GE-I-8: Index – case study

The picture shows a man’s upper arm in focus. The man is lifting the sleeve of his T-shirt with two fingers. In contrast with the skin previously covered by the T-shirt, the part of the skin that has been exposed to sunlight looks very red.Click to enlarge
High UV radiation intensity can cause health-threatening sunburn.
Source: New Africa / stock.adobe.com

2023 Monitoring Report on the German Strategy for Adaptation to Climate Change

GE-I-8: Index – case study

UV radiation is the main cause of skin cancer. It is a disease to which annually more than 300,000 new people in Germany fall prey. Even at stations in lowland areas, almost for half the year, irradiation strengths (UVI ≥3) are reached which can cause sunburn for which sun protection is recommended. UV irradiation strength varies with latitude, altitude and the current weather scenario, especially cloud cover.

The bar chart GE-I-8 ’UV Index – case study’ indicates by means of two axes, for the years of 2016 to 2021, the annual number of days with UV burdens of UVI ≥3, in other words, a UV Index of up to 3 on one hand, and on the other hand, the respective number of days with high UV burdens of UVI ≥8, the annual number of days with a UV Index of up to 8.
GE-I-8: Index – case study
Source: BfS (UV monitoring network)

UV radiation

UV radiation is the energy-richest part of optical radiation and cannot be seen by the human eye. In healthy humans, UV radiation initiates the important vitamin D production by the body. At the same time, however, it can lead to serious medical conditions which may manifest either directly or at some later stage in life, both in the eyes and in the skin32. UV radiation damages the genetic material. It is the main cause of skin cancer and has been assigned by the IARC (International Agency for Research on Cancer) to the highest risk category, Group 1, as ‘carcinogenic to humans’33. UV-related cancerous conditions constitute a major stress on the health of the person affected, and they inflict high expenditure on the public health service34. In Germany the incidence of light skin cancer (both in terms of basal cell and squamous cell carcinoma) quadrupled in respect of men over the past 30 years, whilst it quintupled in respect of women. With regard to malignant melanoma, the incidence has increased approximately fourfold since the 1970s35 35 According to extrapolations from data collected by the Hautkrebsregister (Skin Cancer Registry) of Schleswig-Holstein, currently every year some 300,000 people are newly diagnosed with skin cancer in Germany36.

UV-related damage to health can basically afflict anyone. In particular children are affected, as their skin and eyes are more sensitive to UV radiation than adults. Likewise people who work outdoors, thus being exposed more long-term, are subject to a high risk. At any age, sunburn will increase the risk of malignant melanoma roughly twofold – in childhood even two- to threefold. Damage caused by UV radiation will cumulate over a lifetime37.

Although the depletion of the stratospheric ozone layer arising from anthropogenic influences increases the UV irradiation close to the ground, it is of less importance for UV burdens in Germany. Nevertheless, the recovery of the ozone layer seems to be delayed on account of several influential factors. For the northern hemisphere, a return to ozone column values as experienced in 1980 is to be expected approximately by 203538. Furthermore, so-called ‘low ozone events’ can occur which can cause unexpectedly high UV irradiation strengths lasting for just a few days. The origin of this phenomenon may be sought year-round in dynamic processes in the atmosphere and, especially in spring, in the wintry ozone depletion above the arctic39 39 39. Low-ozone events in spring are particularly relevant in terms of health, as the human skin is still especially sensitive to UV radiation at that time of year. At the end of March / early April in 2020, for example, the UV index in southern Germany (Munich) increased from 3 to 6, owing to such a low-ozone event combined with the weather pattern prevailing at the time40. A study has indicated that the frequency of low-ozone events in spring has decreased over the past two decades41. At the same time, this study demonstrates that spring seems to be the season which is most affected by low-ozone events. As far as the development of low ozone events in the northern hemisphere in the future progress of the 21st century is concerned, no uniform findings have yet emerged from this study42 42 42.

In Germany the number of sunshine hours has changed in the course of recent decades. Until the 1980s, in Germany and the entire northern hemisphere, a continuous decrease in sunshine hours (1951–1980 by roughly 11 %, linear trend) was recorded43. The reason for this so-called global dimming’ effect is attributed to the increasing contamination of the atmosphere with industrial gas emissions and the associated formation of clouds44. Approximately since the middle of the 1980s, the aerosol concentration has decreased in Germany, thanks to the successful implementation of air pollution control measures45, followed by an increasing number of annual sunshine hours (1981–2022 by roughly 19 %). This ‘global brightening’ effect is essentially due to a successful international air pollution control policy rather than representing a direct impact of climate change46 46. The basic relationship between a change in radiation intensity and climate change is currently an important focal point of research. For example, data collected in the period of 1996 to 2017 at four European stations show that long-term changes in UV radiation depend, above all, on changes in aerosols, cloud cover and surface reflexion capacity (albedo)47.

The intensity of UV radiation is indicated in terms of the UV index (UVI) – a worldwide homogeneous standard for the daily peak value expected to be measured at ground level (30-minute mean) of the UV irradiation strength capable of causing sunburn48.The higher the UVI, the higher the UV irradiation strength and the faster sunburn can develop on unprotected skin.

The case study presented in this report is based on the values measured at measuring stations which are part of the UV measuring network. Taking the latitude into account (the UV Index increases from north to south) as well as the altitude (the UV Index is higher in mountains than in lowland areas), the stations have been assigned to four natural spaces. The illustration shows all days with UV values of 3 and more, given that from UV Index 3 upwards, it is already recommended to take measures for sun protection. Given that for a UV Index of 8, the recommendations for taking sun protection have been stepped up further, the days with UVI values equal to or higher than 8 are illustrated. For every station, the days with the relevant values for each year are totalled, and then the mean is calculated across the stations in the natural space concerned.

There are distinct regional differences. In lowland areas, almost for half the year, irradiation strengths are reached for which sun protection is recommended. In the uplands, the foothills of the Alps and in the high mountains, this applies to 200 days and more annually. The period in question does not yet permit any statements on trend. There is a need for further research into the climate-change related changes in influential factors affecting UV radiation close to ground level.

 

32 - Strahlenschutzkommission 2016: Empfehlung der Strahlenschutzkommission „Schutz des Menschen vor den Gefahren solarer UV-Strahlung und UV-Strahlung in Solarien“. https://www.ssk.de/SharedDocs/Beratungsergebnisse/2016/2016-02-11%20Empf_UV-Schutz_KT.html?nn=2241510. 33 - El Ghissassi F., Baan R., Straif K. et al. 2009: A review of human carcinogens – part D: radiation. Lancet Oncol 10: 751-752.  34 - DKG – Deutsche Krebsgesellschaft e. V., DKH – Deutsche Krebshilfe, AWMF – Arbeitsgemeinschaft der Wissenschaftlichen Medizinischen Fachgesellschaften e. V. 2021: Leitlinienprogramm Onkologie, S3-Leitlinie Prävention von Hautkrebs, Langversion 2.1., AWMF Registernummer: 032/052OL. https://www.leitlinienprogramm-onkologie.de/leitlinien/hautkrebs-praevention. 35 - Zentrum für Krebsregisterdaten des RKI: https://www.krebsdaten.de/Krebs/DE/Content/Krebsarten/Nicht-melanotischer-Hautkrebs/nicht-melanotischer-hautkrebs_node.html.
Zentrum für Krebsregisterdaten des RKI: https://www.krebsdaten.de/Krebs/DE/Content/Krebsarten/Melanom/melanom_node.html. 36 - Katalinic A. 2022: Update – Prognose und Zahlen zu Hautkrebs in Deutschland. https://www.krebsregister-sh.de/wp-content/uploads/2022/04/Zahlen_Hautkrebs_2022-1.pdf. 37 - DKG et al. 2021, cf. endnote no. 34  38 - WMO – World Meteorological Organization 2022: Executive Summary – Scientific Assessment of Ozone Depletion. GAW Report No. 278: 56 pp. https://ozone.unep.org/science/assessment/sap. 39 - Reid S.J., Tuck A.F., Kiladis G. 2000: On the changing abundance of ozone minima at northern midlatitudes. Journal of Geophysical Research: Atmospheres, 105(D10): 12169-80. 39 - Brönnimann S. & Hood L.L. 2003: Frequency of low-ozone events over northwestern Europe in 1952–1963 and 1990–2000. Geophysical Research Letters 30(21).39 - Stick C., Krüger K., Schade N.H., Sandmann H., Macke A. 2006: Episode of unusual high solar ultraviolet radiation over central Europe due to dynamical reduced total ozone in May 2005. Atmos Chem Phys. 6(7): 1771-1776.39 - Laschewski G., Matzarakis A. 2023: Long-Term Changes of Positive Anomalies of Erythema-Effective UV Irradiance Associated with Low Ozone Events in Germany 1983–2019. Environments 10(2), 31. doi: 10.3390/environments10020031. 40 - BfS – Bundesamt für Strahlenschutz: Mitteilung aus dem deutschlandweiten UV-Messnetz, Messzentrale Mün­chen / Neuherberg. https://www.bfs.de/DE/themen/opt/uv/uv-index/uv-messnetz/uv-messnetz_node.html. 41 - Laschewski & Matzarakis 2023, cf. endnote no. 39. 42 - Polvani L., Keeble J., Banerjee A., Checa-Garcia R., Chiodo G., Rieder H., Rosenlof K. 2023: No evidence of worsening Arctic springtime ozone losses over the 21st century. Nature Communications, 14. doi: 10.1038/s41467-023-37134-3.42 - UNEP EEAP – United Nations Environment Programme, Environmental Effects Assessment Panel. 2023: Environmental Effects of Stratospheric Ozone Depletion, UV Radiation, and Interactions with Climate Change – 2022 Assessment Report. Montreal (Montreal Protocol on Substances that Deplete the Ozone Layer), 372 pp. https://ozone.unep.org/environmental-effects-stratospheric-ozone-depletion-uv-radiation-and-interactions-climate-change.42 - von der Gathen P., Kivi R., Wohltmann I., Salawitch R. J., Rex M. 2021: Climate change favours large seasonal loss of Arctic ozone. Nature Communications, 12(1), 1-17. doi: 10.1038/s41467-021-24089-6. 43 - Wild M., Wacker S., Yang S., Sanchez-Lorenzo A. 2021: Evidence for Clear-Sky Dimming and Brightening in Central Europe. Geophysical Research Letters, 48(6), e2020GL092216. doi: 10.1029/2020GL092216. 44 - Wild M. 2009: Global dimming and brightening: A review, J. Geophys. Res., 114, D00D16, doi: 10.1029/2008JD011470. 45 - Wild 2009, cf. endnote no. 44. 46 - IPCC – Intergovernmental Panel on Climate Change 2021: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 2391 pp. doi: 10.1017/9781009157896.46 - He Y., Wang K., Zhou C., Wild M. 2018: A revisit of global dimming and brightening based on the sunshine duration. Geophysical Research Letters, 45: 4281–4289. doi: 10.1029/2018GL077424. 47 - Fountoulakis I., Diémoz H., Siani A.-M., Laschewski G., Filippa G., Arola A., Bais A.F., De Backer H., Lakkala K., Webb A.R., De Bock V., Karppinen T., Garane K., Kapsomenakis J., Koukouli M.-E., Zerefos C.S. 2020: Solar UV Irradiance in a Changing Climate: Trends in Europe and the Significance of Spectral Monitoring in Italy. Environments, 7, 1. doi: 10.3390/environments7010001. 48 - WHO – World Health Organization, WMO – World Meteorological Organization, UNEP – United Nations Environment Programme, ICNIRP – International Commission on Non-Ionizing Radiation Protection 2002: Global solar UV index: a practical guide. World Health Organization. https://apps.who.int/iris/handle/10665/42459.
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 DAS-Monitoringbericht 2023