Dr. Bansi Lal

Consultant
EasyGo Technologies, Hinjewadi, Pune, India

Highest Degree
Ph.D. in Physics from Indian Institute of Technology Kanpur, India

My URL
https://livedna.org/91.24640

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Area of Interest:

Physics
Photobiophysics
Heat and Mass Transfer
Semiconductor Materials
Computational Physics

Selected Publications

  1. Rani, S., B. Lal, S. Saxena and S. Shukla, 2019. Optical properties of TAG co-doped with Ce and Eu. Bull. Mater. Sci., Vol. 42. 10.1007/s12034-019-1829-x.
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  2. Rani, S., B. Lal, S. Saxena and S. Shukla, 2019. Modifications in the structural and optical properties of ZnO nanophosphor on doping with Tb. Nanosci. Nanotechnol.-Asia, 9: 353-361.
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  3. Kaur, P., S. Rani and B. Lal, 2019. Excitation dependent photoluminescence properties of ZnO nanophosphor. Optik, Vol. 192. 10.1016/j.ijleo.2019.162929.
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  4. Rani, S., B. Lal, S. Saxena and S. Shukla, 2017. Photoluminescence properties of Gd: ZnO nano phosphor. J. Sol-Gel Sci. Technol., 81: 586-592.
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  5. Rani, S., B. Lal, S. Saxena and S. Shukla, 2017. Investigations on the visible emission from ZnO nanophosphor co-doped with Ce, Eu and Tb. Mater. Today: Proc., 4: 9375-9379.
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  6. Rani, S., B. Lal, S. Saxena and S. Shukla, 2017. Excitation dependence of the photoluminescence of ZnO: Tb nanophosphor. AIP Conf. Proc., Vol. 1860, No. 1. 10.1063/1.4990305.
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  7. Singh, S. and B. Lal, 2010. Laser heated pedestal growth and characterization of the crystalline fibers of KDP doped L-arginine phosphate. J. Crystal Growth, 312: 443-446.
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  8. Singh, S. and B. Lal, 2010. Growth and characterization of a nonlinear optical crystal 2-hydroxy-3-methoxy-N-(2-chloro-benzyl)-benzaldehyde-imine. J. Crystal Growth, 312: 301-304.
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  9. Shabir, H., B. Lal and M. Rafat, 2010. Sol-gel synthesis of Eu3+: Tb3Al5O12 nanophosphor. J. Sol-Gel Sci. Technol., 53: 399-404.
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  10. Shabir, H., B. Lal and M. Rafat, 2010. A comparative study of the properties of terbium aluminum garnet powder sintered in air, vacuum and by laser irradiation. Ceramics Int., 36: 365-369.
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  11. Lal, B., S.K. Patro and S. Singh, 2010. Nano-sized polycrystalline bismuth silicon oxide powder by sol-gel technique. J. Sol-Gel Sci. Technol., 56: 340-344.
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  12. Shabir, H., B. Lal and M. Rafat, 2009. Synthesis and photoluminescence properties of nanocrystalline terbium aluminium garnet phosphor. Int. J. Nano Biomater., 2: 416-424.
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  13. Singh, S. and B. Lal, 2008. Crystalline fiber growth of dye-doped L-arginine phosphate by the laser-heated pedestal growth technique. J. Crystal Growth, 310: 2039-2042.
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  14. Saxena, S. and B. Lal, 2007. Citrate-nitrate route for the synthesis and characterization of TAG using sol-gel techniques. J. Sol-Gel Sci. Technol., 41: 245-248.
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  15. Lal, B., F.Y. Yueh and J.P. Singh, 2005. Laser induced breakdown spectroscopy for quality control in pharmaceuticals industry. J. Optics, 34: 181-192.
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  16. Lal, B., F.Y. Yueh and J.P. Singh, 2005. Glass-batch composition monitoring by laser-induced breakdown spectroscopy. Applied Optics, 44: 3668-3674.
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  17. Lal, B., H. Zheng, F.Y. Yueh and J.P. Singh, 2004. Parametric study of pellets for elemental analysis with laser-induced breakdown spectroscopy. Applied Optics, 43: 2792-2797.
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  18. Lal, B., 1999. Laser heated pedestal growth technique for growing single crystal fibers. J. Opt., 28: 69-69.

  19. Lal, B. and K.V. Rao, 1998. Preparation of single crystal fibers using a CO2 laser. Metals Mater. Processes, 10: 231-236.

  20. Lal, B., 1996. Laser biostimulation. Phys. Educ., 12: 362-362.

  21. Lal, B., 1995. Lasers in surgery. Phys. Educ., 12: 116-116.

  22. Lal, B., 1994. Lasers in plastic industry. J. Plastic Ind., 11: 87-87.

  23. Lal, B., 1994. A simple experimental setup to measure fluorescent decay times. Phys. Educ. (Madras), 11: 87-89.
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  24. Lal, B., B. Rai and P. Venkateswarlu, 1985. Fabrication of a simple rare gas ion laser. J. Instrument Soc. India, 15: 207-207.

  25. Rao, D.N., B. Lal and P. Venkateswarlu, 1980. Fluorescence and excitation spectra of BaF2Ho3+ single crystal. Indian J. Phys., 54: 286-292.
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  26. Lal, B., 1980. Laser excited fluorescence spectra of Ho3+: SrF2. Indian J. Phys., 54: 88-88.

  27. Lal, B. and D.R. Rao, 1979. Multiphoton relaxations in the Ho3+: LaF3 single crystal. J. Phys. Chem. Solids, 40: 97-97.

  28. Lal, B. and D.R. Rao, 1979. An experimental set-up using laser for measurement of fluorescence lifetimes. Indian J. Pure Applied Phys., 17: 798-798.

  29. Lal, B. and D.R. Rao, 1978. Fluorescence and lifetime studies of Ho3+: CaF2. Chem. Phys. Lett., 53: 250-254.
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  30. Lal, B. and D.R. Rao, 1978. Absorption and laser excited fluorescence of Ho3+: LaF3. Pramana, 10: 467-475.
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  31. Rao, D.R., U.V. Kumar, B. Lal and P. Venkateswarlu, 1976. Conversion of a spectrograph into a recording spectrophotometer for fluorescence study. J. Instrument Soc. India, 6: 5-5.
Member since July, 2018