1. Mahi R. Singh (2006) The effect of the dipole-dipole interaction in electromagnetically induced transparency in polaritonic band gap materials. J. Modern Optics. 52, 1857-1869.
2. Mahi R. Singh (2006) Transparency and spontaneous emission in densely doped photonic band gap materials. J. Phys. B: At. Mol. Opt. Phys. 39, 5131–5141.
3. I Haque and M. Singh (2006) Review Article, A Review of Coherent Population Trapping in Photonic and Polaritonic Band-gap Materials. V. J. of Math. Sciences, 6, 87-98.
4. M. Singh and I. Haque (2005) Coherent Population Trapping in Photonic and Dispersive Band-gap Materials. Journal of Modern Optics, 52, pp. 1857-1869.
5. D. Mukherji and M. Singh (2005) Theory of non-linear susceptibility in polaritonic band-gap materials doped with multi-level atoms. Phys. Stat. Solidi C2, 2994-2997.
6. M. Singh (2005) A study of electromagnetically induced transparency in photonic and dispersive band-gap materials. Phys. Stat. Solidi C (2), Issue 8, pp. 3051-3054.
7. M. Singh and I. Haque (2005) Numerical simulations of photon trapping in photonic crystals doped with multi-level atoms. Phys. Stat. Solidi C2, 2998-3001.
8. M. Singh (2004) Temperature dependent polarons hopping transport in poly (dA)-poly (dT) DNA and poly (dG)-poly (dC) DNA. J. Biomaterials Sci. 15(11).
9. M. Singh (2004) Giant refractive-index enhancement in dispersive polaritonic band-gap and photonic band gap materials. Phys. Rev. A 69, 023807-023815.
10. M. Singh (2004) Polaron transport in DNA. J. Biomaterial. Sci. 15, 1533-1544.
11. M. Singh (2004) Anomalous electromagnetically induced transparency in photonic band gap materials. Phys. Rev. A 70, 033813-20.
12. M. Singh and C.M. Tsang (2004) Numerical simulations of variable range hopping conductivity in DNA nucleoside films. J. Vac. Sci. A, 22(3), 752-754.
13. V.M. Yartsev, M. Singh and J. Desforges (2004) The effect of hopping in excitons formation in semiconductor nanostructures. Int. J. Mod. Phys. B, 17, 1-8.
14. M. Singh (2004) The effect of electric and magnetic fields on polaron hopping in DNA structures. Phys. Stat. Solidi C (2), Issue 8, pgs. 2970-2973.
15. S.P. Singh, M. Singh and B. Watson (2004) KY Fan’s best application approximation theorem and application. Fixed Point Theory, 5, 131-136.
16. V.M. Yartsev, M. Singh and J. Desforges (2003) Excitons in semiconductor nanostructures. Rev. Mexicana de Fisica, 49, 1-12.
17. M. Singh (2003) Polariton stark effect in dispersive and photonic materials. Physica B, 337, 266-274.
18. M. Singh (2003) Quantum beat phenomenon due to polaritons in dispersive and photonic band-gap materials. J. Mod. Optics, 50, 1319-1325.
19. M. Singh (2003) The electric field dependence dispersive transport of carriers in band tails of low-dimensional systems. Phil. Mag., 86, 797-805.
20. J. Desforges and M. Singh (2003) Diamagnetic and nonlinear Zeeman shifts in spatially separated electrons and holes layers of heterostructures. Phys. Stat. Solidi B, 237, 487-497.
21. J. Desforges and M. Singh (2003) Magneto-excitons from spatially separated electron-hole systems in semiconductor nanostructures with disorder. Physica E, 17, 215-216.
22. M. Singh and D. Mukherji (2003) Quantum beat phenomenon due to polaritons in III-V and IV-IV semiconductors doped with a quantum dot. Physica E, 17, 406-409.
23. A. Botha and M. Singh (2003) Electron-spin polarization in type II quantum wells from bulk inversion asymmetry. Phys. Rev. B66, 1953341-195338.
24. M. Singh, A. Botha and C.M. Tsang (2003) A study of two polaritons in dispersive and photonic band-gap materials. Physica E, 17, 465-467.
25. M. Singh and J. Desfroges (2002), The effect of magnetic field on excitons in heterostructures and bulk and semiconductors. PHYS REV. B66, 073310-73314.
26. S.P. Singh and M. Singh (2002), Some Results on variational inequalities. J. MATH. Sciences 2, 5-10.
27. V. Yartsev, M. Singh and J. Desfroges (2002), Excitons in semiconductor nanostructures. Rev. Mexicana de Fisica 36, 432-442.
28. Botha and M. Singh (2002), The effect of band anisotropy on the spin tunneling in type II semiconductor nanostructures. PHYS. STATUS SOLIDI B231, 437-445.
29. M. Singh, J. Desforges and S. Barrie (2002), Acoustic phonon and dressed polariton Interaction in dispersive and photonic band gap materials. PHYSICA B 316, 339-341.
30. M. Singh and Jean Desforges (2002), Excitons formation from spatially separated electrons and holes in semiconductor nanostructures with disorder. PHYSICA E 12, 327-330.
31. A.Botha and M. Singh (2001), The effect of band anisotropy on the spin tunneling in type II semiconductor nanostructures. PHYS. STATUS SOLIDI B231, 437-445 (2002).
32. M. Singh, J. Desforges and S. Barrie (2002) Acoustic Phonon and Dressed Polariton Interaction in Dispersive and Photonic Band Gap Materials. PHYSICA B 316, 339-341.
33. M. Singh and Jean Desforges (2002), Excitons formation from spatially separated electrons and holes in semiconductor nanostructures with disorder. PHYSICA E 12, 327-330.
34. V. M. Yertsev and M. Singh (2002), Modeling of nonlinear optical properties of two-dimensional molecular aggregates. Synth. Metals 127, 115-120.
35. V. M. Yertsev and M. Singh (2002), Static Hyperpolarizabilities of 2D Molecular Aggregates. J. Chem. Physics, 276, 293-300.
36. J. Defroges and M. Singh (2001), Model simulations of excitons in semiconductor nanostructures at high concentrations and strong disorder. SOLID STATE COMMUN. 119, 45-49.
37. M. Singh and S. Barrie (2001), Spin flopping in the quasi-two dimensional magnetic systems: Application to Y-Ba-Cu-O compounds. J. of Mag. and Mag. Materials 226,346-347.
