Page 74 - Special Topic Session (STS) - Volume 2
P. 74
STS459 Norshahida S. et al.
4. Lee, S.B., Bae, G.M., Lee, Y.M., Moon, K.C., & Choi, M. (2010). Correlation
between Light Intensity and Ozone Formation for Photochemical Smog
in Urban Air of Seoul. Aerosol and Air Quality Research, 10, 540–549
5. Ling, Z. H. Ling, Guo, H.,Lam, S. H. M.,Saunders, S. M., & Wang, T. (2014).
Atmospheric photochemical reactivity and ozoneproduction at two sites
in Hong Kong: Applicationof a Master Chemical Mechanism–
photochemicalbox model. Journal of Geophysical Research: Atmosphere,
119 (10),567-582
6. Rafia, A., Hassan, M. N., & Ibrahim, N. A. (2002). Review of air pollution
and health impact in Malaysia. Environmental Research, 71-77.
7. Ramli, N.A., Ghazali, N.A., & Yahaya, A.S. (2010). Diurnal fluctuations of
ozone concentrations and its precursors and prediction of ozone using
multiple linear regressions. Malaysian Journal of Environmental
Management, 11 (2), 57-69
8. Shaadan, N., Rosslan, R.R., Deni. S.M. & Ismail, A. The diurnal Ozone
dynamics profile at several locations in Selangor, Malaysia: A functional
data analysis approach. International Conference on Mathematics,
Engineering and Industrial Applications 2018 (ICoMEIA 2018). AIP
Conference Proceedings 2013, 010001 (2018).
https://doi.org/10.1063/1.5054199
9. Siti, R. A., Sharifah, N. S., Muhammad, F., Mohd, T. L., Emilia, Z. A., &
Praveena, S. M. (2015). The assessment of ambient air pollution trend in
Klang Valley, Malaysia. World Environment, 1-11.
10. Verma, N., Satsangi, K., & Kumari, K.M. (2015). Prediction of Ground
Level Ozone Concenrtration in Ambient Air using Multiple Regression
Analysis. J. Chem. Phys. Sci. 5(4), 3685-3696
63 | I S I W S C 2 0 1 9
