in terms of Whittaker functions

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1: 13.27 Mathematical Applications
The other group elements correspond to integral operators whose kernels can be expressed in terms of Whittaker functions. …
2: 13.23 Integrals
§13.23(iv) Integral Transforms interms of WhittakerFunctions
Generalized orthogonality integrals (33.14.13) and (33.14.15) can be expressed in terms of Whittaker functions via the definitions in that section.
3: 13.18 Relations to Other Functions
For representations of Coulomb functions in terms of Whittaker functions see (33.2.3), (33.2.7), (33.14.4) and (33.14.7)
4: 28.8 Asymptotic Expansions for Large $q$
The approximations are expressed in terms of Whittaker functions $W_{\kappa,\mu}\left(z\right)$ and $M_{\kappa,\mu}\left(z\right)$ with $\mu=\tfrac{1}{4}$; compare §2.8(vi). …With additional restrictions on $z$, uniform asymptotic approximations for solutions of (28.2.1) and (28.20.1) are also obtained in terms of elementary functions by re-expansions of the Whittaker functions; compare §2.8(ii). Subsequently the asymptotic solutions involving either elementary or Whittaker functions are identified in terms of the Floquet solutions $\mathrm{me}_{\nu}\left(z,q\right)$28.12(ii)) and modified Mathieu functions ${\mathrm{M}^{(j)}_{\nu}}\left(z,h\right)$28.20(iii)). …
5: 13.10 Integrals
For integral transforms in terms of Whittaker functions see §13.23(iv). …
6: 33.14 Definitions and Basic Properties
33.14.14 $\phi_{n,\ell}(r)=(-1)^{\ell+1+n}(2/n^{3})^{1/2}s\left(-1/n^{2},\ell;r\right)=% \frac{(-1)^{\ell+1+n}}{n^{\ell+2}}\left(\frac{(n-\ell-1)!}{(n+\ell)!}\right)^{% 1/2}(2r)^{\ell+1}{\mathrm{e}}^{-r/n}L^{(2\ell+1)}_{n-\ell-1}\left(2r/n\right)$
7: 32.10 Special Function Solutions
$\mbox{P}_{\mbox{\scriptsize V}}$ then has solutions expressible in terms of Whittaker functions13.14(i)), iff …
8: 18.15 Asymptotic Approximations
These expansions are in terms of Whittaker functions13.14). …
9: 2.8 Differential Equations with a Parameter
For examples of uniform asymptotic approximations in terms of Whittaker functions with fixed second parameter see §18.15(i) and §28.8(iv). …
10: 13.28 Physical Applications
§13.28 Physical Applications
and $V^{(j)}_{\kappa,\mu}(z)$, $j=1,2$, denotes any pair of solutions of Whittaker’s equation (13.14.1). … For potentials in quantum mechanics that are solvable in terms of confluent hypergeometric functions see Negro et al. (2000).