T.J. Wang, K.S. Lam, Q. Liu, X.M. Wang
.
DOI: 10.4236/acs.2011.11002   PDF    HTML     4,638 Downloads   9,315 Views   Citations

Abstract

Time series of daily UV radiation measured by the ground-based Brewer spectrophotometer #115 in Hong Kong during 1995-2005 were studied through statistics analysis, with focus on the variability and long term changes in relation to total ozone, clouds and AOD (Aerosol Optical Depth). The 11-year mean UV daily dose is 2644±262 J/m2, with maxima(3311 J/m2) in 2000 and minima (2415 J/m2) in 2002. The data were compared with that from TOMS (Total Ozone Mapping Spectrometer) Version 8 and show general agreement between the two. However, the Brewer UV measurement is about 10% lower compared to TOMS data. Apart from the common-known strong seasonal cycle, 26 month periodical was resolved by use of wavelet analysis, which was believed to be associated with quasi-biennial oscillation (QBO) of general circulation. In cloudy days, the annual mean UV daily dose decrease 3.5% to 44.5% compared to clear days. It was also found that surface UV irradiance has close relation to air pollution. Under clear sky condition, 1% AOD increase will lead to 0.2% UV decrease. While global UV radiation increase due to the worldwide observed ozone depletion, investigations indicate that this trend is not significant in Hong Kong during the last 11 years. The possible causes can be attributed to the compensative effect from two aspects. One is the increase of UV resulting from the reduction of clouds with rate of 0.56/10 yr. The other is the decrease of UV due to the enhancement of total ozone and AOD with a rate of 4.23 DU/10 yr and 0.33/10 yr, respectively.

Keywords

UV Radiation, Brewer Spectrophotometer, TOMS, Hong Kong

Share and Cite:

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	H. Slaper, M. Velders, J. S. Daniel, F. R. Degruijl and J. C. Vanderleun, “Estimates of ozone depletion and skin cancer incidence to examine the Vienna convention achievement,” Nature, Vol. 384, No. 6606, 1996, pp. 256-258.
[2]	K. S. Lam, A. J. Ding, L. Y. Chan, T. Wang, and T. J. Wang, “Ground Based Measurements of Total Ozone and UV Radia-tion by the Brewer Spectrophotomer #115 at Hong Kong,” Atmospheric Environment, Vol. 36, 2002, pp. 2003-2012.
[3]	Y. W. Chan, “A study of the characteristics of ultraviolet radiation in Hong Kong,” Radiation Protection Do-simetry, Vol. 91, No. 1-3, 2000, pp. 173-176.
[4]	C. K. Chui, “An introduction to wavelets,” Academic Press, 1992, p. 266.
[5]	J. J. Benedetto and M. W. Frazier, “Wavelets: ma-thematics and applications,” CRC Press, 1994, p. 575.
[6]	G. Kaiser, “A friendly guide to wavelets,” Birkhaser, 1994, p. 300.
[7]	WMO, “Scientific assessment of ozone depletion,” Global Ozo ne Res. Monit. Project, Geneva, 2002 p. 47498.
[8]	W. R. Burrows, M. Vallee and J. B. Wardle, “The Canadian Operational Procedure for Forecasting Total Ozone and UV Radiation, Meteorological Applications,” Vol.1, pp. 247-265.
[9]	R. E. Hester and R. M. Harrison, “Cause and environmental implications of increased UV-B radiation,” Published by the Royal Society o Chemistry, Thomas Graham House. 20-22, 2000.
[10]	G. G. Palancar and B. M. Toselli, “Effects of metrology and tropospheric aerosols on UV-B radi-ation: a 4-year study, ” Atmospheric Environment, Vol. 38, 2004, pp. 2749-2757.
[11]	K. Buttner, “Physik. Bioklimat, quoted in M. L. Nack & Green, A. E. S., 1974. Influence of clouds, haze, and smog on the middle ultraviolet reaching the ground,” Appl. Optics, Vol. 13, No. 10, 1938, pp. 2405-2415.
[12]	F. Carvalho and D. Henriques, “Use of Brewer Ozone Spectrophotometer for Aerosol Optical Depth Measurements on Ultraviolet Region,” Adv. Space Res, Vol. 25, No. 5, 2000, pp. 997-1006.
[13]	den Outer, P. N. Slaper and R. B. Tax, “UV radiation in the Netherlands: Assessing long-term variability and trends in relation to ozone and clouds,” Journal of Geophysical Research, Vol. 110, No. D02203, 2005. doi:10.1029/2004JD004824,2005
[14]	J. Grobner and C. Me-leti, “Aerosol optical depth in the UVB and visible wavelength range from Brewer spectrophotometer direct irradiance mea-surements: 1991-2002,” Journal of Geophysical Research, Vol. 109, No. D09202, 2004. doi:10.1029/2003JD004409,2004
[15]	F. Marenco, A. Di Sarra and D. J. Luisi, “Methodology for determining aerosol optical depth from Brewer 300-320 nm ozone measurements,” Applied Optics, Vol. 41, No. 9, pp. 1805-1814, 2002.