Orientation XYZ

Symmetry Operations

In the D2h Point Group, with orientation XYZ there are the following symmetry operations

Operator	Orientation
$\text{E}$	$\{0,0,0\}$ ,
$C_2$	$\{0,0,1\}$ ,
$C_2$	$\{0,1,0\}$ ,
$C_2$	$\{1,0,0\}$ ,
$\text{i}$	$\{0,0,0\}$ ,
$\sigma _h$	$\{0,0,1\}$ ,
$\sigma _h$	$\{0,1,0\}$ ,
$\sigma _h$	$\{1,0,0\}$ ,

Different Settings

Point Group D2h with orientation XYZ

Character Table

$ $	$ \text{E} \,{\text{(1)}} $	$ C_2 \,{\text{(1)}} $	$ C_2 \,{\text{(1)}} $	$ C_2 \,{\text{(1)}} $	$ \text{i} \,{\text{(1)}} $	$ \sigma_h \,{\text{(1)}} $	$ \sigma_h \,{\text{(1)}} $	$ \sigma_h \,{\text{(1)}} $
$ A_g $	$ 1 $	$ 1 $	$ 1 $	$ 1 $	$ 1 $	$ 1 $	$ 1 $	$ 1 $
$ B_{1g} $	$ 1 $	$ 1 $	$ -1 $	$ -1 $	$ 1 $	$ 1 $	$ -1 $	$ -1 $
$ B_{2g} $	$ 1 $	$ -1 $	$ 1 $	$ -1 $	$ 1 $	$ -1 $	$ 1 $	$ -1 $
$ B_{3g} $	$ 1 $	$ -1 $	$ -1 $	$ 1 $	$ 1 $	$ -1 $	$ -1 $	$ 1 $
$ A_u $	$ 1 $	$ 1 $	$ 1 $	$ 1 $	$ -1 $	$ -1 $	$ -1 $	$ -1 $
$ B_{1u} $	$ 1 $	$ 1 $	$ -1 $	$ -1 $	$ -1 $	$ -1 $	$ 1 $	$ 1 $
$ B_{2u} $	$ 1 $	$ -1 $	$ 1 $	$ -1 $	$ -1 $	$ 1 $	$ -1 $	$ 1 $
$ B_{3u} $	$ 1 $	$ -1 $	$ -1 $	$ 1 $	$ -1 $	$ 1 $	$ 1 $	$ -1 $

Product Table

$ $	$ A_g $	$ B_{1g} $	$ B_{2g} $	$ B_{3g} $	$ A_u $	$ B_{1u} $	$ B_{2u} $	$ B_{3u} $
$ A_g $	$ A_g $	$ B_{1g} $	$ B_{2g} $	$ B_{3g} $	$ A_u $	$ B_{1u} $	$ B_{2u} $	$ B_{3u} $
$ B_{1g} $	$ B_{1g} $	$ A_g $	$ B_{3g} $	$ B_{2g} $	$ B_{1u} $	$ A_u $	$ B_{3u} $	$ B_{2u} $
$ B_{2g} $	$ B_{2g} $	$ B_{3g} $	$ A_g $	$ B_{1g} $	$ B_{2u} $	$ B_{3u} $	$ A_u $	$ B_{1u} $
$ B_{3g} $	$ B_{3g} $	$ B_{2g} $	$ B_{1g} $	$ A_g $	$ B_{3u} $	$ B_{2u} $	$ B_{1u} $	$ A_u $
$ A_u $	$ A_u $	$ B_{1u} $	$ B_{2u} $	$ B_{3u} $	$ A_g $	$ B_{1g} $	$ B_{2g} $	$ B_{3g} $
$ B_{1u} $	$ B_{1u} $	$ A_u $	$ B_{3u} $	$ B_{2u} $	$ B_{1g} $	$ A_g $	$ B_{3g} $	$ B_{2g} $
$ B_{2u} $	$ B_{2u} $	$ B_{3u} $	$ A_u $	$ B_{1u} $	$ B_{2g} $	$ B_{3g} $	$ A_g $	$ B_{1g} $
$ B_{3u} $	$ B_{3u} $	$ B_{2u} $	$ B_{1u} $	$ A_u $	$ B_{3g} $	$ B_{2g} $	$ B_{1g} $	$ A_g $

Sub Groups with compatible settings

Super Groups with compatible settings

Invariant Potential expanded on renormalized spherical Harmonics

Any potential (function) can be written as a sum over spherical harmonics. $$V(r,\theta,\phi) = \sum_{k=0}^{\infty} \sum_{m=-k}^{k} A_{k,m}(r) C^{(m)}_k(\theta,\phi)$$ Here $A_{k,m}(r)$ is a radial function and $C^{(m)}_k(\theta,\phi)$ a renormalised spherical harmonics. $$C^{(m)}_k(\theta,\phi)=\sqrt{\frac{4\pi}{2k+1}}Y^{(m)}_k(\theta,\phi)$$ The presence of symmetry induces relations between the expansion coefficients such that $V(r,\theta,\phi)$ is invariant under all symmetry operations. For the D2h Point group with orientation XYZ the form of the expansion coefficients is:

Expansion

$$A_{k,m} = \begin{cases} A(0,0) & k=0\land m=0 \\ A(2,2) & k=2\land (m=-2\lor m=2) \\ A(2,0) & k=2\land m=0 \\ A(4,4) & k=4\land (m=-4\lor m=4) \\ A(4,2) & k=4\land (m=-2\lor m=2) \\ A(4,0) & k=4\land m=0 \\ A(6,6) & k=6\land (m=-6\lor m=6) \\ A(6,4) & k=6\land (m=-4\lor m=4) \\ A(6,2) & k=6\land (m=-2\lor m=2) \\ A(6,0) & k=6\land m=0 \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{A[0, 0], k == 0 && m == 0}, {A[2, 2], k == 2 && (m == -2 || m == 2)}, {A[2, 0], k == 2 && m == 0}, {A[4, 4], k == 4 && (m == -4 || m == 4)}, {A[4, 2], k == 4 && (m == -2 || m == 2)}, {A[4, 0], k == 4 && m == 0}, {A[6, 6], k == 6 && (m == -6 || m == 6)}, {A[6, 4], k == 6 && (m == -4 || m == 4)}, {A[6, 2], k == 6 && (m == -2 || m == 2)}, {A[6, 0], k == 6 && m == 0}}, 0]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{0, 0, A(0,0)} , 
       {2, 0, A(2,0)} , 
       {2,-2, A(2,2)} , 
       {2, 2, A(2,2)} , 
       {4, 0, A(4,0)} , 
       {4,-2, A(4,2)} , 
       {4, 2, A(4,2)} , 
       {4,-4, A(4,4)} , 
       {4, 4, A(4,4)} , 
       {6, 0, A(6,0)} , 
       {6,-2, A(6,2)} , 
       {6, 2, A(6,2)} , 
       {6,-4, A(6,4)} , 
       {6, 4, A(6,4)} , 
       {6,-6, A(6,6)} , 
       {6, 6, A(6,6)} }

One particle coupling on a basis of spherical harmonics

The operator representing the potential in second quantisation is given as: $$ O = \sum_{n'',l'',m'',n',l',m'} \left\langle \psi_{n'',l'',m''}(r,\theta,\phi) \left| V(r,\theta,\phi) \right| \psi_{n',l',m'}(r,\theta,\phi) \right\rangle a^{\dagger}_{n'',l'',m''}a^{\phantom{\dagger}}_{n',l',m'}$$ For the quantisation of the wave-function (physical meaning of the indices n,l,m) we can choose a basis of spherical harmonics times some radial function, i.e. $\psi_{n,l,m}(r,\theta,\phi)=R_{n,l}(r)Y_{m}^{(l)}(\theta,\phi)$. With this choice the integral for the expectation value in front of the creation and annihilation operators separates into a radial part and angular part. The angular part has an analytical solution, the radial integral is cast int a parameter. $$ A_{n''l'',n'l'}(k,m) = \left\langle R_{n'',l''} \left| A_{k,m}(r) \right| R_{n',l'} \right\rangle $$ Note the difference between the function $A_{k,m}$ and the parameter $A_{n''l'',n'l'}(k,m)$

we can express the operator as $$ O = \sum_{n'',l'',m'',n',l',m',k,m} A_{n''l'',n'l'}(k,m) \left\langle Y_{l''}^{(m'')}(\theta,\phi) \left| C_{k}^{(m)}(\theta,\phi) \right| Y_{l'}^{(m')}(\theta,\phi) \right\rangle a^{\dagger}_{n'',l'',m''}a^{\phantom{\dagger}}_{n',l',m'}$$

The table below shows the expectation value of $O$ on a basis of spherical harmonics. We suppressed the principle quantum number indices. Note that in principle $A_{l'',l'}(k,m)$ can be complex. Instead of allowing complex parameters we took $A_{l'',l'}(k,m) + \mathrm{I}\, B_{l'',l'}(k,m)$ (with both A and B real) as the expansion parameter.

$ $	$ {Y_{0}^{(0)}} $	$ {Y_{-1}^{(1)}} $	$ {Y_{0}^{(1)}} $	$ {Y_{1}^{(1)}} $	$ {Y_{-2}^{(2)}} $	$ {Y_{-1}^{(2)}} $	$ {Y_{0}^{(2)}} $	$ {Y_{1}^{(2)}} $	$ {Y_{2}^{(2)}} $	$ {Y_{-3}^{(3)}} $	$ {Y_{-2}^{(3)}} $	$ {Y_{-1}^{(3)}} $	$ {Y_{0}^{(3)}} $	$ {Y_{1}^{(3)}} $	$ {Y_{2}^{(3)}} $	$ {Y_{3}^{(3)}} $
$ {Y_{0}^{(0)}} $	$ \text{Ass}(0,0) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{\text{Asd}(2,2)}{\sqrt{5}} $	$ 0 $	$ \frac{\text{Asd}(2,0)}{\sqrt{5}} $	$ 0 $	$ \frac{\text{Asd}(2,2)}{\sqrt{5}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ {Y_{-1}^{(1)}} $	$\color{darkred}{ 0 }$	$ \text{App}(0,0)-\frac{1}{5} \text{App}(2,0) $	$ 0 $	$ -\frac{1}{5} \sqrt{6} \text{App}(2,2) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{3 \text{Apf}(2,2)}{\sqrt{35}}-\frac{\text{Apf}(4,2)}{3 \sqrt{21}} $	$ 0 $	$ \frac{3}{5} \sqrt{\frac{2}{7}} \text{Apf}(2,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,0) $	$ 0 $	$ \frac{1}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,2)-\frac{1}{3} \sqrt{\frac{5}{7}} \text{Apf}(4,2) $	$ 0 $	$ -\frac{2 \text{Apf}(4,4)}{3 \sqrt{3}} $
$ {Y_{0}^{(1)}} $	$\color{darkred}{ 0 }$	$ 0 $	$ \text{App}(0,0)+\frac{2}{5} \text{App}(2,0) $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \sqrt{\frac{3}{35}} \text{Apf}(2,2)+\frac{2 \text{Apf}(4,2)}{3 \sqrt{7}} $	$ 0 $	$ \frac{3}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,0)+\frac{4 \text{Apf}(4,0)}{3 \sqrt{21}} $	$ 0 $	$ \sqrt{\frac{3}{35}} \text{Apf}(2,2)+\frac{2 \text{Apf}(4,2)}{3 \sqrt{7}} $	$ 0 $
$ {Y_{1}^{(1)}} $	$\color{darkred}{ 0 }$	$ -\frac{1}{5} \sqrt{6} \text{App}(2,2) $	$ 0 $	$ \text{App}(0,0)-\frac{1}{5} \text{App}(2,0) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ -\frac{2 \text{Apf}(4,4)}{3 \sqrt{3}} $	$ 0 $	$ \frac{1}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,2)-\frac{1}{3} \sqrt{\frac{5}{7}} \text{Apf}(4,2) $	$ 0 $	$ \frac{3}{5} \sqrt{\frac{2}{7}} \text{Apf}(2,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,0) $	$ 0 $	$ \frac{3 \text{Apf}(2,2)}{\sqrt{35}}-\frac{\text{Apf}(4,2)}{3 \sqrt{21}} $
$ {Y_{-2}^{(2)}} $	$ \frac{\text{Asd}(2,2)}{\sqrt{5}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \text{Add}(0,0)-\frac{2}{7} \text{Add}(2,0)+\frac{1}{21} \text{Add}(4,0) $	$ 0 $	$ \frac{1}{7} \sqrt{\frac{5}{3}} \text{Add}(4,2)-\frac{2}{7} \text{Add}(2,2) $	$ 0 $	$ \frac{1}{3} \sqrt{\frac{10}{7}} \text{Add}(4,4) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ {Y_{-1}^{(2)}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \text{Add}(0,0)+\frac{1}{7} \text{Add}(2,0)-\frac{4}{21} \text{Add}(4,0) $	$ 0 $	$ -\frac{1}{7} \sqrt{6} \text{Add}(2,2)-\frac{2}{21} \sqrt{10} \text{Add}(4,2) $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ {Y_{0}^{(2)}} $	$ \frac{\text{Asd}(2,0)}{\sqrt{5}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{1}{7} \sqrt{\frac{5}{3}} \text{Add}(4,2)-\frac{2}{7} \text{Add}(2,2) $	$ 0 $	$ \text{Add}(0,0)+\frac{2}{7} \text{Add}(2,0)+\frac{2}{7} \text{Add}(4,0) $	$ 0 $	$ \frac{1}{7} \sqrt{\frac{5}{3}} \text{Add}(4,2)-\frac{2}{7} \text{Add}(2,2) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ {Y_{1}^{(2)}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ -\frac{1}{7} \sqrt{6} \text{Add}(2,2)-\frac{2}{21} \sqrt{10} \text{Add}(4,2) $	$ 0 $	$ \text{Add}(0,0)+\frac{1}{7} \text{Add}(2,0)-\frac{4}{21} \text{Add}(4,0) $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ {Y_{2}^{(2)}} $	$ \frac{\text{Asd}(2,2)}{\sqrt{5}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{1}{3} \sqrt{\frac{10}{7}} \text{Add}(4,4) $	$ 0 $	$ \frac{1}{7} \sqrt{\frac{5}{3}} \text{Add}(4,2)-\frac{2}{7} \text{Add}(2,2) $	$ 0 $	$ \text{Add}(0,0)-\frac{2}{7} \text{Add}(2,0)+\frac{1}{21} \text{Add}(4,0) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ {Y_{-3}^{(3)}} $	$\color{darkred}{ 0 }$	$ \frac{3 \text{Apf}(2,2)}{\sqrt{35}}-\frac{\text{Apf}(4,2)}{3 \sqrt{21}} $	$ 0 $	$ -\frac{2 \text{Apf}(4,4)}{3 \sqrt{3}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \text{Aff}(0,0)-\frac{1}{3} \text{Aff}(2,0)+\frac{1}{11} \text{Aff}(4,0)-\frac{5}{429} \text{Aff}(6,0) $	$ 0 $	$ -\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)+\frac{1}{11} \sqrt{6} \text{Aff}(4,2)-\frac{10}{429} \sqrt{7} \text{Aff}(6,2) $	$ 0 $	$ \frac{1}{11} \sqrt{\frac{14}{3}} \text{Aff}(4,4)-\frac{5}{143} \sqrt{\frac{70}{3}} \text{Aff}(6,4) $	$ 0 $	$ -\frac{10}{13} \sqrt{\frac{7}{33}} \text{Aff}(6,6) $
$ {Y_{-2}^{(3)}} $	$\color{darkred}{ 0 }$	$ 0 $	$ \sqrt{\frac{3}{35}} \text{Apf}(2,2)+\frac{2 \text{Apf}(4,2)}{3 \sqrt{7}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \text{Aff}(0,0)-\frac{7}{33} \text{Aff}(4,0)+\frac{10}{143} \text{Aff}(6,0) $	$ 0 $	$ -\frac{2 \text{Aff}(2,2)}{3 \sqrt{5}}-\frac{\text{Aff}(4,2)}{11 \sqrt{3}}+\frac{20}{429} \sqrt{14} \text{Aff}(6,2) $	$ 0 $	$ \frac{1}{33} \sqrt{70} \text{Aff}(4,4)+\frac{10}{143} \sqrt{14} \text{Aff}(6,4) $	$ 0 $
$ {Y_{-1}^{(3)}} $	$\color{darkred}{ 0 }$	$ \frac{3}{5} \sqrt{\frac{2}{7}} \text{Apf}(2,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,0) $	$ 0 $	$ \frac{1}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,2)-\frac{1}{3} \sqrt{\frac{5}{7}} \text{Apf}(4,2) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ -\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)+\frac{1}{11} \sqrt{6} \text{Aff}(4,2)-\frac{10}{429} \sqrt{7} \text{Aff}(6,2) $	$ 0 $	$ \text{Aff}(0,0)+\frac{1}{5} \text{Aff}(2,0)+\frac{1}{33} \text{Aff}(4,0)-\frac{25}{143} \text{Aff}(6,0) $	$ 0 $	$ -\frac{2}{5} \sqrt{\frac{2}{3}} \text{Aff}(2,2)-\frac{2}{33} \sqrt{10} \text{Aff}(4,2)-\frac{10}{143} \sqrt{\frac{35}{3}} \text{Aff}(6,2) $	$ 0 $	$ \frac{1}{11} \sqrt{\frac{14}{3}} \text{Aff}(4,4)-\frac{5}{143} \sqrt{\frac{70}{3}} \text{Aff}(6,4) $
$ {Y_{0}^{(3)}} $	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{3}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,0)+\frac{4 \text{Apf}(4,0)}{3 \sqrt{21}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ -\frac{2 \text{Aff}(2,2)}{3 \sqrt{5}}-\frac{\text{Aff}(4,2)}{11 \sqrt{3}}+\frac{20}{429} \sqrt{14} \text{Aff}(6,2) $	$ 0 $	$ \text{Aff}(0,0)+\frac{4}{15} \text{Aff}(2,0)+\frac{2}{11} \text{Aff}(4,0)+\frac{100}{429} \text{Aff}(6,0) $	$ 0 $	$ -\frac{2 \text{Aff}(2,2)}{3 \sqrt{5}}-\frac{\text{Aff}(4,2)}{11 \sqrt{3}}+\frac{20}{429} \sqrt{14} \text{Aff}(6,2) $	$ 0 $
$ {Y_{1}^{(3)}} $	$\color{darkred}{ 0 }$	$ \frac{1}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,2)-\frac{1}{3} \sqrt{\frac{5}{7}} \text{Apf}(4,2) $	$ 0 $	$ \frac{3}{5} \sqrt{\frac{2}{7}} \text{Apf}(2,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,0) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{1}{11} \sqrt{\frac{14}{3}} \text{Aff}(4,4)-\frac{5}{143} \sqrt{\frac{70}{3}} \text{Aff}(6,4) $	$ 0 $	$ -\frac{2}{5} \sqrt{\frac{2}{3}} \text{Aff}(2,2)-\frac{2}{33} \sqrt{10} \text{Aff}(4,2)-\frac{10}{143} \sqrt{\frac{35}{3}} \text{Aff}(6,2) $	$ 0 $	$ \text{Aff}(0,0)+\frac{1}{5} \text{Aff}(2,0)+\frac{1}{33} \text{Aff}(4,0)-\frac{25}{143} \text{Aff}(6,0) $	$ 0 $	$ -\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)+\frac{1}{11} \sqrt{6} \text{Aff}(4,2)-\frac{10}{429} \sqrt{7} \text{Aff}(6,2) $
$ {Y_{2}^{(3)}} $	$\color{darkred}{ 0 }$	$ 0 $	$ \sqrt{\frac{3}{35}} \text{Apf}(2,2)+\frac{2 \text{Apf}(4,2)}{3 \sqrt{7}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{1}{33} \sqrt{70} \text{Aff}(4,4)+\frac{10}{143} \sqrt{14} \text{Aff}(6,4) $	$ 0 $	$ -\frac{2 \text{Aff}(2,2)}{3 \sqrt{5}}-\frac{\text{Aff}(4,2)}{11 \sqrt{3}}+\frac{20}{429} \sqrt{14} \text{Aff}(6,2) $	$ 0 $	$ \text{Aff}(0,0)-\frac{7}{33} \text{Aff}(4,0)+\frac{10}{143} \text{Aff}(6,0) $	$ 0 $
$ {Y_{3}^{(3)}} $	$\color{darkred}{ 0 }$	$ -\frac{2 \text{Apf}(4,4)}{3 \sqrt{3}} $	$ 0 $	$ \frac{3 \text{Apf}(2,2)}{\sqrt{35}}-\frac{\text{Apf}(4,2)}{3 \sqrt{21}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ -\frac{10}{13} \sqrt{\frac{7}{33}} \text{Aff}(6,6) $	$ 0 $	$ \frac{1}{11} \sqrt{\frac{14}{3}} \text{Aff}(4,4)-\frac{5}{143} \sqrt{\frac{70}{3}} \text{Aff}(6,4) $	$ 0 $	$ -\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)+\frac{1}{11} \sqrt{6} \text{Aff}(4,2)-\frac{10}{429} \sqrt{7} \text{Aff}(6,2) $	$ 0 $	$ \text{Aff}(0,0)-\frac{1}{3} \text{Aff}(2,0)+\frac{1}{11} \text{Aff}(4,0)-\frac{5}{429} \text{Aff}(6,0) $

Rotation matrix to symmetry adapted functions (choice is not unique)

Instead of a basis of spherical harmonics one can chose any other basis, which is given by a unitary transformation. Here we choose a rotation that simplifies the representation of the crystal field

$ $	$ {Y_{0}^{(0)}} $	$ {Y_{-1}^{(1)}} $	$ {Y_{0}^{(1)}} $	$ {Y_{1}^{(1)}} $	$ {Y_{-2}^{(2)}} $	$ {Y_{-1}^{(2)}} $	$ {Y_{0}^{(2)}} $	$ {Y_{1}^{(2)}} $	$ {Y_{2}^{(2)}} $	$ {Y_{-3}^{(3)}} $	$ {Y_{-2}^{(3)}} $	$ {Y_{-1}^{(3)}} $	$ {Y_{0}^{(3)}} $	$ {Y_{1}^{(3)}} $	$ {Y_{2}^{(3)}} $	$ {Y_{3}^{(3)}} $
$ \text{s} $	$ 1 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ p_x $	$\color{darkred}{ 0 }$	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ -\frac{1}{\sqrt{2}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $
$ p_y $	$\color{darkred}{ 0 }$	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ \frac{i}{\sqrt{2}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $
$ p_z $	$\color{darkred}{ 0 }$	$ 0 $	$ 1 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $
$ d_{x^2-y^2} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ \frac{1}{\sqrt{2}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{3z^2-r^2} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 1 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{\text{yz}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{\text{xz}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ -\frac{1}{\sqrt{2}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{\text{xy}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ -\frac{i}{\sqrt{2}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ f_{\text{xyz}} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ -\frac{i}{\sqrt{2}} $	$ 0 $
$ f_{x\left(5x^2-r^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{\sqrt{5}}{4} $	$ 0 $	$ -\frac{\sqrt{3}}{4} $	$ 0 $	$ \frac{\sqrt{3}}{4} $	$ 0 $	$ -\frac{\sqrt{5}}{4} $
$ f_{y\left(5y^2-r^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ -\frac{i \sqrt{5}}{4} $	$ 0 $	$ -\frac{i \sqrt{3}}{4} $	$ 0 $	$ -\frac{i \sqrt{3}}{4} $	$ 0 $	$ -\frac{i \sqrt{5}}{4} $
$ f_{z\left(5z^2-r^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ 1 $	$ 0 $	$ 0 $	$ 0 $
$ f_{x\left(y^2-z^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ -\frac{\sqrt{3}}{4} $	$ 0 $	$ -\frac{\sqrt{5}}{4} $	$ 0 $	$ \frac{\sqrt{5}}{4} $	$ 0 $	$ \frac{\sqrt{3}}{4} $
$ f_{y\left(z^2-x^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ -\frac{i \sqrt{3}}{4} $	$ 0 $	$ \frac{i \sqrt{5}}{4} $	$ 0 $	$ \frac{i \sqrt{5}}{4} $	$ 0 $	$ -\frac{i \sqrt{3}}{4} $
$ f_{z\left(x^2-y^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ \frac{1}{\sqrt{2}} $	$ 0 $

One particle coupling on a basis of symmetry adapted functions

After rotation we find

$ $	$ \text{s} $	$ p_x $	$ p_y $	$ p_z $	$ d_{x^2-y^2} $	$ d_{3z^2-r^2} $	$ d_{\text{yz}} $	$ d_{\text{xz}} $	$ d_{\text{xy}} $	$ f_{\text{xyz}} $	$ f_{x\left(5x^2-r^2\right)} $	$ f_{y\left(5y^2-r^2\right)} $	$ f_{z\left(5z^2-r^2\right)} $	$ f_{x\left(y^2-z^2\right)} $	$ f_{y\left(z^2-x^2\right)} $	$ f_{z\left(x^2-y^2\right)} $
$ \text{s} $	$ \text{Ass}(0,0) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \sqrt{\frac{2}{5}} \text{Asd}(2,2) $	$ \frac{\text{Asd}(2,0)}{\sqrt{5}} $	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ p_x $	$\color{darkred}{ 0 }$	$ \text{App}(0,0)-\frac{1}{5} \text{App}(2,0)+\frac{1}{5} \sqrt{6} \text{App}(2,2) $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ -\frac{3}{10} \sqrt{\frac{3}{7}} \text{Apf}(2,0)+\frac{9 \text{Apf}(2,2)}{5 \sqrt{14}}+\frac{\text{Apf}(4,0)}{2 \sqrt{21}}-\frac{1}{3} \sqrt{\frac{10}{21}} \text{Apf}(4,2)+\frac{1}{3} \sqrt{\frac{5}{6}} \text{Apf}(4,4) $	$ 0 $	$ 0 $	$ -\frac{3 \text{Apf}(2,0)}{2 \sqrt{35}}-\sqrt{\frac{3}{70}} \text{Apf}(2,2)+\frac{1}{6} \sqrt{\frac{5}{7}} \text{Apf}(4,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,2)-\frac{\text{Apf}(4,4)}{3 \sqrt{2}} $	$ 0 $	$ 0 $
$ p_y $	$\color{darkred}{ 0 }$	$ 0 $	$ \text{App}(0,0)-\frac{1}{5} \text{App}(2,0)-\frac{1}{5} \sqrt{6} \text{App}(2,2) $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ -\frac{3}{10} \sqrt{\frac{3}{7}} \text{Apf}(2,0)-\frac{9 \text{Apf}(2,2)}{5 \sqrt{14}}+\frac{\text{Apf}(4,0)}{2 \sqrt{21}}+\frac{1}{3} \sqrt{\frac{10}{21}} \text{Apf}(4,2)+\frac{1}{3} \sqrt{\frac{5}{6}} \text{Apf}(4,4) $	$ 0 $	$ 0 $	$ \frac{3 \text{Apf}(2,0)}{2 \sqrt{35}}-\sqrt{\frac{3}{70}} \text{Apf}(2,2)-\frac{1}{6} \sqrt{\frac{5}{7}} \text{Apf}(4,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,2)+\frac{\text{Apf}(4,4)}{3 \sqrt{2}} $	$ 0 $
$ p_z $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ \text{App}(0,0)+\frac{2}{5} \text{App}(2,0) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ \frac{3}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,0)+\frac{4 \text{Apf}(4,0)}{3 \sqrt{21}} $	$ 0 $	$ 0 $	$ \sqrt{\frac{6}{35}} \text{Apf}(2,2)+\frac{2}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,2) $
$ d_{x^2-y^2} $	$ \sqrt{\frac{2}{5}} \text{Asd}(2,2) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \text{Add}(0,0)-\frac{2}{7} \text{Add}(2,0)+\frac{1}{21} \text{Add}(4,0)+\frac{1}{3} \sqrt{\frac{10}{7}} \text{Add}(4,4) $	$ \frac{1}{7} \sqrt{\frac{10}{3}} \text{Add}(4,2)-\frac{2}{7} \sqrt{2} \text{Add}(2,2) $	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{3z^2-r^2} $	$ \frac{\text{Asd}(2,0)}{\sqrt{5}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \frac{1}{7} \sqrt{\frac{10}{3}} \text{Add}(4,2)-\frac{2}{7} \sqrt{2} \text{Add}(2,2) $	$ \text{Add}(0,0)+\frac{2}{7} \text{Add}(2,0)+\frac{2}{7} \text{Add}(4,0) $	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{\text{yz}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ \text{Add}(0,0)+\frac{1}{7} \text{Add}(2,0)-\frac{1}{7} \sqrt{6} \text{Add}(2,2)-\frac{4}{21} \text{Add}(4,0)-\frac{2}{21} \sqrt{10} \text{Add}(4,2) $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{\text{xz}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ \text{Add}(0,0)+\frac{1}{7} \text{Add}(2,0)+\frac{1}{7} \sqrt{6} \text{Add}(2,2)-\frac{4}{21} \text{Add}(4,0)+\frac{2}{21} \sqrt{10} \text{Add}(4,2) $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ d_{\text{xy}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ \text{Add}(0,0)-\frac{2}{7} \text{Add}(2,0)+\frac{1}{21} \text{Add}(4,0)-\frac{1}{3} \sqrt{\frac{10}{7}} \text{Add}(4,4) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$
$ f_{\text{xyz}} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ \text{Aff}(0,0)-\frac{7}{33} \text{Aff}(4,0)-\frac{1}{33} \sqrt{70} \text{Aff}(4,4)+\frac{10}{143} \text{Aff}(6,0)-\frac{10}{143} \sqrt{14} \text{Aff}(6,4) $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $
$ f_{x\left(5x^2-r^2\right)} $	$\color{darkred}{ 0 }$	$ -\frac{3}{10} \sqrt{\frac{3}{7}} \text{Apf}(2,0)+\frac{9 \text{Apf}(2,2)}{5 \sqrt{14}}+\frac{\text{Apf}(4,0)}{2 \sqrt{21}}-\frac{1}{3} \sqrt{\frac{10}{21}} \text{Apf}(4,2)+\frac{1}{3} \sqrt{\frac{5}{6}} \text{Apf}(4,4) $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \text{Aff}(0,0)-\frac{2}{15} \text{Aff}(2,0)+\frac{2}{5} \sqrt{\frac{2}{3}} \text{Aff}(2,2)+\frac{3}{44} \text{Aff}(4,0)-\frac{1}{11} \sqrt{\frac{5}{2}} \text{Aff}(4,2)+\frac{1}{22} \sqrt{\frac{35}{2}} \text{Aff}(4,4)-\frac{125 \text{Aff}(6,0)}{1716}+\frac{25}{572} \sqrt{\frac{35}{3}} \text{Aff}(6,2)-\frac{25}{286} \sqrt{\frac{7}{2}} \text{Aff}(6,4)+\frac{25}{52} \sqrt{\frac{7}{33}} \text{Aff}(6,6) $	$ 0 $	$ 0 $	$ \frac{\text{Aff}(2,0)}{\sqrt{15}}+\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)-\frac{1}{44} \sqrt{\frac{5}{3}} \text{Aff}(4,0)+\frac{\text{Aff}(4,2)}{11 \sqrt{6}}+\frac{1}{22} \sqrt{\frac{7}{6}} \text{Aff}(4,4)-\frac{35}{572} \sqrt{\frac{5}{3}} \text{Aff}(6,0)+\frac{85 \sqrt{7} \text{Aff}(6,2)}{1716}-\frac{5}{286} \sqrt{\frac{35}{6}} \text{Aff}(6,4)-\frac{5}{52} \sqrt{\frac{35}{11}} \text{Aff}(6,6) $	$ 0 $	$ 0 $
$ f_{y\left(5y^2-r^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ -\frac{3}{10} \sqrt{\frac{3}{7}} \text{Apf}(2,0)-\frac{9 \text{Apf}(2,2)}{5 \sqrt{14}}+\frac{\text{Apf}(4,0)}{2 \sqrt{21}}+\frac{1}{3} \sqrt{\frac{10}{21}} \text{Apf}(4,2)+\frac{1}{3} \sqrt{\frac{5}{6}} \text{Apf}(4,4) $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ \text{Aff}(0,0)-\frac{2}{15} \text{Aff}(2,0)-\frac{2}{5} \sqrt{\frac{2}{3}} \text{Aff}(2,2)+\frac{3}{44} \text{Aff}(4,0)+\frac{1}{11} \sqrt{\frac{5}{2}} \text{Aff}(4,2)+\frac{1}{22} \sqrt{\frac{35}{2}} \text{Aff}(4,4)-\frac{125 \text{Aff}(6,0)}{1716}-\frac{25}{572} \sqrt{\frac{35}{3}} \text{Aff}(6,2)-\frac{25}{286} \sqrt{\frac{7}{2}} \text{Aff}(6,4)-\frac{25}{52} \sqrt{\frac{7}{33}} \text{Aff}(6,6) $	$ 0 $	$ 0 $	$ -\frac{\text{Aff}(2,0)}{\sqrt{15}}+\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)+\frac{1}{44} \sqrt{\frac{5}{3}} \text{Aff}(4,0)+\frac{\text{Aff}(4,2)}{11 \sqrt{6}}-\frac{1}{22} \sqrt{\frac{7}{6}} \text{Aff}(4,4)+\frac{35}{572} \sqrt{\frac{5}{3}} \text{Aff}(6,0)+\frac{85 \sqrt{7} \text{Aff}(6,2)}{1716}+\frac{5}{286} \sqrt{\frac{35}{6}} \text{Aff}(6,4)-\frac{5}{52} \sqrt{\frac{35}{11}} \text{Aff}(6,6) $	$ 0 $
$ f_{z\left(5z^2-r^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ \frac{3}{5} \sqrt{\frac{3}{7}} \text{Apf}(2,0)+\frac{4 \text{Apf}(4,0)}{3 \sqrt{21}} $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ \text{Aff}(0,0)+\frac{4}{15} \text{Aff}(2,0)+\frac{2}{11} \text{Aff}(4,0)+\frac{100}{429} \text{Aff}(6,0) $	$ 0 $	$ 0 $	$ -\frac{2}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)-\frac{1}{11} \sqrt{\frac{2}{3}} \text{Aff}(4,2)+\frac{40}{429} \sqrt{7} \text{Aff}(6,2) $
$ f_{x\left(y^2-z^2\right)} $	$\color{darkred}{ 0 }$	$ -\frac{3 \text{Apf}(2,0)}{2 \sqrt{35}}-\sqrt{\frac{3}{70}} \text{Apf}(2,2)+\frac{1}{6} \sqrt{\frac{5}{7}} \text{Apf}(4,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,2)-\frac{\text{Apf}(4,4)}{3 \sqrt{2}} $	$ 0 $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{\text{Aff}(2,0)}{\sqrt{15}}+\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)-\frac{1}{44} \sqrt{\frac{5}{3}} \text{Aff}(4,0)+\frac{\text{Aff}(4,2)}{11 \sqrt{6}}+\frac{1}{22} \sqrt{\frac{7}{6}} \text{Aff}(4,4)-\frac{35}{572} \sqrt{\frac{5}{3}} \text{Aff}(6,0)+\frac{85 \sqrt{7} \text{Aff}(6,2)}{1716}-\frac{5}{286} \sqrt{\frac{35}{6}} \text{Aff}(6,4)-\frac{5}{52} \sqrt{\frac{35}{11}} \text{Aff}(6,6) $	$ 0 $	$ 0 $	$ \text{Aff}(0,0)+\frac{7}{132} \text{Aff}(4,0)+\frac{7}{33} \sqrt{\frac{5}{2}} \text{Aff}(4,2)-\frac{1}{22} \sqrt{\frac{35}{2}} \text{Aff}(4,4)-\frac{5}{44} \text{Aff}(6,0)+\frac{5}{572} \sqrt{105} \text{Aff}(6,2)+\frac{25}{286} \sqrt{\frac{7}{2}} \text{Aff}(6,4)+\frac{5}{52} \sqrt{\frac{21}{11}} \text{Aff}(6,6) $	$ 0 $	$ 0 $
$ f_{y\left(z^2-x^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ \frac{3 \text{Apf}(2,0)}{2 \sqrt{35}}-\sqrt{\frac{3}{70}} \text{Apf}(2,2)-\frac{1}{6} \sqrt{\frac{5}{7}} \text{Apf}(4,0)-\frac{1}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,2)+\frac{\text{Apf}(4,4)}{3 \sqrt{2}} $	$ 0 $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ -\frac{\text{Aff}(2,0)}{\sqrt{15}}+\frac{1}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)+\frac{1}{44} \sqrt{\frac{5}{3}} \text{Aff}(4,0)+\frac{\text{Aff}(4,2)}{11 \sqrt{6}}-\frac{1}{22} \sqrt{\frac{7}{6}} \text{Aff}(4,4)+\frac{35}{572} \sqrt{\frac{5}{3}} \text{Aff}(6,0)+\frac{85 \sqrt{7} \text{Aff}(6,2)}{1716}+\frac{5}{286} \sqrt{\frac{35}{6}} \text{Aff}(6,4)-\frac{5}{52} \sqrt{\frac{35}{11}} \text{Aff}(6,6) $	$ 0 $	$ 0 $	$ \text{Aff}(0,0)+\frac{7}{132} \text{Aff}(4,0)-\frac{7}{33} \sqrt{\frac{5}{2}} \text{Aff}(4,2)-\frac{1}{22} \sqrt{\frac{35}{2}} \text{Aff}(4,4)-\frac{5}{44} \text{Aff}(6,0)-\frac{5}{572} \sqrt{105} \text{Aff}(6,2)+\frac{25}{286} \sqrt{\frac{7}{2}} \text{Aff}(6,4)-\frac{5}{52} \sqrt{\frac{21}{11}} \text{Aff}(6,6) $	$ 0 $
$ f_{z\left(x^2-y^2\right)} $	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ \sqrt{\frac{6}{35}} \text{Apf}(2,2)+\frac{2}{3} \sqrt{\frac{2}{7}} \text{Apf}(4,2) $	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$\color{darkred}{ 0 }$	$ 0 $	$ 0 $	$ 0 $	$ -\frac{2}{3} \sqrt{\frac{2}{5}} \text{Aff}(2,2)-\frac{1}{11} \sqrt{\frac{2}{3}} \text{Aff}(4,2)+\frac{40}{429} \sqrt{7} \text{Aff}(6,2) $	$ 0 $	$ 0 $	$ \text{Aff}(0,0)-\frac{7}{33} \text{Aff}(4,0)+\frac{1}{33} \sqrt{70} \text{Aff}(4,4)+\frac{10}{143} \text{Aff}(6,0)+\frac{10}{143} \sqrt{14} \text{Aff}(6,4) $

Coupling for a single shell

Although the parameters $A_{l'',l'}(k,m)$ uniquely define the potential, there is no simple relation between these paramters and the eigenstates of the potential. In this section we replace the parameters $A_{l'',l'}(k,m)$ by paramters that relate to the eigen energies of the potential acting on or between two shells with angular momentum $l''$ and $l'$.

Click on one of the subsections to expand it or

Potential for s orbitals

Potential parameterized with onsite energies of irriducible representations

$$A_{k,m} = \begin{cases} \text{Ea1g} & k=0\land m=0 \\ 0 & \text{True} \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{Ea1g, k == 0 && m == 0}}, 0]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{0, 0, Ea1g} }

The Hamiltonian on a basis of spherical Harmonics

$ $	$ {Y_{0}^{(0)}} $
$ {Y_{0}^{(0)}} $	$ \text{Ea1g} $

The Hamiltonian on a basis of symmetric functions

$ $	$ \text{s} $
$ \text{s} $	$ \text{Ea1g} $

Rotation matrix used

$ $	$ {Y_{0}^{(0)}} $
$ \text{s} $	$ 1 $

Irriducible representations and their onsite energy

	$$\text{Ea1g}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2 \sqrt{\pi }}$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2 \sqrt{\pi }}$$

Potential for p orbitals

Potential parameterized with onsite energies of irriducible representations

$$A_{k,m} = \begin{cases} \frac{1}{3} (\text{Eb1u}+\text{Eb2u}+\text{Eb3u}) & k=0\land m=0 \\ -\frac{5 (\text{Eb2u}-\text{Eb3u})}{2 \sqrt{6}} & k=2\land (m=-2\lor m=2) \\ \frac{5}{6} (2 \text{Eb1u}-\text{Eb2u}-\text{Eb3u}) & k=2\land m=0 \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{(Eb1u + Eb2u + Eb3u)/3, k == 0 && m == 0}, {(-5*(Eb2u - Eb3u))/(2*Sqrt[6]), k == 2 && (m == -2 || m == 2)}, {(5*(2*Eb1u - Eb2u - Eb3u))/6, k == 2 && m == 0}}, 0]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{0, 0, (1/3)*(Eb1u + Eb2u + Eb3u)} , 
       {2, 0, (5/6)*((2)*(Eb1u) + (-1)*(Eb2u) + (-1)*(Eb3u))} , 
       {2,-2, (-5/2)*((1/(sqrt(6)))*(Eb2u + (-1)*(Eb3u)))} , 
       {2, 2, (-5/2)*((1/(sqrt(6)))*(Eb2u + (-1)*(Eb3u)))} }

The Hamiltonian on a basis of spherical Harmonics

$ $	$ {Y_{-1}^{(1)}} $	$ {Y_{0}^{(1)}} $	$ {Y_{1}^{(1)}} $
$ {Y_{-1}^{(1)}} $	$ \frac{\text{Eb2u}+\text{Eb3u}}{2} $	$ 0 $	$ \frac{\text{Eb2u}-\text{Eb3u}}{2} $
$ {Y_{0}^{(1)}} $	$ 0 $	$ \text{Eb1u} $	$ 0 $
$ {Y_{1}^{(1)}} $	$ \frac{\text{Eb2u}-\text{Eb3u}}{2} $	$ 0 $	$ \frac{\text{Eb2u}+\text{Eb3u}}{2} $

The Hamiltonian on a basis of symmetric functions

$ $	$ p_x $	$ p_y $	$ p_z $
$ p_x $	$ \text{Eb3u} $	$ 0 $	$ 0 $
$ p_y $	$ 0 $	$ \text{Eb2u} $	$ 0 $
$ p_z $	$ 0 $	$ 0 $	$ \text{Eb1u} $

Rotation matrix used

$ $	$ {Y_{-1}^{(1)}} $	$ {Y_{0}^{(1)}} $	$ {Y_{1}^{(1)}} $
$ p_x $	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ -\frac{1}{\sqrt{2}} $
$ p_y $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ \frac{i}{\sqrt{2}} $
$ p_z $	$ 0 $	$ 1 $	$ 0 $

Irriducible representations and their onsite energy

	$$\text{Eb3u}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{3}{\pi }} \sin (\theta ) \cos (\phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{3}{\pi }} x$$
	$$\text{Eb2u}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{3}{\pi }} \sin (\theta ) \sin (\phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{3}{\pi }} y$$
	$$\text{Eb1u}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{3}{\pi }} \cos (\theta )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{3}{\pi }} z$$

Potential for d orbitals

Potential parameterized with onsite energies of irriducible representations

$$A_{k,m} = \begin{cases} \frac{1}{5} (\text{Eagx2y2}+\text{Eagz2}+\text{Eb1g}+\text{Eb2g}+\text{Eb3g}) & k=0\land m=0 \\ \frac{1}{4} \left(\sqrt{6} \text{Eb2g}-\sqrt{6} \text{Eb3g}-4 \sqrt{2} \text{Mag}\right) & k=2\land (m=-2\lor m=2) \\ \frac{1}{2} (-2 \text{Eagx2y2}+2 \text{Eagz2}-2 \text{Eb1g}+\text{Eb2g}+\text{Eb3g}) & k=2\land m=0 \\ \frac{3}{2} \sqrt{\frac{7}{10}} (\text{Eagx2y2}-\text{Eb1g}) & k=4\land (m=-4\lor m=4) \\ \frac{3 \left(\text{Eb2g}-\text{Eb3g}+\sqrt{3} \text{Mag}\right)}{\sqrt{10}} & k=4\land (m=-2\lor m=2) \\ \frac{3}{10} (\text{Eagx2y2}+6 \text{Eagz2}+\text{Eb1g}-4 \text{Eb2g}-4 \text{Eb3g}) & k=4\land m=0 \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{(Eagx2y2 + Eagz2 + Eb1g + Eb2g + Eb3g)/5, k == 0 && m == 0}, {(Sqrt[6]*Eb2g - Sqrt[6]*Eb3g - 4*Sqrt[2]*Mag)/4, k == 2 && (m == -2 || m == 2)}, {(-2*Eagx2y2 + 2*Eagz2 - 2*Eb1g + Eb2g + Eb3g)/2, k == 2 && m == 0}, {(3*Sqrt[7/10]*(Eagx2y2 - Eb1g))/2, k == 4 && (m == -4 || m == 4)}, {(3*(Eb2g - Eb3g + Sqrt[3]*Mag))/Sqrt[10], k == 4 && (m == -2 || m == 2)}, {(3*(Eagx2y2 + 6*Eagz2 + Eb1g - 4*Eb2g - 4*Eb3g))/10, k == 4 && m == 0}}, 0]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{0, 0, (1/5)*(Eagx2y2 + Eagz2 + Eb1g + Eb2g + Eb3g)} , 
       {2, 0, (1/2)*((-2)*(Eagx2y2) + (2)*(Eagz2) + (-2)*(Eb1g) + Eb2g + Eb3g)} , 
       {2,-2, (1/4)*((sqrt(6))*(Eb2g) + (-1)*((sqrt(6))*(Eb3g)) + (-4)*((sqrt(2))*(Mag)))} , 
       {2, 2, (1/4)*((sqrt(6))*(Eb2g) + (-1)*((sqrt(6))*(Eb3g)) + (-4)*((sqrt(2))*(Mag)))} , 
       {4, 0, (3/10)*(Eagx2y2 + (6)*(Eagz2) + Eb1g + (-4)*(Eb2g) + (-4)*(Eb3g))} , 
       {4,-2, (3)*((1/(sqrt(10)))*(Eb2g + (-1)*(Eb3g) + (sqrt(3))*(Mag)))} , 
       {4, 2, (3)*((1/(sqrt(10)))*(Eb2g + (-1)*(Eb3g) + (sqrt(3))*(Mag)))} , 
       {4,-4, (3/2)*((sqrt(7/10))*(Eagx2y2 + (-1)*(Eb1g)))} , 
       {4, 4, (3/2)*((sqrt(7/10))*(Eagx2y2 + (-1)*(Eb1g)))} }

The Hamiltonian on a basis of spherical Harmonics

$ $	$ {Y_{-2}^{(2)}} $	$ {Y_{-1}^{(2)}} $	$ {Y_{0}^{(2)}} $	$ {Y_{1}^{(2)}} $	$ {Y_{2}^{(2)}} $
$ {Y_{-2}^{(2)}} $	$ \frac{\text{Eagx2y2}+\text{Eb1g}}{2} $	$ 0 $	$ \frac{\text{Mag}}{\sqrt{2}} $	$ 0 $	$ \frac{\text{Eagx2y2}-\text{Eb1g}}{2} $
$ {Y_{-1}^{(2)}} $	$ 0 $	$ \frac{\text{Eb2g}+\text{Eb3g}}{2} $	$ 0 $	$ \frac{\text{Eb3g}-\text{Eb2g}}{2} $	$ 0 $
$ {Y_{0}^{(2)}} $	$ \frac{\text{Mag}}{\sqrt{2}} $	$ 0 $	$ \text{Eagz2} $	$ 0 $	$ \frac{\text{Mag}}{\sqrt{2}} $
$ {Y_{1}^{(2)}} $	$ 0 $	$ \frac{\text{Eb3g}-\text{Eb2g}}{2} $	$ 0 $	$ \frac{\text{Eb2g}+\text{Eb3g}}{2} $	$ 0 $
$ {Y_{2}^{(2)}} $	$ \frac{\text{Eagx2y2}-\text{Eb1g}}{2} $	$ 0 $	$ \frac{\text{Mag}}{\sqrt{2}} $	$ 0 $	$ \frac{\text{Eagx2y2}+\text{Eb1g}}{2} $

The Hamiltonian on a basis of symmetric functions

$ $	$ d_{x^2-y^2} $	$ d_{3z^2-r^2} $	$ d_{\text{yz}} $	$ d_{\text{xz}} $	$ d_{\text{xy}} $
$ d_{x^2-y^2} $	$ \text{Eagx2y2} $	$ \text{Mag} $	$ 0 $	$ 0 $	$ 0 $
$ d_{3z^2-r^2} $	$ \text{Mag} $	$ \text{Eagz2} $	$ 0 $	$ 0 $	$ 0 $
$ d_{\text{yz}} $	$ 0 $	$ 0 $	$ \text{Eb3g} $	$ 0 $	$ 0 $
$ d_{\text{xz}} $	$ 0 $	$ 0 $	$ 0 $	$ \text{Eb2g} $	$ 0 $
$ d_{\text{xy}} $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ \text{Eb1g} $

Rotation matrix used

$ $	$ {Y_{-2}^{(2)}} $	$ {Y_{-1}^{(2)}} $	$ {Y_{0}^{(2)}} $	$ {Y_{1}^{(2)}} $	$ {Y_{2}^{(2)}} $
$ d_{x^2-y^2} $	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ \frac{1}{\sqrt{2}} $
$ d_{3z^2-r^2} $	$ 0 $	$ 0 $	$ 1 $	$ 0 $	$ 0 $
$ d_{\text{yz}} $	$ 0 $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ \frac{i}{\sqrt{2}} $	$ 0 $
$ d_{\text{xz}} $	$ 0 $	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ -\frac{1}{\sqrt{2}} $	$ 0 $
$ d_{\text{xy}} $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ -\frac{i}{\sqrt{2}} $

Irriducible representations and their onsite energy

	$$\text{Eagx2y2}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{15}{\pi }} \sin ^2(\theta ) \cos (2 \phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{15}{\pi }} \left(x^2-y^2\right)$$
	$$\text{Eagz2}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{8} \sqrt{\frac{5}{\pi }} (3 \cos (2 \theta )+1)$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{5}{\pi }} \left(3 z^2-1\right)$$
	$$\text{Eb3g}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{15}{\pi }} \sin (2 \theta ) \sin (\phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{15}{\pi }} y z$$
	$$\text{Eb2g}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{15}{\pi }} \sin (2 \theta ) \cos (\phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{15}{\pi }} x z$$
	$$\text{Eb1g}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{15}{\pi }} \sin ^2(\theta ) \sin (2 \phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{15}{\pi }} x y$$

Potential for f orbitals

Potential parameterized with onsite energies of irriducible representations

$$A_{k,m} = \begin{cases} \frac{1}{7} (\text{Eau}+\text{Eb1u1}+\text{Eb1u2}+\text{Eb2u1}+\text{Eb2u2}+\text{Eb3u1}+\text{Eb3u2}) & k=0\land m=0 \\ \frac{5}{28} \left(-\sqrt{6} \text{Eb2u1}+\sqrt{6} \text{Eb3u1}+\sqrt{10} (-2 \text{Mb1u}+\text{Mb2u}+\text{Mb3u})\right) & k=2\land (m=-2\lor m=2) \\ \frac{5}{14} \left(2 \text{Eb1u1}-\text{Eb2u1}-\text{Eb3u1}-\sqrt{15} \text{Mb2u}+\sqrt{15} \text{Mb3u}\right) & k=2\land m=0 \\ \frac{3 \left(-4 \sqrt{5} \text{Eau}+4 \sqrt{5} \text{Eb1u2}+3 \sqrt{5} \text{Eb2u1}-3 \sqrt{5} \text{Eb2u2}+3 \sqrt{5} \text{Eb3u1}-3 \sqrt{5} \text{Eb3u2}-2 \sqrt{3} \text{Mb2u}+2 \sqrt{3} \text{Mb3u}\right)}{8 \sqrt{14}} & k=4\land (m=-4\lor m=4) \\ \frac{3}{56} \left(3 \sqrt{10} \text{Eb2u1}-7 \sqrt{10} \text{Eb2u2}-3 \sqrt{10} \text{Eb3u1}+7 \sqrt{10} \text{Eb3u2}-4 \sqrt{6} \text{Mb1u}+2 \sqrt{6} \text{Mb2u}+2 \sqrt{6} \text{Mb3u}\right) & k=4\land (m=-2\lor m=2) \\ \frac{3}{56} \left(-28 \text{Eau}+24 \text{Eb1u1}-28 \text{Eb1u2}+9 \text{Eb2u1}+7 \text{Eb2u2}+9 \text{Eb3u1}+7 \text{Eb3u2}+2 \sqrt{15} \text{Mb2u}-2 \sqrt{15} \text{Mb3u}\right) & k=4\land m=0 \\ -\frac{13}{160} \sqrt{\frac{11}{7}} \left(5 \sqrt{3} \text{Eb2u1}+3 \sqrt{3} \text{Eb2u2}-5 \sqrt{3} \text{Eb3u1}-3 \sqrt{3} \text{Eb3u2}+6 \sqrt{5} \text{Mb2u}+6 \sqrt{5} \text{Mb3u}\right) & k=6\land (m=-6\lor m=6) \\ -\frac{13 \left(24 \text{Eau}-24 \text{Eb1u2}+15 \text{Eb2u1}-15 \text{Eb2u2}+15 \text{Eb3u1}-15 \text{Eb3u2}-2 \sqrt{15} \text{Mb2u}+2 \sqrt{15} \text{Mb3u}\right)}{80 \sqrt{14}} & k=6\land (m=-4\lor m=4) \\ -\frac{13 \left(5 \sqrt{15} \text{Eb2u1}+3 \sqrt{15} \text{Eb2u2}-5 \sqrt{15} \text{Eb3u1}-3 \sqrt{15} \text{Eb3u2}-64 \text{Mb1u}-34 \text{Mb2u}-34 \text{Mb3u}\right)}{160 \sqrt{7}} & k=6\land (m=-2\lor m=2) \\ \frac{13}{560} \left(24 \text{Eau}+80 \text{Eb1u1}+24 \text{Eb1u2}-25 \text{Eb2u1}-39 \text{Eb2u2}-25 \text{Eb3u1}-39 \text{Eb3u2}+14 \sqrt{15} \text{Mb2u}-14 \sqrt{15} \text{Mb3u}\right) & k=6\land m=0 \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{(Eau + Eb1u1 + Eb1u2 + Eb2u1 + Eb2u2 + Eb3u1 + Eb3u2)/7, k == 0 && m == 0}, {(5*(-(Sqrt[6]*Eb2u1) + Sqrt[6]*Eb3u1 + Sqrt[10]*(-2*Mb1u + Mb2u + Mb3u)))/28, k == 2 && (m == -2 || m == 2)}, {(5*(2*Eb1u1 - Eb2u1 - Eb3u1 - Sqrt[15]*Mb2u + Sqrt[15]*Mb3u))/14, k == 2 && m == 0}, {(3*(-4*Sqrt[5]*Eau + 4*Sqrt[5]*Eb1u2 + 3*Sqrt[5]*Eb2u1 - 3*Sqrt[5]*Eb2u2 + 3*Sqrt[5]*Eb3u1 - 3*Sqrt[5]*Eb3u2 - 2*Sqrt[3]*Mb2u + 2*Sqrt[3]*Mb3u))/(8*Sqrt[14]), k == 4 && (m == -4 || m == 4)}, {(3*(3*Sqrt[10]*Eb2u1 - 7*Sqrt[10]*Eb2u2 - 3*Sqrt[10]*Eb3u1 + 7*Sqrt[10]*Eb3u2 - 4*Sqrt[6]*Mb1u + 2*Sqrt[6]*Mb2u + 2*Sqrt[6]*Mb3u))/56, k == 4 && (m == -2 || m == 2)}, {(3*(-28*Eau + 24*Eb1u1 - 28*Eb1u2 + 9*Eb2u1 + 7*Eb2u2 + 9*Eb3u1 + 7*Eb3u2 + 2*Sqrt[15]*Mb2u - 2*Sqrt[15]*Mb3u))/56, k == 4 && m == 0}, {(-13*Sqrt[11/7]*(5*Sqrt[3]*Eb2u1 + 3*Sqrt[3]*Eb2u2 - 5*Sqrt[3]*Eb3u1 - 3*Sqrt[3]*Eb3u2 + 6*Sqrt[5]*Mb2u + 6*Sqrt[5]*Mb3u))/160, k == 6 && (m == -6 || m == 6)}, {(-13*(24*Eau - 24*Eb1u2 + 15*Eb2u1 - 15*Eb2u2 + 15*Eb3u1 - 15*Eb3u2 - 2*Sqrt[15]*Mb2u + 2*Sqrt[15]*Mb3u))/(80*Sqrt[14]), k == 6 && (m == -4 || m == 4)}, {(-13*(5*Sqrt[15]*Eb2u1 + 3*Sqrt[15]*Eb2u2 - 5*Sqrt[15]*Eb3u1 - 3*Sqrt[15]*Eb3u2 - 64*Mb1u - 34*Mb2u - 34*Mb3u))/(160*Sqrt[7]), k == 6 && (m == -2 || m == 2)}, {(13*(24*Eau + 80*Eb1u1 + 24*Eb1u2 - 25*Eb2u1 - 39*Eb2u2 - 25*Eb3u1 - 39*Eb3u2 + 14*Sqrt[15]*Mb2u - 14*Sqrt[15]*Mb3u))/560, k == 6 && m == 0}}, 0]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{0, 0, (1/7)*(Eau + Eb1u1 + Eb1u2 + Eb2u1 + Eb2u2 + Eb3u1 + Eb3u2)} , 
       {2, 0, (5/14)*((2)*(Eb1u1) + (-1)*(Eb2u1) + (-1)*(Eb3u1) + (-1)*((sqrt(15))*(Mb2u)) + (sqrt(15))*(Mb3u))} , 
       {2,-2, (5/28)*((-1)*((sqrt(6))*(Eb2u1)) + (sqrt(6))*(Eb3u1) + (sqrt(10))*((-2)*(Mb1u) + Mb2u + Mb3u))} , 
       {2, 2, (5/28)*((-1)*((sqrt(6))*(Eb2u1)) + (sqrt(6))*(Eb3u1) + (sqrt(10))*((-2)*(Mb1u) + Mb2u + Mb3u))} , 
       {4, 0, (3/56)*((-28)*(Eau) + (24)*(Eb1u1) + (-28)*(Eb1u2) + (9)*(Eb2u1) + (7)*(Eb2u2) + (9)*(Eb3u1) + (7)*(Eb3u2) + (2)*((sqrt(15))*(Mb2u)) + (-2)*((sqrt(15))*(Mb3u)))} , 
       {4,-2, (3/56)*((3)*((sqrt(10))*(Eb2u1)) + (-7)*((sqrt(10))*(Eb2u2)) + (-3)*((sqrt(10))*(Eb3u1)) + (7)*((sqrt(10))*(Eb3u2)) + (-4)*((sqrt(6))*(Mb1u)) + (2)*((sqrt(6))*(Mb2u)) + (2)*((sqrt(6))*(Mb3u)))} , 
       {4, 2, (3/56)*((3)*((sqrt(10))*(Eb2u1)) + (-7)*((sqrt(10))*(Eb2u2)) + (-3)*((sqrt(10))*(Eb3u1)) + (7)*((sqrt(10))*(Eb3u2)) + (-4)*((sqrt(6))*(Mb1u)) + (2)*((sqrt(6))*(Mb2u)) + (2)*((sqrt(6))*(Mb3u)))} , 
       {4,-4, (3/8)*((1/(sqrt(14)))*((-4)*((sqrt(5))*(Eau)) + (4)*((sqrt(5))*(Eb1u2)) + (3)*((sqrt(5))*(Eb2u1)) + (-3)*((sqrt(5))*(Eb2u2)) + (3)*((sqrt(5))*(Eb3u1)) + (-3)*((sqrt(5))*(Eb3u2)) + (-2)*((sqrt(3))*(Mb2u)) + (2)*((sqrt(3))*(Mb3u))))} , 
       {4, 4, (3/8)*((1/(sqrt(14)))*((-4)*((sqrt(5))*(Eau)) + (4)*((sqrt(5))*(Eb1u2)) + (3)*((sqrt(5))*(Eb2u1)) + (-3)*((sqrt(5))*(Eb2u2)) + (3)*((sqrt(5))*(Eb3u1)) + (-3)*((sqrt(5))*(Eb3u2)) + (-2)*((sqrt(3))*(Mb2u)) + (2)*((sqrt(3))*(Mb3u))))} , 
       {6, 0, (13/560)*((24)*(Eau) + (80)*(Eb1u1) + (24)*(Eb1u2) + (-25)*(Eb2u1) + (-39)*(Eb2u2) + (-25)*(Eb3u1) + (-39)*(Eb3u2) + (14)*((sqrt(15))*(Mb2u)) + (-14)*((sqrt(15))*(Mb3u)))} , 
       {6,-2, (-13/160)*((1/(sqrt(7)))*((5)*((sqrt(15))*(Eb2u1)) + (3)*((sqrt(15))*(Eb2u2)) + (-5)*((sqrt(15))*(Eb3u1)) + (-3)*((sqrt(15))*(Eb3u2)) + (-64)*(Mb1u) + (-34)*(Mb2u) + (-34)*(Mb3u)))} , 
       {6, 2, (-13/160)*((1/(sqrt(7)))*((5)*((sqrt(15))*(Eb2u1)) + (3)*((sqrt(15))*(Eb2u2)) + (-5)*((sqrt(15))*(Eb3u1)) + (-3)*((sqrt(15))*(Eb3u2)) + (-64)*(Mb1u) + (-34)*(Mb2u) + (-34)*(Mb3u)))} , 
       {6,-4, (-13/80)*((1/(sqrt(14)))*((24)*(Eau) + (-24)*(Eb1u2) + (15)*(Eb2u1) + (-15)*(Eb2u2) + (15)*(Eb3u1) + (-15)*(Eb3u2) + (-2)*((sqrt(15))*(Mb2u)) + (2)*((sqrt(15))*(Mb3u))))} , 
       {6, 4, (-13/80)*((1/(sqrt(14)))*((24)*(Eau) + (-24)*(Eb1u2) + (15)*(Eb2u1) + (-15)*(Eb2u2) + (15)*(Eb3u1) + (-15)*(Eb3u2) + (-2)*((sqrt(15))*(Mb2u)) + (2)*((sqrt(15))*(Mb3u))))} , 
       {6,-6, (-13/160)*((sqrt(11/7))*((5)*((sqrt(3))*(Eb2u1)) + (3)*((sqrt(3))*(Eb2u2)) + (-5)*((sqrt(3))*(Eb3u1)) + (-3)*((sqrt(3))*(Eb3u2)) + (6)*((sqrt(5))*(Mb2u)) + (6)*((sqrt(5))*(Mb3u))))} , 
       {6, 6, (-13/160)*((sqrt(11/7))*((5)*((sqrt(3))*(Eb2u1)) + (3)*((sqrt(3))*(Eb2u2)) + (-5)*((sqrt(3))*(Eb3u1)) + (-3)*((sqrt(3))*(Eb3u2)) + (6)*((sqrt(5))*(Mb2u)) + (6)*((sqrt(5))*(Mb3u))))} }

The Hamiltonian on a basis of spherical Harmonics

$ $	$ {Y_{-3}^{(3)}} $	$ {Y_{-2}^{(3)}} $	$ {Y_{-1}^{(3)}} $	$ {Y_{0}^{(3)}} $	$ {Y_{1}^{(3)}} $	$ {Y_{2}^{(3)}} $	$ {Y_{3}^{(3)}} $
$ {Y_{-3}^{(3)}} $	$ \frac{1}{16} \left(5 \text{Eb2u1}+3 \text{Eb2u2}+5 \text{Eb3u1}+3 \text{Eb3u2}+2 \sqrt{15} (\text{Mb2u}-\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}-\sqrt{15} \text{Eb3u1}+\sqrt{15} \text{Eb3u2}-2 (\text{Mb2u}+\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}+\sqrt{15} \text{Eb3u1}-\sqrt{15} \text{Eb3u2}-2 \text{Mb2u}+2 \text{Mb3u}\right) $	$ 0 $	$ \frac{1}{16} \left(5 \text{Eb2u1}+3 \text{Eb2u2}-5 \text{Eb3u1}-3 \text{Eb3u2}+2 \sqrt{15} (\text{Mb2u}+\text{Mb3u})\right) $
$ {Y_{-2}^{(3)}} $	$ 0 $	$ \frac{\text{Eau}+\text{Eb1u2}}{2} $	$ 0 $	$ \frac{\text{Mb1u}}{\sqrt{2}} $	$ 0 $	$ \frac{\text{Eb1u2}-\text{Eau}}{2} $	$ 0 $
$ {Y_{-1}^{(3)}} $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}-\sqrt{15} \text{Eb3u1}+\sqrt{15} \text{Eb3u2}-2 (\text{Mb2u}+\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(3 \text{Eb2u1}+5 \text{Eb2u2}+3 \text{Eb3u1}+5 \text{Eb3u2}+2 \sqrt{15} (\text{Mb3u}-\text{Mb2u})\right) $	$ 0 $	$ \frac{1}{16} \left(3 \text{Eb2u1}+5 \text{Eb2u2}-3 \text{Eb3u1}-5 \text{Eb3u2}-2 \sqrt{15} (\text{Mb2u}+\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}+\sqrt{15} \text{Eb3u1}-\sqrt{15} \text{Eb3u2}-2 \text{Mb2u}+2 \text{Mb3u}\right) $
$ {Y_{0}^{(3)}} $	$ 0 $	$ \frac{\text{Mb1u}}{\sqrt{2}} $	$ 0 $	$ \text{Eb1u1} $	$ 0 $	$ \frac{\text{Mb1u}}{\sqrt{2}} $	$ 0 $
$ {Y_{1}^{(3)}} $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}+\sqrt{15} \text{Eb3u1}-\sqrt{15} \text{Eb3u2}-2 \text{Mb2u}+2 \text{Mb3u}\right) $	$ 0 $	$ \frac{1}{16} \left(3 \text{Eb2u1}+5 \text{Eb2u2}-3 \text{Eb3u1}-5 \text{Eb3u2}-2 \sqrt{15} (\text{Mb2u}+\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(3 \text{Eb2u1}+5 \text{Eb2u2}+3 \text{Eb3u1}+5 \text{Eb3u2}+2 \sqrt{15} (\text{Mb3u}-\text{Mb2u})\right) $	$ 0 $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}-\sqrt{15} \text{Eb3u1}+\sqrt{15} \text{Eb3u2}-2 (\text{Mb2u}+\text{Mb3u})\right) $
$ {Y_{2}^{(3)}} $	$ 0 $	$ \frac{\text{Eb1u2}-\text{Eau}}{2} $	$ 0 $	$ \frac{\text{Mb1u}}{\sqrt{2}} $	$ 0 $	$ \frac{\text{Eau}+\text{Eb1u2}}{2} $	$ 0 $
$ {Y_{3}^{(3)}} $	$ \frac{1}{16} \left(5 \text{Eb2u1}+3 \text{Eb2u2}-5 \text{Eb3u1}-3 \text{Eb3u2}+2 \sqrt{15} (\text{Mb2u}+\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}+\sqrt{15} \text{Eb3u1}-\sqrt{15} \text{Eb3u2}-2 \text{Mb2u}+2 \text{Mb3u}\right) $	$ 0 $	$ \frac{1}{16} \left(\sqrt{15} \text{Eb2u1}-\sqrt{15} \text{Eb2u2}-\sqrt{15} \text{Eb3u1}+\sqrt{15} \text{Eb3u2}-2 (\text{Mb2u}+\text{Mb3u})\right) $	$ 0 $	$ \frac{1}{16} \left(5 \text{Eb2u1}+3 \text{Eb2u2}+5 \text{Eb3u1}+3 \text{Eb3u2}+2 \sqrt{15} (\text{Mb2u}-\text{Mb3u})\right) $

The Hamiltonian on a basis of symmetric functions

$ $	$ f_{\text{xyz}} $	$ f_{x\left(5x^2-r^2\right)} $	$ f_{y\left(5y^2-r^2\right)} $	$ f_{z\left(5z^2-r^2\right)} $	$ f_{x\left(y^2-z^2\right)} $	$ f_{y\left(z^2-x^2\right)} $	$ f_{z\left(x^2-y^2\right)} $
$ f_{\text{xyz}} $	$ \text{Eau} $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $	$ 0 $
$ f_{x\left(5x^2-r^2\right)} $	$ 0 $	$ \text{Eb3u1} $	$ 0 $	$ 0 $	$ \text{Mb3u} $	$ 0 $	$ 0 $
$ f_{y\left(5y^2-r^2\right)} $	$ 0 $	$ 0 $	$ \text{Eb2u1} $	$ 0 $	$ 0 $	$ \text{Mb2u} $	$ 0 $
$ f_{z\left(5z^2-r^2\right)} $	$ 0 $	$ 0 $	$ 0 $	$ \text{Eb1u1} $	$ 0 $	$ 0 $	$ \text{Mb1u} $
$ f_{x\left(y^2-z^2\right)} $	$ 0 $	$ \text{Mb3u} $	$ 0 $	$ 0 $	$ \text{Eb3u2} $	$ 0 $	$ 0 $
$ f_{y\left(z^2-x^2\right)} $	$ 0 $	$ 0 $	$ \text{Mb2u} $	$ 0 $	$ 0 $	$ \text{Eb2u2} $	$ 0 $
$ f_{z\left(x^2-y^2\right)} $	$ 0 $	$ 0 $	$ 0 $	$ \text{Mb1u} $	$ 0 $	$ 0 $	$ \text{Eb1u2} $

Rotation matrix used

$ $	$ {Y_{-3}^{(3)}} $	$ {Y_{-2}^{(3)}} $	$ {Y_{-1}^{(3)}} $	$ {Y_{0}^{(3)}} $	$ {Y_{1}^{(3)}} $	$ {Y_{2}^{(3)}} $	$ {Y_{3}^{(3)}} $
$ f_{\text{xyz}} $	$ 0 $	$ \frac{i}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ -\frac{i}{\sqrt{2}} $	$ 0 $
$ f_{x\left(5x^2-r^2\right)} $	$ \frac{\sqrt{5}}{4} $	$ 0 $	$ -\frac{\sqrt{3}}{4} $	$ 0 $	$ \frac{\sqrt{3}}{4} $	$ 0 $	$ -\frac{\sqrt{5}}{4} $
$ f_{y\left(5y^2-r^2\right)} $	$ -\frac{i \sqrt{5}}{4} $	$ 0 $	$ -\frac{i \sqrt{3}}{4} $	$ 0 $	$ -\frac{i \sqrt{3}}{4} $	$ 0 $	$ -\frac{i \sqrt{5}}{4} $
$ f_{z\left(5z^2-r^2\right)} $	$ 0 $	$ 0 $	$ 0 $	$ 1 $	$ 0 $	$ 0 $	$ 0 $
$ f_{x\left(y^2-z^2\right)} $	$ -\frac{\sqrt{3}}{4} $	$ 0 $	$ -\frac{\sqrt{5}}{4} $	$ 0 $	$ \frac{\sqrt{5}}{4} $	$ 0 $	$ \frac{\sqrt{3}}{4} $
$ f_{y\left(z^2-x^2\right)} $	$ -\frac{i \sqrt{3}}{4} $	$ 0 $	$ \frac{i \sqrt{5}}{4} $	$ 0 $	$ \frac{i \sqrt{5}}{4} $	$ 0 $	$ -\frac{i \sqrt{3}}{4} $
$ f_{z\left(x^2-y^2\right)} $	$ 0 $	$ \frac{1}{\sqrt{2}} $	$ 0 $	$ 0 $	$ 0 $	$ \frac{1}{\sqrt{2}} $	$ 0 $

Irriducible representations and their onsite energy

	$$\text{Eau}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{105}{\pi }} \sin ^2(\theta ) \cos (\theta ) \sin (2 \phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{2} \sqrt{\frac{105}{\pi }} x y z$$
	$$\text{Eb3u1}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{16} \sqrt{\frac{7}{\pi }} \sin (\theta ) \cos (\phi ) \left(10 \sin ^2(\theta ) \cos (2 \phi )-5 \cos (2 \theta )-7\right)$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{16} \sqrt{\frac{7}{\pi }} x \left(5 x^2-15 y^2-15 z^2+3\right)$$
	$$\text{Eb2u1}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$-\frac{1}{16} \sqrt{\frac{7}{\pi }} \sin (\theta ) \sin (\phi ) \left(10 \sin ^2(\theta ) \cos (2 \phi )+5 \cos (2 \theta )+7\right)$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{16} \sqrt{\frac{7}{\pi }} y \left(-15 x^2+5 y^2-15 z^2+3\right)$$
	$$\text{Eb1u1}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{16} \sqrt{\frac{7}{\pi }} (3 \cos (\theta )+5 \cos (3 \theta ))$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{7}{\pi }} z \left(5 z^2-3\right)$$
	$$\text{Eb3u2}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$-\frac{1}{16} \sqrt{\frac{105}{\pi }} \sin (\theta ) \cos (\phi ) \left(2 \sin ^2(\theta ) \cos (2 \phi )+3 \cos (2 \theta )+1\right)$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$-\frac{1}{16} \sqrt{\frac{105}{\pi }} x \left(x^2-3 y^2+5 z^2-1\right)$$
	$$\text{Eb2u2}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{32} \sqrt{\frac{105}{\pi }} \sin (\theta ) \sin (\phi ) \left(-4 \sin ^2(\theta ) \cos (2 \phi )+6 \cos (2 \theta )+2\right)$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{16} \sqrt{\frac{105}{\pi }} y \left(-3 x^2+y^2+5 z^2-1\right)$$
	$$\text{Eb1u2}$$
$$\psi(\theta,\phi)=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{105}{\pi }} \sin ^2(\theta ) \cos (\theta ) \cos (2 \phi )$$
$$\psi(\hat{x},\hat{y},\hat{z})=\phantom{\sqrt{\frac{1}{1}}}$$	$$\frac{1}{4} \sqrt{\frac{105}{\pi }} z \left(x^2-y^2\right)$$

Coupling between two shells

Click on one of the subsections to expand it or

Potential for s-d orbital mixing

Potential parameterized with onsite energies of irriducible representations

$$A_{k,m} = \begin{cases} 0 & k\neq 2\lor (m\neq -2\land m\neq 0\land m\neq 2) \\ A(2,2) & k=2\land (m=-2\lor m=2) \\ A(2,0) & \text{True} \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{0, k != 2 || (m != -2 && m != 0 && m != 2)}, {A[2, 2], k == 2 && (m == -2 || m == 2)}}, A[2, 0]]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{2, 0, A(2,0)} , 
       {2,-2, A(2,2)} , 
       {2, 2, A(2,2)} }

The Hamiltonian on a basis of spherical Harmonics

$ $	$ {Y_{-2}^{(2)}} $	$ {Y_{-1}^{(2)}} $	$ {Y_{0}^{(2)}} $	$ {Y_{1}^{(2)}} $	$ {Y_{2}^{(2)}} $
$ {Y_{0}^{(0)}} $	$ \frac{A(2,2)}{\sqrt{5}} $	$ 0 $	$ \frac{A(2,0)}{\sqrt{5}} $	$ 0 $	$ \frac{A(2,2)}{\sqrt{5}} $

The Hamiltonian on a basis of symmetric functions

$ $	$ d_{x^2-y^2} $	$ d_{3z^2-r^2} $	$ d_{\text{yz}} $	$ d_{\text{xz}} $	$ d_{\text{xy}} $
$ \text{s} $	$ \sqrt{\frac{2}{5}} A(2,2) $	$ \frac{A(2,0)}{\sqrt{5}} $	$ 0 $	$ 0 $	$ 0 $

Potential for p-f orbital mixing

Potential parameterized with onsite energies of irriducible representations

$$A_{k,m} = \begin{cases} 0 & k=0\land m=0 \\ A(2,2) & k=2\land (m=-2\lor m=2) \\ A(2,0) & k=2\land m=0 \\ A(4,4) & k=4\land (m=-4\lor m=4) \\ A(4,2) & k=4\land (m=-2\lor m=2) \\ A(4,0) & k=4\land m=0 \end{cases}$$

Input format suitable for Mathematica (Quanty.nb)

Akm_D2h_XYZ.Quanty.nb

Akm[k_,m_]:=Piecewise[{{0, k == 0 && m == 0}, {A[2, 2], k == 2 && (m == -2 || m == 2)}, {A[2, 0], k == 2 && m == 0}, {A[4, 4], k == 4 && (m == -4 || m == 4)}, {A[4, 2], k == 4 && (m == -2 || m == 2)}, {A[4, 0], k == 4 && m == 0}}, 0]

Input format suitable for Quanty

Akm_D2h_XYZ.Quanty

Akm = {{2, 0, A(2,0)} , 
       {2,-2, A(2,2)} , 
       {2, 2, A(2,2)} , 
       {4, 0, A(4,0)} , 
       {4,-2, A(4,2)} , 
       {4, 2, A(4,2)} , 
       {4,-4, A(4,4)} , 
       {4, 4, A(4,4)} }

The Hamiltonian on a basis of spherical Harmonics

$ $	$ {Y_{-3}^{(3)}} $	$ {Y_{-2}^{(3)}} $	$ {Y_{-1}^{(3)}} $	$ {Y_{0}^{(3)}} $	$ {Y_{1}^{(3)}} $	$ {Y_{2}^{(3)}} $	$ {Y_{3}^{(3)}} $
$ {Y_{-1}^{(1)}} $	$ \frac{3 A(2,2)}{\sqrt{35}}-\frac{A(4,2)}{3 \sqrt{21}} $	$ 0 $	$ \frac{1}{15} \sqrt{\frac{2}{7}} (9 A(2,0)-5 A(4,0)) $	$ 0 $	$ \frac{1}{105} \left(3 \sqrt{21} A(2,2)-5 \sqrt{35} A(4,2)\right) $	$ 0 $	$ -\frac{2 A(4,4)}{3 \sqrt{3}} $
$ {Y_{0}^{(1)}} $	$ 0 $	$ \sqrt{\frac{3}{35}} A(2,2)+\frac{2 A(4,2)}{3 \sqrt{7}} $	$ 0 $	$ \frac{27 A(2,0)+20 A(4,0)}{15 \sqrt{21}} $	$ 0 $	$ \sqrt{\frac{3}{35}} A(2,2)+\frac{2 A(4,2)}{3 \sqrt{7}} $	$ 0 $
$ {Y_{1}^{(1)}} $	$ -\frac{2 A(4,4)}{3 \sqrt{3}} $	$ 0 $	$ \frac{1}{105} \left(3 \sqrt{21} A(2,2)-5 \sqrt{35} A(4,2)\right) $	$ 0 $	$ \frac{1}{15} \sqrt{\frac{2}{7}} (9 A(2,0)-5 A(4,0)) $	$ 0 $	$ \frac{3 A(2,2)}{\sqrt{35}}-\frac{A(4,2)}{3 \sqrt{21}} $

The Hamiltonian on a basis of symmetric functions

$ $	$ f_{\text{xyz}} $	$ f_{x\left(5x^2-r^2\right)} $	$ f_{y\left(5y^2-r^2\right)} $	$ f_{z\left(5z^2-r^2\right)} $	$ f_{x\left(y^2-z^2\right)} $	$ f_{y\left(z^2-x^2\right)} $	$ f_{z\left(x^2-y^2\right)} $
$ p_x $	$ 0 $	$ \frac{1}{630} \left(-27 \sqrt{21} A(2,0)+81 \sqrt{14} A(2,2)+5 \left(3 \sqrt{21} A(4,0)-2 \sqrt{210} A(4,2)+7 \sqrt{30} A(4,4)\right)\right) $	$ 0 $	$ 0 $	$ \frac{1}{210} \left(-9 \sqrt{35} A(2,0)-3 \sqrt{210} A(2,2)+5 \left(\sqrt{35} A(4,0)-2 \sqrt{14} A(4,2)-7 \sqrt{2} A(4,4)\right)\right) $	$ 0 $	$ 0 $
$ p_y $	$ 0 $	$ 0 $	$ \frac{1}{630} \left(-27 \sqrt{21} A(2,0)-81 \sqrt{14} A(2,2)+5 \left(3 \sqrt{21} A(4,0)+2 \sqrt{210} A(4,2)+7 \sqrt{30} A(4,4)\right)\right) $	$ 0 $	$ 0 $	$ \frac{1}{210} \left(9 \sqrt{35} A(2,0)-3 \sqrt{210} A(2,2)-5 \left(\sqrt{35} A(4,0)+2 \sqrt{14} A(4,2)-7 \sqrt{2} A(4,4)\right)\right) $	$ 0 $
$ p_z $	$ 0 $	$ 0 $	$ 0 $	$ \frac{27 A(2,0)+20 A(4,0)}{15 \sqrt{21}} $	$ 0 $	$ 0 $	$ \sqrt{\frac{6}{35}} A(2,2)+\frac{2}{3} \sqrt{\frac{2}{7}} A(4,2) $

Table of several point groups

Return to Main page on Point Groups

Nonaxial groups	C₁	C_s	C_i
C_n groups	C₂	C₃	C₄	C₅	C₆	C₇	C₈
D_n groups	D₂	D₃	D₄	D₅	D₆	D₇	D₈
C_nv groups	C_2v	C_3v	C_4v	C_5v	C_6v	C_7v	C_8v
C_nh groups	C_2h	C_3h	C_4h	C_5h	C_6h
D_nh groups	D_2h	D_3h	D_4h	D_5h	D_6h	D_7h	D_8h
D_nd groups	D_2d	D_3d	D_4d	D_5d	D_6d	D_7d	D_8d
S_n groups	S₂	S₄	S₆	S₈	S₁₀	S₁₂
Cubic groups	T	T_h	T_d	O	O_h	I	I_h
Linear groups	C_$\infty$v	D_$\infty$h

Table of Contents

Orientation XYZ

Symmetry Operations

Different Settings

Character Table

Product Table

Sub Groups with compatible settings

Super Groups with compatible settings

Invariant Potential expanded on renormalized spherical Harmonics

Expansion

Input format suitable for Mathematica (Quanty.nb)

Input format suitable for Quanty

One particle coupling on a basis of spherical harmonics

Rotation matrix to symmetry adapted functions (choice is not unique)

One particle coupling on a basis of symmetry adapted functions

Coupling for a single shell

Potential for s orbitals

Potential for p orbitals

Potential for d orbitals

Potential for f orbitals

Coupling between two shells

Potential for s-d orbital mixing

Potential for p-f orbital mixing

Table of several point groups