Teaching 2011/12

• Physics 9812A

Research Interests

More Information

• Students and Scientists
• Work Experience
• Recently Organized Conferences
  (2006 - present)
• Invited Speaker
  (2006 - present)
• Administrative Positions

Publications

• 2007 - present
• 2002 - 2005
• 1997 - 2001
• 1990 - 1996
• 1981 - 1989
• 1970 - 1980

Publications: 2002 - 2005

 

1)     M. Singh (2004), Giant refractive index enhancement in dispersive polaritonic band-gap and photonic band-gap materials. Phys. Rev. A 69, 023807-15:

2)     M. Singh (2004), Anomalous electromagnetically induced transparency in photonic band gap materials. Phys. Rev. A 70, 033813-20

3)     D. Mukherji and M. Singh (2004), Theory of non-linear susceptibility in polaritonic band-gap materials doped with multi-level atoms, Phys. Stat. Solidi C (accepted).

4)     M. Singh (2004), A study of electromagnetically induced transparency in photonic and dispersive band-gap materials, Phys. Stat. Solidi C (accepted).

5)     M. Singh and I. Haque (2004), Numerical simulations of photon trapping in photonic crystals doped with multi-level atoms, Phys. Stat. Solidi C (accepted).

6)     M. Singh (2004), The effect of electric and magnetic fields on polaron hopping in DNA structures, Phys. Stat. Solidi C (accepted).

7)     M. Singh (2004), Hopping conduction in DNA nucleotides and nucleosides, Phil. Mag. B.

8)  M. Singh (2004), Polaron transport mechanism in DNA.  J. Biomat. Sc. 15(11), 1533-1544.

9)  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)(accepted).

10)  M. Singh and I. Haque (2004), Coherent photon trapping in photonic materials, J. Mod. Optics (in press).

11)  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

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)  S.P. Singh, M. Singh and B. Watson (2004), KY Fan’s best application approximation theorem and application, Fixed Point Theory, 5, 131-136.

14)  M Singh (2004), Transient linewidth in photonic crystals, SPIE Proc. (accepted).

15)  M. Singh and R. Nistor (2004), Transient absorption in polaritonic crystals.  SPIE Proc. (accepted).

16)  I. Haque and M. Singh (2004), Dipole-dipole interaction in photonic crystals. SPIE Proc. (accepted).

17)  I. Haque and M. Singh (2004), Coherent photon trapping in doped photonic crystals and dispersive semiconductor materials, 27th Int. Conference on the Physics of Semiconductors (AIP) (in press).

18)  M. Singh and I. Haque (2004), A theory of photon trapping in photonic band-gap materials, ISAAC Conf. Proc. (Kluwer Academic Publishers, New York) (in press).

19)  D. Mukherji and M. Singh (2004), Nonlinear susceptibility in photonic crystals, ISAAC Conf. Proc. (Kluwer Academic Publishers, New York) (in press).

20)  M Singh (2004), Transient linewidth in photonic crystals, SPIE Proc. (accepted).

21)  M. Singh (2003), Transient line width narrowing in photonic and dispersive crystals, Phys. Rev. A.

22)  M. Singh (2003), Polariton stark effect in dispersive and photonic materials, Physica B, 337, 266-274.

23)  J. Desforges and M. Singh (2003), Magneto-excitons from spatially separated electron-hole systems in semiconductor nanostructures with disorder, Physica E, 17, 215-216.

24)  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.

25)  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.

26)  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.

27)  V.M. Yartsev, M. Singh and J. Desforges (2003), Excitons in semiconductor nanostructures, Rev. Mexicana de Fisica, 49, 1.

28)  M. Singh (2003), Quantum beat phenomenon due to polaritons in dispersive and photonic band-gap materials, J. Mod. Optics, 50, 1319-1325.

29)  S.P. Singh and M. Singh (2002), Some results on variational inequalities, J. Math. Sciences, 2, 5-10.

30)  M. Singh (2003), The electric field dependence dispersive transport of carriers in band tails of low-dimensional systems, Phil. Mag., 86, 797-805.

31)  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

32)  M. Singh and J. Desforges (2002), Excitons formation from spatially separated electrons and holes in semiconductor nanostructures with disorder, Physica E, 12, 327-330.

33)  J. Desforges and M. Singh (2002), Effect of magnetic field on excitons in bulk and heterostructure semiconductors containing disorder. Phys. Rev. B 66, 073310-14.

34)  A. Botha and M. Singh (2002), The effect of band anisotropy on the spin tunneling in type II semiconductor nanostructures, Phys. Stat. Solidi B, 231, 437-445.

35)  V.M. Yartsev and M. Singh (2002), Static hyperpolarizabilities of 2D molecular aggregates, J. Chem. Physics, 276, 293-300.

36)  V.M. Yartsev and M. Singh (2002), Modeling of nonlinear optical properties of two-dimensional molecular aggregates, Synth. Metals, 127, 115-120.

37)  M. Singh, V.M. Yartsev, and J. Desforges (2002), Effect of hopping in localized excitons and drag current in disordered semiconductors, Proc. Int. Conf. Sem. Phys. (World Scientific, NJ), 344-348.

38)  A. Botha and M. Singh (2002), Anisotropic spin-resonance tunneling in asymmetric type II quantum wells nanostructures, Proc. Int. Conf. Sem. Phys. (World Scientific, NJ).