Abstract

Abstract. Satellite data from the Ozone Measuring Instrument (OMI) and Earth Polychromatic Imaging Camera (EPIC) are used to study long-term changes and global distribution of UV erythemal irradiance E(ζ,φ,z,t) (mW m−2) and the dimensionless UV index E ∕ (25 m Wm−2) over major cities as a function of latitude ζ, longitude φ, altitude z, and time t. Extremely high amounts of erythemal irradiance (12 < UV index <18) are found for many low-latitude and high-altitude sites (e.g., San Pedro, Chile, 2.45 km; La Paz, Bolivia, 3.78 km). Lower UV indices at some equatorial or high-altitude sites (e.g., Quito, Ecuador) occur because of persistent cloud effects. High UVI levels (UVI > 6) are also found at most mid-latitude sites during the summer months for clear-sky days. OMI time-series data starting in January 2005 to December 2018 are used to estimate 14-year changes in erythemal irradiance ΔE, total column ozone ΔTCO3, cloud and haze transmission ΔCT derived from scene reflectivity LER, and reduced transmission from absorbing aerosols ΔCA derived from absorbing aerosol optical depth τA for 191 specific cities in the Northern Hemisphere and Southern Hemisphere from 60∘ S to 60∘ N using publicly available OMI data. A list of the sites showing changes at the 1 standard deviation level 1σ is provided. For many specific sites there has been little or no change in E(ζ,φ,z,t) for the period 2005–2018. When the sites are averaged over 15∘ of latitude, there are strong correlation effects of both short- and long-term cloud and absorbing aerosol change as well as anticorrelation with total column ozone change ΔTCO3. Estimates of changes in atmospheric transmission ΔCT (ζ, φ, z, t) derived from OMI-measured cloud and haze reflectivity LER and averaged over 15∘ of latitude show an increase of 1.1±1.2 % per decade between 60 and 45∘ S, almost no average 14-year change of 0.03±0.5 % per decade from 55∘ S to 30∘ N, local increases and decreases from 20 to 30∘ N, and an increase of 1±0.9 % per decade from 35 to 60∘ N. The largest changes in E(ζ,φ,z,t) are driven by changes in cloud transmission CT. Synoptic EPIC radiance data from the sunlit Earth are used to derive ozone and reflectivity needed for global images of the distribution of E(ζ,φ,z,t) from sunrise to sunset centered on the Americas, Europe–Africa, and Asia. EPIC data are used to show the latitudinal distribution of E(ζ,φ,z,t) from the Equator to 75∘ for specific longitudes. EPIC UV erythemal images show the dominating effect of solar zenith angle (SZA), the strong increase in E with altitude, and the decreases caused by cloud cover. The nearly cloud-free images of E(ζ,φ,z,t) over Australia during the summer (December) show regions of extremely high UVI (14–16) covering large parts of the continent. Zonal averages show a maximum of UVI = 14 in the equatorial region seasonally following latitudes where SZA = 0∘. Dangerously high amounts of erythemal irradiance (12 < UV index < 18) are found for many low-latitude and high-altitude sites. High levels of UVI are known to lead to health problems (skin cancer and eye cataracts) with extended unprotected exposure, as shown in the extensive health statistics maintained by the Australian Institute of Health and Welfare and the United States National Institute of Health National Cancer Institute.

Highlights

  • Calculated and measured amounts of UV radiation reaching the Earth’s surface can be used as a proxy to estimate the combined effects of changing ozone, aerosols, and cloud cover on human health

  • This paper presents calculated noontime E(ζ, φ, z, t) time series and estimated least squares (LS) trends (2005–2018) from a multivariate linear regression model (Randel and Cobb, 1994) for globally distributed locations at different latitudes ζ, longitudes φ, altitudes z, and time t, most of which are centered over heavily populated areas such as New York City, Seoul, Korea, and Buenos Aires based on measurements of the relevant parameters from Ozone Measuring Instrument (OMI)

  • This study presents a global view based on satellite observations (OMI and Earth Polychromatic Imaging Camera (EPIC)) of the amount and changes for erythemal irradiance over major cities that are affected by ozone, clouds plus scattering aerosols, absorbing aerosols, and terrain height

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Summary

Introduction

Calculated and measured amounts of UV radiation reaching the Earth’s surface can be used as a proxy to estimate the combined effects of changing ozone, aerosols, and cloud cover on human health. Erythemal irradiance (E) is usually measured or calculated in energy units (mW m−2) or in terms of the UV index UVI = E / (25 mW m−2), reaching the Earth’s surface after passing through atmospheric absorbing and scattering effects from ozone, aerosols, and clouds. Lindfors et al (2009) published a global erythemal analysis based on pseudo-spherical radiative transfer that includes absorbing aerosol optical depth τA from a climatology and combined ozone and cloud data from multiple satellites. This means that the already low amounts of erythemal irradiance during high solar zenith angle winter months for high-latitude cities are further underestimated

UV-absorbing aerosols
Comparison with previous results
Erythemal time series and LS linear trends
Multivariate linear regression model for calculating LS trends
Northern Hemisphere
Equatorial region
Southern Hemisphere
Findings
Summary

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