Theory to apply Raman spectroscopy and infra red emission spectroscopy
for pollution control has been presented.
This theory applies wave numbers with strong intensities obtained in
outputs of these two spectroscopy methods to find energies required to
decompose materials. It has been
suggested that this theory should be applied as a quality checking in
production of materials to control pollution over materials which need
decomposition.
[1] Fujioka, Y. Infrared Emission Spectroscopy and Its Application to Analyze Non-smooth Metallic Materials Surface.
[2] Long, D. A. (2002). The raman effect. Wiley.
[3] Moorthy, C. Ganesa; Sankar, G. Udhaya. (2018). Planets And Electromagnetic waves. Idea Publishing, 1-110
[4] Moorthy, C. G., Sankar, G. U., & RajKumar, G. (2017). A Design for Charging Section of Electrostatic Precipitators by Applying a Law for Electric Field Waves. Imperial Journal of Interdisciplinary Research, 3(6).
[5] Moorthy, C. G., Sankar, G. U., & Rajkumar, G. (2017). Two Expressions for Electrostatic Forces and For Magnetic Forces to Classify Electromagnetic Waves. Imperial Journal of Interdisciplinary Research, 3(10).
[6] Moorthy, C. G., Sankar, G. U., & RajKumar, G. (2017). LIGOs Detected Magnetic Field Waves; not Gravitational Waves. Imperial Journal of Interdisciplinary Research, 3(8).
[7] Moorthy, C. G., Sankar, G., & Rajkumar, G. (2017). Simplified Interpretation for Einstein’s Energy Mass Relation. Imperial Journal of Interdisciplinary Research.
[8] Moorthy, C. G., Sankar, G. U., & RajKumar, G. (2018). Temperature of Black Holes and Minimum Wavelength of Radio Waves.
[9] Moorthy, C. Ganesa, G. Udhaya Sankar, and Graj Kumar. "What Is The Polarity Of An Electromagnetic Wave?." Indian J. Sci. Res 13.1 (2017): 255-256.
[10] RajKumar, G., Moorthy, C. G., & Sekar, S. (2018). New Design for Charging Section of Electrostatic Precipitators Using Thermocouple Principle for Air Pollution Control. Int. J. of Environmental Pollution & Environmental Modelling, 1(4), 116-119.
[11] Ewen, S., & Geoffrey, D. (2005). Modern Raman spectroscopy: a practical approach. New York: John Wiler & Sons.
[12] Stuart, B. H. (2004). Experimental methods. Infrared Spectroscopy: Fundamentals and Applications; John Wiley & Sons: Hoboken, NJ, USA, 18-19.
[13] Tsuchida, A., Kawazumi, H., Kazuyoshi, A., & Yasuo, T. (2009, October). Identification of shredded plastics in milliseconds using Raman spectroscopy for recycling. In SENSORS, 2009 IEEE (pp. 1473-1476). IEEE.
[14] Ayturan, Y. A., Öztürk, A., & Ayturan, Z. C. (2017). Modelling of PM10 Pollution in Karatay District of Konya with Artificial Neural Networks. Journal of International Environmental Application and Science, 12(3), 256-263.
[15] Udhaya Sankar, G., Ganesa Moorthy, C., & RajKumar, G. (2018). Synthesizing graphene from waste mosquito repellent graphite rod by using electrochemical exfoliation for battery/supercapacitor applications. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 40(10), 1209-1214.
[16] Moorthy, C. G., Sankar, G. U., & Rajkumar, G. (2016). Rotating Bodies Do Have Magnetic Field.
[17] Ayturan, Y., Ayturan, Z., & Altun, H. (2018). Air Pollution Modelling with Deep Learning: A Review. International Journal of Environmental Pollution and Environmental Modelling, 1(3), 58-62.
[18] Udhaya Sankar, G., Ganesa Moorthy, C., & RajKumar, G. (2018). A suggestion for a good anode material synthesized and characterized. Discov, 54, 249-253.
[19] Sankar, G. U. (2016). Climate change challenge–photosynthesis vs. hydro-electrolysis principle. Climate Change, 3, 128-131.
[20] Udhaya Sankar, G., Ganesa Moorthy, C., & RajKumar, G. (2019). Smart Storage Systems for Electric Vehicles–A Review. Smart Science, 7(1), 1-15.
[21] Vallikkodi, M., Sankar, G. U., & Vishnukumar, P. (2017). An Innovative Interpretation for Parallel Universe. Imperial Journal of Interdisciplinary Research, 3(5).
[22] MOORTHY, C. G., SANKAR, G. U., & KUMAR, G. A VELOCITY INDEX FOR EXISTENCE OF ATMOSPHERE IN A PLANET. Mercury, 4(47.4), 10-8937.
[23] Moorthy, C. G., Sankar, G. U., & Kumar, G. R. Why Do Distant Planets Have Speedy Winds?. Mercury, 3, 0-24055556.
[24] G.udhaya sankar, (2007). A Survey on Wavelength Based Application of Ultraviolet LED, computing.
[25] Moorthy, G., & Raj, I. (2013). Weak convergence of fixed point iterations in metric spaces. Journal of Nonlinear Analysis and Optimization: Theory & Applications, 4(2), 189-192.
[26] Moorthy, C. G. (1992). A problem of Good on Hausdorff dimension. Mathematika, 39(2), 244-246.
[27] Marikkannan, N., & Ganesamoorthy, C. (2008). On applications of differential subordination and superordination. Tamkang Journal of Mathematics, 39(2), 155-164.
Year 2019,
Volume: 2 Issue: 1, 44 - 47, 02.01.2019
[1] Fujioka, Y. Infrared Emission Spectroscopy and Its Application to Analyze Non-smooth Metallic Materials Surface.
[2] Long, D. A. (2002). The raman effect. Wiley.
[3] Moorthy, C. Ganesa; Sankar, G. Udhaya. (2018). Planets And Electromagnetic waves. Idea Publishing, 1-110
[4] Moorthy, C. G., Sankar, G. U., & RajKumar, G. (2017). A Design for Charging Section of Electrostatic Precipitators by Applying a Law for Electric Field Waves. Imperial Journal of Interdisciplinary Research, 3(6).
[5] Moorthy, C. G., Sankar, G. U., & Rajkumar, G. (2017). Two Expressions for Electrostatic Forces and For Magnetic Forces to Classify Electromagnetic Waves. Imperial Journal of Interdisciplinary Research, 3(10).
[6] Moorthy, C. G., Sankar, G. U., & RajKumar, G. (2017). LIGOs Detected Magnetic Field Waves; not Gravitational Waves. Imperial Journal of Interdisciplinary Research, 3(8).
[7] Moorthy, C. G., Sankar, G., & Rajkumar, G. (2017). Simplified Interpretation for Einstein’s Energy Mass Relation. Imperial Journal of Interdisciplinary Research.
[8] Moorthy, C. G., Sankar, G. U., & RajKumar, G. (2018). Temperature of Black Holes and Minimum Wavelength of Radio Waves.
[9] Moorthy, C. Ganesa, G. Udhaya Sankar, and Graj Kumar. "What Is The Polarity Of An Electromagnetic Wave?." Indian J. Sci. Res 13.1 (2017): 255-256.
[10] RajKumar, G., Moorthy, C. G., & Sekar, S. (2018). New Design for Charging Section of Electrostatic Precipitators Using Thermocouple Principle for Air Pollution Control. Int. J. of Environmental Pollution & Environmental Modelling, 1(4), 116-119.
[11] Ewen, S., & Geoffrey, D. (2005). Modern Raman spectroscopy: a practical approach. New York: John Wiler & Sons.
[12] Stuart, B. H. (2004). Experimental methods. Infrared Spectroscopy: Fundamentals and Applications; John Wiley & Sons: Hoboken, NJ, USA, 18-19.
[13] Tsuchida, A., Kawazumi, H., Kazuyoshi, A., & Yasuo, T. (2009, October). Identification of shredded plastics in milliseconds using Raman spectroscopy for recycling. In SENSORS, 2009 IEEE (pp. 1473-1476). IEEE.
[14] Ayturan, Y. A., Öztürk, A., & Ayturan, Z. C. (2017). Modelling of PM10 Pollution in Karatay District of Konya with Artificial Neural Networks. Journal of International Environmental Application and Science, 12(3), 256-263.
[15] Udhaya Sankar, G., Ganesa Moorthy, C., & RajKumar, G. (2018). Synthesizing graphene from waste mosquito repellent graphite rod by using electrochemical exfoliation for battery/supercapacitor applications. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 40(10), 1209-1214.
[16] Moorthy, C. G., Sankar, G. U., & Rajkumar, G. (2016). Rotating Bodies Do Have Magnetic Field.
[17] Ayturan, Y., Ayturan, Z., & Altun, H. (2018). Air Pollution Modelling with Deep Learning: A Review. International Journal of Environmental Pollution and Environmental Modelling, 1(3), 58-62.
[18] Udhaya Sankar, G., Ganesa Moorthy, C., & RajKumar, G. (2018). A suggestion for a good anode material synthesized and characterized. Discov, 54, 249-253.
[19] Sankar, G. U. (2016). Climate change challenge–photosynthesis vs. hydro-electrolysis principle. Climate Change, 3, 128-131.
[20] Udhaya Sankar, G., Ganesa Moorthy, C., & RajKumar, G. (2019). Smart Storage Systems for Electric Vehicles–A Review. Smart Science, 7(1), 1-15.
[21] Vallikkodi, M., Sankar, G. U., & Vishnukumar, P. (2017). An Innovative Interpretation for Parallel Universe. Imperial Journal of Interdisciplinary Research, 3(5).
[22] MOORTHY, C. G., SANKAR, G. U., & KUMAR, G. A VELOCITY INDEX FOR EXISTENCE OF ATMOSPHERE IN A PLANET. Mercury, 4(47.4), 10-8937.
[23] Moorthy, C. G., Sankar, G. U., & Kumar, G. R. Why Do Distant Planets Have Speedy Winds?. Mercury, 3, 0-24055556.
[24] G.udhaya sankar, (2007). A Survey on Wavelength Based Application of Ultraviolet LED, computing.
[25] Moorthy, G., & Raj, I. (2013). Weak convergence of fixed point iterations in metric spaces. Journal of Nonlinear Analysis and Optimization: Theory & Applications, 4(2), 189-192.
[26] Moorthy, C. G. (1992). A problem of Good on Hausdorff dimension. Mathematika, 39(2), 244-246.
[27] Marikkannan, N., & Ganesamoorthy, C. (2008). On applications of differential subordination and superordination. Tamkang Journal of Mathematics, 39(2), 155-164.
C., G. M. (2019). Application of Raman Spectroscopy to Pollution Control Using Wave Numbers. International Journal of Environmental Pollution and Environmental Modelling, 2(1), 44-47.
AMA
C. GM. Application of Raman Spectroscopy to Pollution Control Using Wave Numbers. Int. j. environ. pollut. environ. model. January 2019;2(1):44-47.
Chicago
C., Ganesa Moorthy. “Application of Raman Spectroscopy to Pollution Control Using Wave Numbers”. International Journal of Environmental Pollution and Environmental Modelling 2, no. 1 (January 2019): 44-47.
EndNote
C. GM (January 1, 2019) Application of Raman Spectroscopy to Pollution Control Using Wave Numbers. International Journal of Environmental Pollution and Environmental Modelling 2 1 44–47.
IEEE
G. M. C., “Application of Raman Spectroscopy to Pollution Control Using Wave Numbers”, Int. j. environ. pollut. environ. model., vol. 2, no. 1, pp. 44–47, 2019.
ISNAD
C., Ganesa Moorthy. “Application of Raman Spectroscopy to Pollution Control Using Wave Numbers”. International Journal of Environmental Pollution and Environmental Modelling 2/1 (January 2019), 44-47.
JAMA
C. GM. Application of Raman Spectroscopy to Pollution Control Using Wave Numbers. Int. j. environ. pollut. environ. model. 2019;2:44–47.
MLA
C., Ganesa Moorthy. “Application of Raman Spectroscopy to Pollution Control Using Wave Numbers”. International Journal of Environmental Pollution and Environmental Modelling, vol. 2, no. 1, 2019, pp. 44-47.
Vancouver
C. GM. Application of Raman Spectroscopy to Pollution Control Using Wave Numbers. Int. j. environ. pollut. environ. model. 2019;2(1):44-7.