Quasi-exact solvability

Template:Multiple issues A linear differential operator L is called quasi-exactly-solvable (QES) if it has a finite-dimensional invariant subspace of functions ${\displaystyle \{𝒱{\}}_n}$ such that ${\displaystyle L:\{𝒱{\}}_n\to \{𝒱{\}}_n,}$ where n is a dimension of ${\displaystyle \{𝒱{\}}_n}$. There are two important cases:

1. ${\displaystyle \{𝒱{\}}_n}$ is the space of multivariate polynomials of degree not higher than some integer number; and
2. ${\displaystyle \{𝒱{\}}_n}$ is a subspace of a Hilbert space. Sometimes, the functional space ${\displaystyle \{𝒱{\}}_n}$ is isomorphic to the finite-dimensional representation space of a Lie algebra g of first-order differential operators. In this case, the operator L is called a g-Lie-algebraic Quasi-Exactly-Solvable operator. Usually, one can indicate basis where L has block-triangular form. If the operator L is of the second order and has the form of the Schrödinger operator, it is called a Quasi-Exactly-Solvable Schrödinger operator.

The most studied cases are one-dimensional ${\displaystyle sl(2)}$-Lie-algebraic quasi-exactly-solvable (Schrödinger) operators. The best known example is the sextic QES anharmonic oscillator with the Hamiltonian

${\displaystyle \{\mathscr{H}\}=-\frac{d^2}{d{x}^2}+a^2{x}^6+2ab{x}^4+[b^2-(4n+3+2p)a]x^2,a\ge 0,n\in \mathbb{N},p=\{0,1\},}$

where (n+1) eigenstates of positive (negative) parity can be found algebraically. Their eigenfunctions are of the form

${\displaystyle \mathrm{\Psi }(x)=x^p{P}_n(x^2)e^{-\frac{a{x}^4}{4}-\frac{b{x}^2}{2}},}$

where ${\displaystyle P_n(x^2)}$ is a polynomial of degree n and (energies) eigenvalues are roots of an algebraic equation of degree (n+1). In general, twelve families of one-dimensional QES problems are known, two of them characterized by elliptic potentials.

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