Solar Blue Light Radiation Enhancement during Mid to Low Solar Elevation Periods under Cloud Affected Skies.

Alfio V Parisi,Nathan J Downs,Damien P Igoe,Abdurazaq Amar

doi:10.3390/s20154105

Alfio V Parisi, Nathan J Downs + Show 2 more

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https://doi.org/10.3390/s20154105

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Abstract

Solar blue-violet wavelengths (380−455 nm) are at the high energy end of the visible spectrum; referred to as “high energy visible” (HEV). Both chronic and acute exposure to these wavelengths has been often highlighted as a cause for concern with respect to ocular health. The sun is the source of HEV which reaches the Earth’s surface either directly or after scattering by the atmosphere and clouds. This research has investigated the effect of clouds on HEV for low solar elevation (solar zenith angles between 60° and 80°), simulating time periods when the opportunity for ocular exposure in global populations with office jobs is high during the early morning and late afternoon. The enhancement of “bluing” of the sky due to the influence of clouds was found to increase significantly with the amount of cloud. A method is presented for calculating HEV irradiance at sub-tropical latitudes from the more commonly measured global solar radiation (300–3000 nm) for all cases when clouds do and do not obscure the sun. The method; when applied to global solar radiation data correlates well with measured HEV within the solar zenith angle range 60° and 80° (R2 = 0.82; mean bias error (MBE) = −1.62%, mean absolute bias error (MABE) = 10.3% and root mean square error (RMSE) = 14.6%). The technique can be used to develop repeatable HEV hazard evaluations for human ocular health applications

Highlights

The blue region (380−500 nm) of the visible waveband possesses the highest energy within the scotopic limits of human vision
The shorter blue-violet wavelengths within this range (380−455 nm) are sometimes referred to as high energy visible (HEV) radiation [1,2]
The validation of the model developed in this research for low solar elevation angles during the early morning and late afternoon when a significant part of the population are going to work or taking children to school shows that the mean bias error (MBE) values were very similar to those developed for the ultraviolet radiation (UV) waveband

Summary

Introduction

The blue region (380−500 nm) of the visible waveband possesses the highest energy within the scotopic limits of human vision. The shorter blue-violet wavelengths within this range (380−455 nm) are sometimes referred to as high energy visible (HEV) radiation [1,2]. The action spectrum for blue light hazard peaks at approximately 440 nm [3,4] and is associated with what is frequently referred as the “blue light hazard”. In contrast to blue-violet wavelengths that have higher energy, the green-yellow wavelengths associated with photopic vision have lower energy as the photopic action spectrum peaks at about 555 nm. These wavelengths are beneficial to the regulation of human circadian rhythms and colour perception [2]. As this research does not measure retinal injury, the term “HEV” will be used throughout

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