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We derive an expression for the energy spectrum and the wave function in terms of generalized hypergeometric functions $_2F_1(\\alpha, \\beta; \\gamma; k_3s)$. 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Falaye, Majid Hamzavi, Sameer M. Ikhdair","submitted_at":"2014-08-15T12:50:24Z","abstract_excerpt":"We present a simple formula for finding bound state solution of any quantum wave equation which can be simplified to the form of $\\Psi\"(s)+\\frac{(k_1-k_2s)}{s(1-k_3s)}\\Psi'(s)+\\frac{(As^2+Bs+C)}{s^2(1-k_3s)^2}\\Psi(s)=0$. The two cases where $k_3=0$ and $k_3\\neq 0$ are studied. We derive an expression for the energy spectrum and the wave function in terms of generalized hypergeometric functions $_2F_1(\\alpha, \\beta; \\gamma; k_3s)$. 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