Discrete spectrum Analysis using Laplace transform and Volterra equations (DALV-method)

The theory of excitons in two dimensional materials including graphene and transition metal dichalcogenides (TMD) is complicated, as there appears a screened interaction in equations. Such interaction can be represented as Keldysh potential. The exact solution does not seem to exist yet. The method of searching appropriate solutions to equations of quantum mechanics is believed to solve this problem by using Laplace transform of tempered distributions and Volterra equations. The method is to seek solution as a Laplace transform of some tempered distribution that satisfies the appropriate Laplace spectral equation which, under Laplace transform, gives us the initial equation. Due to Paly-Wigner-Schwarz theorem, the image functions behavior depends on the geometry of original one support. In addition, the homogenous Volterra equation does not have nontrivial continuous solution. These constraints together with the fact that the studied equations turn out to be Volterra equations of III kind lead to a method that seems to solve a wide class of quantum mechanics equations.

1. Titchmarsh E.G., Teichmann T. Eigenfunction expansions associated with secondorder differential equations, part 2. PhT, 1958, 11(10), P. 34.

2. Teschl G. Mathematical Methods in Quantum Mechanics: With Applications to Schrödinger Operators. Graduate studies in mathematics. American Mathematical Society, 2009.

3. Dunford N., Schwartz J.T. Linear Operators, Part 2: Spectral Theory, Self Adjoint Operators in Hilbert Space. Wiley Classics Library, Wiley, 1988.

4. Fedoryuk M.V., Maslov V.P. Quasiclassical approximation for quantum mechanics equations, 1976.

5. Englefield M.J. Solution of Schrödinger equation by Laplace transform. Journal of The Australian Mathematical Society, 1968, 8(3), P. 557– 567.

6. Englefield M.J. Solution of coulomb problem by Laplace transform. Journal of Mathematical Analysis and Applications, 1974, 48(1), P. 270– 275.

7. Altuüg Arda and Ramazan Sever. Exact solutions of the Schrödinger equation via Laplace transform approach: pseudoharmonic potential and mietype potentials. Journal of Mathematical Chemistry, 2012, 50(4), P. 971–980.

8. Douglas R.M., Pimentel and Antonio S De Castro. A Laplace transform approach to the quantum harmonic oscillator. European Journal of Physics, 2012, 34(1), P. 199.

9. Ginyih Tsaur and Jyhpyng Wang. A universal Laplace transform approach to solving Schrödinger equations for all known solvable models. European Journal of Physics, 2013, 35(1), P. 015006.

10. Tapas Das and Altu¨g Arda. Exact analytical solution of the ndimensional radial Schrödinger equation with pseudoharmonic potential via Laplace transform approach. Advances in High Energy Physics, 2015, 2015.

11. Yangqiang Ran, Lihui Xue, Sizhu Hu, and RuKeng Su. On the coulombtype potential of the onedimensional Schrödinger equation. Journal of Physics A: Mathematical and General, 2000, 33(50), P. 9265.

12. Naber M. Time fractional Schrödinger equation. Journal of Mathematical Physics, 2004, 45(8), P. 3339–3352.

13. Michael E. Clarkson and Huw O Pritchard. A Laplace transform solution of Schrödingers equation using symbolic algebra. International journal of quantum chemistry, 1992, 41(6), P. 829–844.

14. Zemanian A.H. Generalized integral transformations, 1968.

15. Warnock R.L. Bart G.R. Linear integral equations of the third kind. SIAM Journal on Mathematical Analysis, 1973, 4(4), P. 609–622.

16. Vainikko G. Cordial Volterra integral equations 1. Numerical Functional Analysis and Optimization, 2009, 30(910), P. 1145–1172.

17. Vainikko G. Cordial Volterra integral equations 2. Numrical Functional Analysis and Optimization, 2010, 31(2), P. 191–219.

18. Vladimirov V.S. Generalized functions in mathematical physics, Nauka, Moscow, 1979. English transl, Mir, Moscow, 1979.