Admission open in MBA & BBA program for AY 2021-22

Jaypee Institute of Information Technology, Noida
  • Home
  • Prof. Navneet Kumar Sharma
Professor
navneetk.sharma@jiit.ac.in, nk.sharma2004@gmail.com

Education

M.Sc. (UOR Roorkee), Ph.D. (IIT Delhi)

Work Experience : Research experience = 19.5 Years, Teaching Experience=15.5 Years

Biography

Navneet Kumar Sharma is currently working as Professor in department of Physics and Materials Science and Engineering, JIIT, Noida. He did M.Sc. in Physics (specialization in Engineering Physics) from University of Roorkee (now IIT Roorkee) in 1997 and Ph.D. from IIT Delhi in 2004. At present, he is actively involved in teaching and research related to various aspects of SPR based fiber optic sensors, plasmonics and photonics. He has guided three Ph.D. students.

Professional Achievement:

  • NET, GATE

Project Details:

  • Project Title: Experimental investigations on surface plasmon resonance based fiber optic refractive index sensors
  • Project cost: Rs. 27.71 Lakh
  • Granting Agency: DRDO, India
  • Status: Ongoing
  • Duration: 03 years (2017-2020)

Publications:

International Journals

  • Kapoor V., and Sharma N. K. (2020). Surface plasmon resonance based fiber optic sensor prepared from bilayers of indium tin oxide-indium oxide. Microwave and Optical Technology Letters, 62, 2439-2443.
  • Mann, K. L., Sajal, V., Panwar, A., and Sharma, N. K. (2019). Excitation of terahertz radiation by parametric mixing of four waves in magnetized plasma. Optik, 186, 182-186.
  • Kapoor, V., Sharma, N. K., and Sajal V. (2019). Indium tin oxide and silver based fiber optic SPR sensor: an experimental study. Optical and Quantum Electronics, 51, 125.

  • Kapoor, V., Sharma, N. K., and Sajal V. (2019). Effect of zinc oxide overlayer on the sensitivity of fiber optic SPR sensor with indium tin oxide layer. Optik, 185, 464-468.

  • Mann, K. L., Sajal, V., Panwar, A., and Sharma, N. K. (2019). Excitation of terahertz radiation by parametric coupling of a laser beam and its frequency shifted second harmonic in a corrugated magnetized plasma. Optik, 179, 401-407.
  • Baliyan, S., Rafat, M., Panwar, A., Sharma, N. K., and Sajal, V. (2019). Suppression of stimulated Raman side-scattering of a laser in a plasma in presence of co-propagating electron beam. Optik, 179, 330-335.
  • Shah, K., Sharma, N. K., and Sajal V. (2018). Analysis of fiber optic SPR sensor utilizing platinum based nanocomposites. Optical and Quantum Electronics, 50, 265.
  • Shah, K., Sharma, N. K., and Sajal, V. (2018). Simulation of LSPR based fiber optic sensor utilizing layer of platinum nanoparticles. Optik, 154, 530-537.
  • Mann, K. L., Sajal, V., Varshney, P., Sharma, N. K. (2017). Terahertz radiation generation by pulse slippage of Cosh-Gaussian lasers in a corrugated magnetized plasma. Physics of Plasmas, 24, 123117.
  • Mann, K. L., Sajal, V., Sharma, N. K. (2017). Excitation of terahertz radiation generation by obliquely incident beating lasers on a hot magnetized plasma with step density profile. Laser and Particle Beams, 35, 528-533
  • Shah, K., Sharma, N. K., and Sajal, V. (2017). SPR based fiber optic sensor with bi layers of indium tin oxide and platinum: A theoretical evaluation. Optik, 135, 50-56.
  • Sharma, N. K., Shukla, S. and Sajal, V. (2017). Surface plasmon resonance based fiber optic sensor using an additional layer of platinum: A theoretical study. Optik, 133, 43-50.
  • Verma, K., Baliyan, S., Sajal, V., Kumar, R., & Sharma, N. K. (2016). Parametric excitation of coupled fast and slow upper hybrid waves by counter-propagating circularly polarized lasers in a magnetized plasma. Physics of Plasmas, 23, 072123. 
  • Verma, K., Sajal, V., Kumar, R., & Sharma, N. K. (2016). Suppression of decay instability of the non-resonant beat wave excited by two counter-propagating x-mode lasers in magnetized plasma. Physics of Plasmas, 23, 012109.
  • Shukla, S., Sharma, N. K., & Sajal, V. (2016). Theoretical analysis of surface plasmon resonance based fiber optic sensor using ITO and ZnO thin films. Optical and Quantum Electronics, 48, 57.
  • Shah, K., Shukla, S., Sharma N. K., & Sajal, V. (2016). Theoretical study of surface plasmon resonance based fiber optic sensor utilizing an additional layer of zinc oxide. Optik, 127, 5743-5749.
  • Shukla, S., Sharma, N. K., & Sajal, V. (2016). Theoretical study of surface plasmon resonance based fiber optic sensor utilizing cobalt and nickel films. Brazilian Journal of Physics, 46, 288-293.
  • Shukla, S., Rani, M., Sharma, N. K., & Sajal, V. (2015). Sensitivity enhancement of a surface plasmon resonance based fiber optic sensor utilizing platinum layer. Optik, 126, 4636-4639.
  • Verma, K., Sajal, V., Baliyan, S., Kumar, R., & Sharma, N. K. (2015). Stimulated Brillouin side-scattering of the beat wave excited by two counter-propagating x-mode lasers in magnetized plasma. Physics of Plasmas, 22, 062106.
  • Varshney, P., Sajal, V., Singh, K. P., Kumar, R., & Sharma, N. K. (2015). Tunable and efficient terahertz radiation generation by photomixing of two super gaussian laser pulses in a corrugated magnetized plasma. Journal of Applied Physics, 117, 193303.
  • Shukla, S., Sharma, N. K., & Sajal, V. (2015). Sensitivity enhancement of a surface plasmon resonance based fiber optic sensor using ZnO thin film: a theoretical study. Sensors and Actuators B, 206, 463-470.
  • Varshney, P., Sajal, V., Baliyan, S., Sharma, N. K., Chauhan, P. K., & Kumar, R. (2015). Strong terahertz radiation generation by beating of two x-mode spatial triangular lasers in magnetized plasma. Laser and Particle Beams, 33, 51-58.
  • Verma, K., Sajal, V., Varshney, P., Kumar, R., & Sharma, N. K. (2014). Parametric excitation of fast upper hybrid waves by non-resonant beating of counter-propagating x-mode lasers in a magnetized plasma. Physics of Plasmas, 21, 122110.
  • Varshney, P., Sajal, V., Chauhan, P., Kumar, R., & Sharma, N. K. (2014). Effects of transverse static electric field on terahertz radiation generation by beating of two transversely modulated gaussian laser beams in a plasma. Laser and Particle Beams, 32, 375-381.
  • Rani, M., Shukla, S., Sharma, N. K., & Sajal, V. (2014). Theoretical analysis of surface plasmon resonance based fiber optic sensor using indium nitride. Optik, 125, 6026-6031.
  • Sharma, N. K., Yadav, S., & Sajal V. (2014). Theoretical analysis of highly sensitive prism based surface plasmon resonance sensor with indium tin oxide. Optics Communications, 318, 74-78.
  • Verma, K., Sajal, V., Varshney, P., Kumar, R., & Sharma, N. K.(2014). Stimulated Raman scattering of beat wave of two counter-propagating x-mode lasers in a magnetized plasma. Physics of Plasmas, 21, 022104.
  • Rani, M., Shukla, S., Sharma, N. K., & Sajal, V. (2014). Theoretical study of nanocomposites based fiber optic SPR sensor. Optics Communications, 313, 303-314.
  • Sharma, N. K., Rani, M., & Sajal V. (2013). Surface plasmon resonance based fiber optic sensor with double resonance dips. Sensors and Actuators B, 188, 326-333.
  • Rani, M., Sharma, N. K., & Sajal V. (2013). Surface plasmon resonance based fiber optic sensor utilizing Indium oxide. Optik, 124, 5034-5038.
  • Varshney, P., Sajal, V., Singh K. P., Kumar, R., & Sharma, N. K.(2013). Strong terahetz radiation generation by beating of extra-ordinary mode lasers in a rippled density magnetized plasma. Laser and Particle Beams, 31, 337-344.
  • Rani, M., Sharma, N. K., & Sajal, V. (2013). Localized surface plasmon resonance based fiber optic sensor with nanoparticles. Optics Communications, 292, 92-100.
  • Sajal, V., Sharma, N. K., Kumar, R., & Tripathi, V. K. (2012). Stimulated Raman backward scattering of a laser beam in a magnetized plasma. Optics Communications, 285, 3563-3566.
  • Sharma, N. K., & Pathak, A. (2009). Bosonic Channel Capacity of a Nonlinear Dispersive Optical Fiber. Applied Mathematics and Information Sciences, 3(2), 151-158.
  • Verma, A., Sharma, N. K., & Pathak, A. (2008). Higher order antibunching in intermediate states. Physics Letters A, 372, 5542-5551.
  • Sharma, N. K., & Gupta, B. D. (2004). Fabrication and Characterization of a fiber optic pH Sensor for the pH Range 2 to 13. Fiber and Integrated Optics, 23, 327-335.
  • Sharma, N. K., & Gupta, B. D. (2003). Fabrication and Characterization of pH sensor based on side polished single mode optical fiber. Optics Communications, 216, 299-303.
  • Gupta, B. D., & Sharma, N. K. (2002). Fabrication and Characterization of U-shaped fiber optic pH probes. Sensors and Actuators B, 82, 89-93.

National Journals

  • Sharma, N. K. (2012). Performances of different metals in optical fiber based surface plasmon resonance sensor. Pramana, 78, 417-427.
  • Sharma, N. K., & Gupta, B. D. (2003). U-shaped fiber optic pH sensor: effect of temperature and ionic strength. Asian Journal of Physics, 12, 225-231

International Conferences

  • Kapoor, V., and Sharma, N. K. (2020). Fiber optic SPR sensing using zinc oxide. Materials Today: Proc., Noida, India, 28, 14-15.
  • Kapoor, V., and Sharma, N. K. (2019). SPR based fiber optic refractive index sensor. AIP Conf. Proc., Noida, India, 2136, 050003
  • Shah, K., and Sharma, N. K. (2018). Nanoparticles based fiber optic SPR sensor. AIP Conf. Proc., Bikaner, India, 1953, 060007.
  • Shah, K., and Sharma, N. K. (2018). SPR based fiber optic sensor utilizing thin film of nickel. AIP Conf. Proc., Noida, India, 2009, 020040.
  • Sharma, I., Gupta, P., and Sharma, N. K. (2018). Effect of focal length of convex lens on the intensity of spot size of He-Ne laser. ICIoTCT-2018,Jaipur, India.
  • Mathur, T., and Sharma, N. K. (2018). Diffraction grating based surface plasmon resonance sensor. ICEECE-2018,New Delhi,India.
  • Shukla, S., & Sharma, N. K.(2016). Indium oxide based fiber optic SPR sensor. AIP Conf. Proc.,Bikaner, India, 1728, 020036.
  • Shukla, S., Mishra, S. K., Pathak, A., Gupta, B. D., & Sharma, N. K. (2014). Surface plasmon resonance based fiber optic hydrogen sulphide gas sensor utilizing titanium dioxide thin film. PHOTONICS-2014, Kharagpur, India.
  • Rani, M., & Sharma, N. K. (2014). Simulation of Cobalt based fiber optic surface plasmon resonance sensor. ICOL-2014, Dehradun, India.
  • Rani, M., & Sharma, N. K. (2013). ITO Based Fiber Optic SPR Sensor. AIP Conf. Proc., Bikaner, India, 1536, 1117-1118.
  • Sharma, N. K., Verma, A., Sen, B., & Pathak, A. (2011). Nonclassical properties Atom-Molecule BEC Revisited. ICQOQC-11, Noida, India.
  • Verma, A., Sharma, N. K., & Pathak, A. (2011). Nonclassical properties of intermediate states. ICQOQC-11, Noida, India.
  • Sharma, S., Kumar, D., Dasgupta, L., & Sharma, N. K. (2010). Structural and optical properties of TiO2 thin films grown by oblique angle deposition. PHOTONICS-2010, Guwahati, India.
  • Sharma, N. K., & Pathak, A. (2007). Nonclassical quantum fluctuation affects Bosonic channel capacity of quantum channel. International Conference on Fluctuations and Noise,Florence, Italy.
  • Sharma, N. K., & Gupta, B. D. (2003). Fiber Optic pH Sensor based on Evanescent Wave Absorption Spectroscopy. ICLAOM-03, Delhi, India.
  • Gupta, B. D., & Sharma, N. K.(2002). U-shaped fiber-optic pH sensor prepared by Dye doped sol-gel immobilization technology. PHOTONICS-2002, Mumbai, India.

National Conferences

  • Sharma, S., Kumar, D., Dasgupta, L., & Sharma, N. K. (2010). Effect of oblique angle deposition on optical properties of optical thin films TiO2. RAMSE-2010, Raghogarh–Guna, India.