Hyperpolarizability

The hyperpolarizability, a nonlinear-optical property of a molecule, is the second order electric susceptibility per unit volume.^[1] The hyperpolarizability can be calculated using quantum chemical calculations developed in several software packages.^[2]^[3]^[4] See nonlinear optics.

Definition and higher orders

The linear electric polarizability $\alpha$ in isotropic media is defined as the ratio of the induced dipole moment $\mathbf {p}$ of an atom to the electric field $\mathbf {E}$ that produces this dipole moment.^[5]

Therefore, the dipole moment is:

\mathbf {p} =\alpha \mathbf {E}

In an isotropic medium $\mathbf {p}$ is in the same direction as $\mathbf {E}$ , i.e. $\alpha$ is a scalar. In an anisotropic medium $\mathbf {p}$ and $\mathbf {E}$ can be in different directions and the polarisability is now a tensor.

The total density of induced polarization is the product of the number density of molecules multiplied by the dipole moment of each molecule, i.e.:

\mathbf {P} =\rho \mathbf {p} =\rho \alpha \mathbf {E} =\varepsilon _{0}\chi \mathbf {E} ,

where $\rho$ is the concentration, $\varepsilon _{0}$ is the vacuum permittivity, and $\chi$ is the electric susceptibility.

In a nonlinear optical medium, the polarization density is written as a series expansion in powers of the applied electric field, and the coefficients are termed the non-linear susceptibility:

\mathbf {P} (t)=\varepsilon _{0}\left(\chi ^{(1)}\mathbf {E} (t)+\chi ^{(2)}\mathbf {E} ^{2}(t)+\chi ^{(3)}\mathbf {E} ^{3}(t)+\ldots \right),

where the coefficients χ⁽ⁿ⁾ are the n-th-order susceptibilities of the medium, and the presence of such a term is generally referred to as an n-th-order nonlinearity. In isotropic media $\chi ^{(n)}$ is zero for even n, and is a scalar for odd n. In general, χ⁽ⁿ⁾ is an (n + 1)-th-rank tensor. It is natural to perform the same expansion for the non-linear molecular dipole moment:

\mathbf {p} (t)=\alpha ^{(1)}\mathbf {E} (t)+\alpha ^{(2)}\mathbf {E} ^{2}(t)+\alpha ^{(3)}\mathbf {E} ^{3}(t)+\ldots ,

i.e. the n-th-order susceptibility for an ensemble of molecules is simply related to the n-th-order hyperpolarizability for a single molecule by:

\alpha ^{(n)}={\frac {\varepsilon _{0}}{\rho }}\chi ^{(n)}.

With this definition $\alpha ^{(1)}$ is equal to $\alpha$ defined above for the linear polarizability. Often $\alpha ^{(2)}$ is given the symbol $\beta$ and $\alpha ^{(3)}$ is given the symbol $\gamma$ . However, care is needed because some authors^[6] take out the factor $\varepsilon _{0}$ from $\alpha ^{(n)}$ , so that $\mathbf {p} =\varepsilon _{0}\sum _{n}\alpha ^{(n)}\mathbf {E} ^{n}$ and hence $\alpha ^{(n)}=\chi ^{(n)}/\rho$ , which is convenient because then the (hyper-)polarizability may be accurately called the (nonlinear-)susceptibility per molecule, but at the same time inconvenient because of the inconsistency with the usual linear polarisability definition above.