The
Bohr–Van Leeuwen theorem proves that there cannot be any diamagnetism or paramagnetism in a purely classical system. The paramagnetic response has then two possible quantum origins, either coming from permanent magnetic moments of the ions or from the spatial motion of the conduction electrons inside the material. Both descriptions are given below.
Curie's law For low levels of magnetization, the magnetization of paramagnets follows what is known as
Curie's law, at least approximately. This law indicates that the susceptibility, \chi, of paramagnetic materials is inversely proportional to their temperature, i.e. that materials become more magnetic at lower temperatures. The mathematical expression is: \mathbf{M} = \chi\mathbf{H} = \frac{C}{T}\mathbf{H} where: • \mathbf M is the resulting magnetization, measured in
amperes/meter (A/m), • \chi is the
volume magnetic susceptibility (
dimensionless), • H is the auxiliary
magnetic field (A/m), • T is absolute temperature, measured in
kelvins (K), • C is a material-specific
Curie constant (K). Curie's law is valid under the commonly encountered conditions of low magnetization (
μB
H ≲
kB
T), but does not apply in the high-field/low-temperature regime where saturation of magnetization occurs (
μB
H ≳
kB
T) and magnetic dipoles are all aligned with the applied field. When the dipoles are aligned, increasing the external field will not increase the total magnetization since there can be no further alignment. For a paramagnetic ion with noninteracting magnetic moments with angular momentum
J, the Curie constant is related to the individual ions' magnetic moments, C=\frac{n}{3k_\mathrm{B}}\mu_{\mathrm{eff}}^2 \text{ where } \mu_{\mathrm{eff}} = g_J \mu_\mathrm{B} \sqrt{J(J+1)}. where
n is the number of atoms per unit volume. The parameter
μeff is interpreted as the effective magnetic moment per paramagnetic ion. If one uses a classical treatment with molecular magnetic moments represented as discrete magnetic dipoles,
μ, a Curie Law expression of the same form will emerge with
μ appearing in place of
μeff. {{math proof | title = Derivation | proof = Curie's Law can be derived by considering a substance with noninteracting magnetic moments with angular momentum
J. If orbital contributions to the magnetic moment are negligible (a common case), then in what follows
J =
S. If we apply a magnetic field along what we choose to call the
z-axis, the energy levels of each paramagnetic center will experience
Zeeman splitting of its energy levels, each with a
z-component labeled by
MJ (or just
MS for the spin-only magnetic case). Applying semiclassical
Boltzmann statistics, the magnetization of such a substance is n\bar{m} = \frac{n\sum\limits_{M_{J} = -J}^{J}{\mu_{M_{J}}e^{{-E_{M_{J}}}/{k_{\mathrm{B}}T}\;}}}{\sum\limits_{M_{J} = -J}^{J}{e^{{-E_{M_{J}}}/{k_{\mathrm{B}}T}\;}}} = \frac{n\sum\limits_{M_{J} = -J}^{J}{M_{J}g_{J}\mu_{\mathrm{B}}e^{{M_{J}g_{J}\mu_{\mathrm{B}}H}/{k_{\mathrm{B}}T}\;}}}{\sum\limits_{M_{J} = -J}^{J}{e^{{M_{J}g_{J}\mu_{\mathrm{B}}H}/{k_{\mathrm{B}}T}\;}}}. Where \mu_{M_J} is the
z-component of the magnetic moment for each Zeeman level, so \mu _{M_J} = M_J g_J\mu_\mathrm{B} - \mu_\mathrm{B} is called the
Bohr magneton and
gJ is the
Landé g-factor, which reduces to the free-electron g-factor,
gS when
J =
S. (in this treatment, we assume that the
x- and
y-components of the magnetization, averaged over all molecules, cancel out because the field applied along the
z-axis leave them randomly oriented.) The energy of each Zeeman level is E_{M_J} = -M_J g_J \mu_\mathrm{B} H. For temperatures over a few
K, M_J g_J \mu_\mathrm{B}H/k_\mathrm{B} T \ll 1, and we can apply the approximation e^{M_J g_J \mu_\mathrm{B} H /k_\mathrm{B} T\;} \simeq 1 + M_J g_J \mu_\mathrm{B} H/k_\mathrm{B} T\;: \bar{m}=\frac{\sum\limits_{M_J=-J}^J {M_J g_J \mu_\mathrm{B} e^{M_J g_J \mu_\mathrm{B} H/k_\mathrm{B} T\;}}}{\sum\limits_{M_J=-J}^J e^{M_Jg_J\mu_\mathrm{B} H/k_\mathrm{B} T\;}}\simeq g_J\mu_\mathrm{B} \frac{\sum\limits_{M_J=-J}^J M_J \left( 1+M_J g_J\mu_\mathrm{B} H/k_\mathrm{B} T\; \right)}{\sum\limits_{M_J=-J}^J \left( 1+M_J g_J \mu_\mathrm{B} H/k_\mathrm{B} T \; \right)}=\frac{g_J^2 \mu_\mathrm{B}^2 H}{k_\mathrm{B} T} \frac{\sum\limits_{-J}^J M_J^2}{\sum\limits_{M_J=-J}^J{(1)}}, which yields: \bar{m}=\frac{g_J^2 \mu_\mathrm{B}^2 H}{3k_\mathrm{B} T} J(J+1). The bulk magnetization is then M = n\bar{m} = \frac{n}{3k_\mathrm{B}T} \left[ g_J^2 J(J+1) \mu_\mathrm{B}^2 \right]H, and the susceptibility is given by \chi=\frac{\partial M_{\rm m}}{\partial H} = \frac{n}{3k_{\rm B} T} \mu_{\mathrm{eff}}^2 \text{ ; and } \mu_{\mathrm{eff}} = g_J \sqrt{J(J+1)} \mu_{\mathrm B}. }} When orbital angular momentum contributions to the magnetic moment are small, as occurs for most
organic radicals or for octahedral transition metal complexes with d3 or high-spin d5 configurations, the effective magnetic moment takes the form ( with
g-factor ge = 2.0023... ≈ 2), \mu_{\mathrm{eff}}\simeq 2\sqrt{S(S+1)} \mu_\mathrm{B} =\sqrt{N_{\rm u}(N_{\rm u}+2)} \mu_\mathrm{B}, where
Nu is the number of
unpaired electrons. In other transition metal complexes this yields a useful, if somewhat cruder, estimate. When Curie constant is null, second order effects that couple the ground state with the excited states can also lead to a paramagnetic susceptibility independent of the temperature, known as
Van Vleck susceptibility.
Pauli paramagnetism For some alkali metals and noble metals, conduction electrons are weakly interacting and delocalized in space forming a
Fermi gas. For these materials one contribution to the magnetic response comes from the interaction between the electron spins and the magnetic field known as Pauli paramagnetism. For a small magnetic field \mathbf{H}, the additional energy per electron from the interaction between an electron spin and the magnetic field is given by: : \Delta E= -\mu_0\mathbf{H}\cdot\boldsymbol{\mu}_\text{e}=- \mu_0\mathbf{H}\cdot\left(-g_\text{e}\frac{\mu_\mathrm{B}}{\hbar}\mathbf{S}\right)=\pm \mu_0 \mu_\mathrm{B} H, where \mu_0 is the
vacuum permeability, \boldsymbol{\mu}_\text{e} is the
electron magnetic moment, \mu_{\rm B} is the
Bohr magneton, \hbar is the reduced Planck constant, and the
g-factor cancels with the spin \mathbf{S}=\pm\hbar/2. The \pm indicates that the sign is positive (negative) when the electron spin component in the direction of \mathbf{H} is parallel (antiparallel) to the magnetic field. For low temperatures with respect to the
Fermi temperature T_{\rm F} (around for metals), the
number density of electrons n_{\uparrow} (n_{\downarrow}) pointing parallel (antiparallel) to the magnetic field can be written as: : n_{\uparrow}\approx\frac{n_\text{e}}{2}-\frac{\mu_0\mu_\mathrm{B}}{2}g(E_\mathrm{F})H\quad;\quad \left(n_{\downarrow}\approx\frac{n_\text{e}}{2}+\frac{\mu_0\mu_\mathrm{B}}{2}g(E_\mathrm{F})H\right), with n_\text{e} the total free-electron density and g(E_\mathrm{F}) the electronic density of states (number of states per energy per volume) at the
Fermi energy E_\mathrm{F}. In this approximation the magnetization is given as the magnetic moment of one electron times the difference in densities: : M=\mu_\mathrm{B}(n_{\downarrow}-n_{\uparrow})=\mu_0\mu_\mathrm{B}^2g(E_\mathrm{F})H, which yields a positive paramagnetic susceptibility independent of temperature: : \chi_\mathrm{P}=\mu_0\mu_\mathrm{B}^2g(E_\mathrm{F}). The Pauli paramagnetic susceptibility is a macroscopic effect and has to be contrasted with
Landau diamagnetic susceptibility which is equal to minus one third of Pauli's and also comes from delocalized electrons. The Pauli susceptibility comes from the spin interaction with the magnetic field while the Landau susceptibility comes from the spatial motion of the electrons and it is independent of the spin. In doped semiconductors the ratio between Landau's and Pauli's susceptibilities changes as the
effective mass of the charge carriers m^* can differ from the electron mass m_\text{e}. The magnetic response calculated for a gas of electrons is not the full picture as the magnetic susceptibility coming from the ions has to be included. Additionally, these formulas may break down for confined systems that differ from the bulk, like
quantum dots, or for high fields, as demonstrated in the
De Haas-Van Alphen effect. Pauli paramagnetism is named after the physicist
Wolfgang Pauli. Before Pauli's theory, the lack of a strong Curie paramagnetism in metals was an open problem as the
leading Drude model could not account for this contribution without the use of
quantum statistics. Pauli paramagnetism and Landau diamagnetism are essentially applications of the spin and the
free electron model, the first is due to intrinsic spin of electrons; the second is due to their orbital motion. == Examples of paramagnets ==