Hooke's atom

Template:Short description Hooke's atom, also known as harmonium or hookium, refers to an artificial helium-like atom where the Coulombic electron-nucleus interaction potential is replaced by a harmonic potential.^[1][2] This system is of significance as it is, for certain values of the force constant defining the harmonic containment, an exactly solvable^[3] ground-state many-electron problem that explicitly includes electron correlation. As such it can provide insight into quantum correlation (albeit in the presence of a non-physical nuclear potential) and can act as a test system for judging the accuracy of approximate quantum chemical methods for solving the Schrödinger equation.^[4][5] The name "Hooke's atom" arises because the harmonic potential used to describe the electron-nucleus interaction is a consequence of Hooke's law.

Employing atomic units, the Hamiltonian defining the Hooke's atom is

${\displaystyle \hat{H}=-\frac{1}{2}{\displaystyle \underset{1}{\overset{2}{\mathrm{\nabla }}}}-\frac{1}{2}{\displaystyle \underset{2}{\overset{2}{\mathrm{\nabla }}}}+\frac{1}{2}k(r_1^2+r_2^2)+\frac{1}{|{𝐫}_1-{𝐫}_2|}.}$

As written, the first two terms are the kinetic energy operators of the two electrons, the third term is the harmonic electron-nucleus potential, and the final term the electron-electron interaction potential. The non-relativistic Hamiltonian of the helium atom differs only in the replacement:

${\displaystyle -\frac{2}{r}\to \frac{1}{2}k{r}^2.}$

The equation to be solved is the two electron Schrödinger equation:

${\displaystyle \hat{H}\mathrm{\Psi }({𝐫}_1,{𝐫}_2)=E\mathrm{\Psi }({𝐫}_1,{𝐫}_2).}$

For arbitrary values of the force constant, Template:Math, the Schrödinger equation does not have an analytic solution. However, for a countably infinite number of values, such as Template:Math, simple closed form solutions can be derived.^[5] Given the artificial nature of the system this restriction does not hinder the usefulness of the solution.

To solve, the system is first transformed from the Cartesian electronic coordinates, Template:Math, to the center of mass coordinates, Template:Math, defined as

${\displaystyle 𝐑=\frac{1}{2}({𝐫}_1+{𝐫}_2),𝐮={𝐫}_2-{𝐫}_1.}$

Under this transformation, the Hamiltonian becomes separable – that is, the Template:Math term coupling the two electrons is removed (and not replaced by some other form) allowing the general separation of variables technique to be applied to further a solution for the wave function in the form ${\displaystyle \mathrm{\Psi }({𝐫}_1,{𝐫}_2)=\chi (𝐑)\mathrm{\Phi }(𝐮)}$. The original Schrödinger equation is then replaced by:

${\displaystyle (-\frac{1}{4}{\displaystyle \underset{𝐑}{\overset{2}{\mathrm{\nabla }}}}+k{R}^2)\chi (𝐑)=E_{𝐑}\chi (𝐑),}$

${\displaystyle (-{\displaystyle \underset{𝐮}{\overset{2}{\mathrm{\nabla }}}}+\frac{1}{4}k{u}^2+\frac{1}{u})\mathrm{\Phi }(𝐮)=E_{𝐮}\mathrm{\Phi }(𝐮).}$

The first equation for ${\displaystyle \chi (𝐑)}$ is the Schrödinger equation for an isotropic quantum harmonic oscillator with ground-state energy ${\displaystyle E_{𝐑}=(3/2)\sqrt{k}{E}_{\mathrm{h}}}$ and (unnormalized) wave function

${\displaystyle \chi (𝐑)=e^{-\sqrt{k}{R}^2}.}$

Asymptotically, the second equation again behaves as a harmonic oscillator of the form ${\displaystyle \exp (-(\sqrt{k}/4)u^2)}$ and the rotationally invariant ground state can be expressed, in general, as ${\displaystyle \mathrm{\Phi }(𝐮)=f(u)\exp (-(\sqrt{k}/4)u^2)}$ for some function ${\displaystyle f(u)}$. It was long noted that Template:Math is very well approximated by a linear function in Template:Math.^[2] Thirty years after the proposal of the model an exact solution was discovered for Template:Math,^[3] and it was seen that Template:Math. It was later shown that there are many values of Template:Math which lead to an exact solution for the ground state,^[5] as will be shown in the following.

Decomposing ${\displaystyle \mathrm{\Phi }(𝐮)=R_l(u)Y_{lm}}$ and expressing the Laplacian in spherical coordinates,

${\displaystyle (-\frac{1}{u^2}\frac{\partial }{\partial u}\left(u^2\frac{\partial }{\partial u}\right)+\frac{{\hat{L}}^2}{u^2}+\frac{1}{4}k{u}^2+\frac{1}{u})R_l(u)Y_{lm}(\widehat{𝐮})=E_l{R}_l(u)Y_{lm}(\widehat{𝐮}),}$

one further decomposes the radial wave function as ${\displaystyle R_l(u)=S_l(u)/u}$ which removes the first derivative to yield

${\displaystyle -\frac{{\partial }^2{S}_l(u)}{\partial u^2}+(\frac{l(l+1)}{u^2}+\frac{1}{4}k{u}^2+\frac{1}{u})S_l(u)=E_l{S}_l(u).}$

The asymptotic behavior ${\displaystyle S_l(u)\sim e^{-\frac{\sqrt{k}}{4}{u}^2}}$ encourages a solution of the form

${\displaystyle S_l(u)=e^{-\frac{\sqrt{k}}{4}{u}^2}{T}_l(u).}$

The differential equation satisfied by ${\displaystyle T_l(u)}$ is

${\displaystyle -\frac{{\partial }^2{T}_l(u)}{\partial u^2}+\sqrt{k}u\frac{\partial T_l(u)}{\partial u}+(\frac{l(l+1)}{u^2}+\frac{1}{u}+(\frac{\sqrt{k}}{2}-E_l))T_l(u)=0.}$

This equation lends itself to a solution by way of the Frobenius method. That is, ${\displaystyle T_l(u)}$ is expressed as

${\displaystyle T_l(u)=u^m{\displaystyle \sum _{k=0}^{\mathrm{\infty }}}{a}_k{u}^k.}$

for some ${\displaystyle m}$ and ${\displaystyle \{a_k{\}}_{k=0}^{k=\mathrm{\infty }}}$ which satisfy:

${\displaystyle m(m-1)=l(l+1),}$

${\displaystyle a_0\ne 0}$

${\displaystyle a_1=\frac{a_0}{2(l+1)},}$

${\displaystyle a_2=\frac{a_1+(\sqrt{k}(l+\frac{3}{2})-E_l)a_0}{2(2l+3)}=\frac{a_0}{2(2l+3)}(\frac{1}{2(l+1)}+\sqrt{k}(l+\frac{3}{2})-E_l),}$

${\displaystyle a_3=\frac{a_2+(\sqrt{k}(l+\frac{5}{2})-E_l)a_1}{6(l+2)},}$

${\displaystyle a_{n+1}=\frac{a_n+(\sqrt{k}(l+\frac{1}{2}+n)-E_l)a_{n-1}}{(n+1)(2l+2+n)}.}$

The two solutions to the indicial equation are ${\displaystyle m=l+1}$ and ${\displaystyle m=-l}$ of which the former is taken as it yields the regular (bounded, normalizable) wave function. For a simple solution to exist, the infinite series is sought to terminate and it is here where particular values of Template:Math are exploited for an exact closed-form solution. Terminating the polynomial at any particular order can be accomplished with different values of Template:Math defining the Hamiltonian. As such there exists an infinite number of systems, differing only in the strength of the harmonic containment, with exact ground-state solutions. Most simply, to impose Template:Math for Template:Math, two conditions must be satisfied:

${\displaystyle \frac{1}{2(l+1)}+\sqrt{k}(l+\frac{3}{2})-E_l=0,}$

${\displaystyle \sqrt{k}(l+\frac{5}{2})=E_l.}$

These directly force Template:Math and Template:Math respectively, and as a consequence of the three term recession, all higher coefficients also vanish. Solving for ${\displaystyle \sqrt{k}}$ and ${\displaystyle E_l}$ yields

${\displaystyle \sqrt{k}=\frac{1}{2(l+1)},}$

${\displaystyle E_l=\frac{2l+5}{4(l+1)},}$

and the radial wave function

${\displaystyle T_l=u^{l+1}(a_0+\frac{a_0}{2(l+1)}u).}$

Transforming back to ${\displaystyle R_l(u)}$

${\displaystyle R_l(u)=\frac{T_l(u)e^{-\frac{\sqrt{k}}{4}{u}^2}}{u}=u^l(1+\frac{1}{2(l+1)}u)e^{-\frac{\sqrt{k}}{4}{u}^2},}$

the ground-state (with ${\displaystyle l=0}$ and energy ${\displaystyle 5/4E_{\mathrm{h}}}$) is finally

${\displaystyle \mathrm{\Phi }(𝐮)=(1+\frac{u}{2})e^{-u^2/8}.}$

Combining, normalizing, and transforming back to the original coordinates yields the ground state wave function:

${\displaystyle \mathrm{\Psi }({𝐫}_1,{𝐫}_2)=\frac{1}{2\sqrt{8{\pi }^{5/2}+5{\pi }^3}}(1+\frac{1}{2}|{𝐫}_1-{𝐫}_2|)\exp (-\frac{1}{4}(r_1^2+r_2^2\left)\right).}$

The corresponding ground-state total energy is then ${\displaystyle E=E_R+E_u=\frac{3}{4}+\frac{5}{4}=2E_{\mathrm{h}}}$.

The exact ground state electronic density of the Hooke atom for the special case ${\displaystyle k=1/4}$ is^[4]

${\displaystyle \rho (𝐫)=\frac{2}{{\pi }^{3/2}(8+5\sqrt{\pi })}{e}^{-(1/2)r^2}({\left(\frac{\pi }{2}\right)}^{1/2}(\frac{7}{4}+\frac{1}{4}{r}^2+(r+\frac{1}{r})\mathrm{e}\mathrm{r}\mathrm{f}\left(\frac{r}{\sqrt{2}}\right))+e^{-(1/2)r^2}).}$

From this we see that the radial derivative of the density vanishes at the nucleus. This is in stark contrast to the real (non-relativistic) helium atom where the density displays a cusp at the nucleus as a result of the unbounded Coulomb potential.

• List of quantum-mechanical systems with analytical solutions

Template:Reflist

• Template:Cite journal
• Template:Cite journal