⁻¹

[N] [L]⁻³ [T]⁻¹

Activity of a component i in a mixture

a_i

a_i=

\left

(\mu_i-

	\ominus
\mu
	i

\right)/RT

dimensionless

Mole fraction, molality, and molar concentration activity coefficients

γ_xi for mole fraction, γ_bi for molality, γ_ci for molar concentration.

Three coefficients are used;

a_i=\gamma_xix_i

a_i=\gamma_bi

	\ominus
b
	i/b

a_i=\gamma_ci\left[X_i\right]/\left[X_i\right]^\ominus

dimensionless

Rate constant

d\left[Y\right]/dt

\prod

\left[X_i\right

	\sigma_i
]

i=1

(mol dm⁻³)^(S2) s⁻¹

([N] [L]⁻³)^(S2) [T]⁻¹

General equilibrium constant^[1]

K_c

K_c=

\prod

\left[Y_j\right

	η_j
]

j=1

\prod

\left[X_i\right

	\nu_i
]

i=1

(mol dm⁻³)^(S1)

([N] [L]⁻³)^(S1)

General thermodynamic activity constant ^[2]

K₀

K₀=

\prod

a\left(Y_j\right

	η_j
)

j=1

\prod

a\left(X_i\right

	\nu_i
)

i=1

a(X_i) and a(Y_j) are activities of X_i and Y_j respectively.

(mol dm⁻³)^(S1)

([N] [L]⁻³)^(S1)

Equilibrium constant for gaseous reactions, using Partial pressures

K_p

K_p=

\prod

p\left(Y_j\right

	η_j
)

j=1

\prod

p\left(X_i\right

	\nu_i
)

i=1

Pa^(S1)

([M] [L]⁻¹ [T]⁻²)^(S1)

Logarithm of any equilibrium constant

pK_c

pK_c=-log₁₀K_c=

	p
\sum
	j=1

η_jlog₁₀\left[Y_j\right]-

	r
\sum
	i=1

\nu_ilog₁₀\left[X_i\right]

dimensionless

Logarithm of dissociation constant

pK=-log₁₀K

dimensionless

pH=-log₁₀[H^+]

dimensionless

pOH

pOH=-log₁₀[OH^-]

dimensionless

Electrochemistry

Notation for half-reaction standard electrode potentials is as follows. The redox reaction

A + BX <=> B + AX

split into:

a reduction reaction: B+ + e^- <=> B
and an oxidation reaction: A+ + e^- <=> A

(written this way by convention) the electrode potential for the half reactions are written as $E^\ominus\left(\ce \vert \ce \right)$ and $E^\ominus\left(\ce \vert \ce \right)$ respectively.

For the case of a metal-metal half electrode, letting M represent the metal and z be its valency, the half reaction takes the form of a reduction reaction:

+ \mathit e^- <=> M

Quantity (Common Name/s)

(Common) Symbol/s

Defining Equation

SI Units

Dimension

Standard EMF of an electrode

E^\ominus, E^\ominus\left(\ce \right)

\Delta E^\ominus \left(\ce \right) = E^ \left(\ce \right) - E^ \left(\ce \right)

where Def is the standard electrode of definition, defined to have zero potential. The chosen one is hydrogen:

$E^ \left(\ce \right) = E^ \left(\ce \vert \ce \right) = 0$

[M][L]²[I][T]⁻¹

Standard EMF of an electrochemical cell

	\ominus
E
	cell

,\DeltaE^\ominus

	\ominus
E
	cell

=E^{\ominus\left(}Cat\right)-E^{\ominus\left(}An\right)

where Cat is the cathode substance and An is the anode substance.

[M][L]²[I][T]⁻¹

Ionic strength

Two definitions are used, one using molarity concentration,

$I = \frac\sum_^ z_i^ \left [{\rm X}_i \right ]$

and one using molality,^[3]

$I = \frac\sum_^ z_i^ b_i$

The sum is taken over all ions in the solution.

mol dm⁻³
or
mol dm⁻³ kg⁻¹

[N] [L]⁻³ [M]⁻¹

Electrochemical potential (of component i in a mixture)

\bar{\mu}_i

\bar{\mu}_i=\mu-zeN_A\phi

φ = local electrostatic potential (see below also)z_i = valency (charge) of the ion i

[M][L]²[T]⁻²

Sources

Physical chemistry, P.W. Atkins, Oxford University Press, 1978,
Chemistry, Matter and the Universe, R.E. Dickerson, I. Geis, W.A. Benjamin Inc. (USA), 1976,
Chemical thermodynamics, D.J.G. Ives, University Cchemistry Series, Macdonald Technical and Scientific co. .
Elements of Statistical Thermodynamics (2nd Edition), L.K. Nash, Principles of Chemistry, Addison-Wesley, 1974,
Statistical Physics (2nd Edition), F. Mandl, Manchester Physics, John Wiley & Sons, 2008,

Notes and References

Quantitative Chemical Analysis (4th Edition), I.M. Kolthoff, E.B. Sandell, E.J. Meehan, S. Bruckenstein, The Macmillan Co. (USA) 1969, Library of Congress Catalogue Number 69 10291
Quantitative Chemical Analysis (4th Edition), I.M. Kolthoff, E.B. Sandell, E.J. Meehan, S. Bruckenstein, The Macmillan Co. (USA) 1969, Library of Congress Catalogue Number 69 10291
Physical chemistry, P.W. Atkins, Oxford University Press, 1978,

Defining equation (physical chemistry) explained

Introduction

Notes on nomenclature

Quantification

General basic quantities

General derived quantities

Kinetics and equilibria

Electrochemistry

Sources

Further reading

Notes and References