IV. Extremwetter

23. Bringt uns der Klimawandel mehr Stürme?

1. Lehmann, J., Coumou, D. (2015): The influence of mid-latitude storm tracks on hot, cold, dry and wet extremes: Scientific Reports 5, 17491.

2. PIK (2015): Kalt, heiß oder trocken: Anhaltende Wetterextreme durch abnehmende Sturmaktivität 11.12.2015, https://www.pik-potsdam.de/aktuelles/pressemitteilungen/kalt-heiss-oder-trocken-anhaltende-wetterextreme-durch-abnehmende-sturmaktivitaet

3. Chang, E. K. M., Ma, C.-G., Zheng, C., Yau, A. M. W. (2016): Observed and projected decrease in Northern Hemisphere extratropical cyclone activity in summer and its impacts on maximum temperature: Geophysical Research Letters 43 (5), 2200-2208.

4. Herring, S. C., Hoerling, M. P., Peterson, T. C., Stott, P. A. (2014): Explaining Extreme Events of 2013 from a Climate Perspective: Bulletin of the American Meteorological Society 95 (9), S1-S104.

5. Helmholtz-Zentrum Geesthacht (2014): Unsere Winterstürme bisher nicht vom Klimawandel beeinflusst: 6.10.2014, https://www.hzg.de/public_relations_media/news/056510/index.php.de

6. ZAMG (2019): Der Mythos der stürmischen Gegenwart: https://www.zamg.ac.at/cms/de/klima/informationsportal-klimawandel/klimavergangenheit/neoklima/stuerme (Zugriff: 1.5.2019).

7. Dangendorf, S., Müller-Navarra, S., Jensen, J., Schenk, F., Wahl, T., Weisse, R. (2014): North Sea Storminess from a Novel Storm Surge Record since AD 1843: Journal of Climate 27 (10), 3582-3595.

8. Cusack, S. (2013): A 101 year record of windstorms in the Netherlands: Climatic Change 116 (3), 693-704.

9. APCC (2014): Österreichischer Sachstandsbericht Klimawandel 2014 (AAR14), Wien, Austrian Panel on Climate Change (APCC), Verlag der Österreichischen Akademie der Wissenschaften, http://austriaca.at/APPC_AAR2014.pdf.

10. Allan, R., Tett, S., Alexander, L. (2009): Fluctuations in autumn–winter severe storms over the British Isles: 1920 to present: International Journal of Climatology 29 (3), 357-371.

11. Bett, P. E., Thornton, H. E., Clark, R. T. (2017): Using the Twentieth Century Reanalysis to assess climate variability for the European wind industry: Theoretical and Applied Climatology 127 (1), 61-80.

12. Bielec-Bąkowska, Z., Piotrowicz, K. (2013): Long-term occurrence, variability and tracks of deep cyclones over Krakow (Central Europe) during the period 1900–2010: International Journal of Climatology 33 (3), 677-689.

13. Cunningham, A. C., Bakker, M. A. J., van Heteren, S., van der Valk, B., van der Spek, A. J. F., Schaart, D. R., Wallinga, J. (2011): Extracting storm-surge data from coastal dunes for improved assessment of flood risk: Geology 39 (11), 1063-1066.

14. Sabatier, P., Dezileau, L., Colin, C., Briqueu, L., Bouchette, F., Martinez, P., Siani, G., Raynal, O., Von Grafenstein, U. (2012): 7000 years of paleostorm activity in the NW Mediterranean Sea in response to Holocene climate events: Quaternary Research 77 (1), 1-11.

15. Costas, S., Jerez, S., Trigo, R. M., Goble, R., Rebêlo, L. (2012): Sand invasion along the Portuguese coast forced by westerly shifts during cold climate events: Quaternary Science Reviews 42 (0), 15-28.

16. Athimon, E., Maanan, M. (2018): Vulnerability, resilience and adaptation of societies during major extreme storms during the Little Ice Age: Clim. Past 14 (10), 1487-1497.

17. Streeter, R., Dugmore, A. (2014): Late-Holocene land surface change in a coupled social–ecological system, southern Iceland: a cross-scale tephrochronology approach: Quaternary Science Reviews 86, 99-114.

18. Van Vliet-Lanoë, B., Goslin, J., Hallégouët, B., Hénaff, A., Delacourt, C., Fernane, A., Franzetti, M., Le Cornec, E., Le Roy, P., Penaud, A. (2014): Middle- to late-Holocene storminess in Brittany (NW France): Part I – morphological impact and stratigraphical record: The Holocene 24 (4), 413-433.

19. Degeai, J.-P., Devillers, B., Dezileau, L., Oueslati, H., Bony, G. (2015): Major storm periods and climate forcing in the Western Mediterranean during the Late Holocene: Quaternary Science Reviews 129, 37-56.

20. Orme, L. C., Reinhardt, L., Jones, R. T., Charman, D. J., Barkwith, A., Ellis, M. A. (2016): Aeolian sediment reconstructions from the Scottish Outer Hebrides: Late Holocene storminess and the role of the North Atlantic Oscillation: Quaternary Science Reviews 132, 15-25.

21. Van Vliet-Lanoë, B., Penaud, A., Hénaff, A., Delacourt, C., Fernane, A., Goslin, J., Hallégouët, B., Le Cornec, E. (2014): Middle- to late-Holocene storminess in Brittany (NW France): Part II – The chronology of events and climate forcing: The Holocene 24 (4), 434-453.

22. Feal-Pérez, A., Blanco-Chao, R., Ferro-Vázquez, C., Martínez-Cortizas, A., Costa-Casais, M. (2014): Late-Holocene storm imprint in a coastal sedimentary sequence (Northwest Iberian coast): The Holocene 24 (4), 477-488.

23. Rangel-Buitrago, N. G., Thomas, T., Phillips, M. R., Anfuso, G., Williams, A. T. (2016): Wave Climate, Storminess, and Northern Hemisphere Teleconnection Patterns Influences: The Outer Bristol Channel, South Wales, U.K: Journal of Coastal Research 32 (6), 1262-1276, 1215.

24. Dezileau, L., Pérez-Ruzafa, A., Blanchemanche, P., Degeai, J. P., Raji, O., Martinez, P., Marcos, C., Von Grafenstein, U. (2016): Extreme storms during the last 6500 years from lagoonal sedimentary archives in the Mar Menor (SE Spain): Clim. Past 12 (6), 1389-1400.

25. Martin-Puertas, C., Matthes, K., Brauer, A., Muscheler, R., Hansen, F., Petrick, C., Aldahan, A., Possnert, G., Geel, B. v. (2012): Regional atmospheric circulation shifts induced by a grand solar minimum: Nature Geoscience doi:10.1038/ngeo1460.

26. GFZ (2012): Klimatische Folgen einer schwachen Sonne: 6.5.2012, https://www.gfz-potsdam.de/medien-kommunikation/meldungen/detailansicht/article/klimatische-folgen-einer-schwachen-sonne/

27. Orme, L. C., Davies, S. J., Duller, G. A. T. (2015): Reconstructed centennial variability of Late Holocene storminess from Cors Fochno, Wales, UK: Journal of Quaternary Science 30 (5), 478-488.

28. Sorrel, P., Debret, M., Billeaud, I., Jaccard, S. L., McManus, J. F., Tessier, B. (2012): Persistent non-solar forcing of Holocene storm dynamics in coastal sedimentary archives: Nature Geosci 5 (12), 892-896.

29. University of Manchester (2014): Linking storms to climate change a ‘distraction’, say experts: 20.3.2014, https://www.manchester.ac.uk/discover/news/article/?id=11794

30. IPCC (2012): Management des Risikos von Extremereignissen und Katastrophen zur Förderung der Anpassung an den Klimawandel – Zusammenfassung für politische Entscheidungsträger (deutsche Übersetzung): Sonderbericht des Zwischenstaatlichen Ausschusses für Klimaänderungen (IPCC), https://www.de-ipcc.de/128.php

31. Trenary, L., DelSole, T., Camargo, S. J., Tippett, M. K. (2019): Are Midtwentieth Century Forced Changes in North Atlantic Hurricane Potential Intensity Detectable?: Geophysical Research Letters 46 (6), 3378-3386.

32. Truchelut, R. E., Staehling, E. M. (2017): An Energetic Perspective on United States Tropical Cyclone Landfall Droughts: Geophysical Research Letters 44 (23), 12,013-012,019.

33. Mavume, A. F., Rydberg, L., Rouault, M., Lutjeharms, J. R. E. (2009): Climatology and Landfall of Tropical Cyclones in the South-West Indian Ocean: Western Indian Ocean Journal of Marine Science 8 (1), 15-36.

34. Fitchett, J. M., Grab, S. W. (2014): A 66-year tropical cyclone record for south-east Africa: temporal trends in a global context: International Journal of Climatology 34 (13), 3604-3615.

35. Yamashita, M., Mitsumata, J. (2013): Does Global Warming Affect Typhoon Patterns in Japan? Discussion from the Viewpoints of the Numbers of Typhoons That Develop, Approach, and Hit Japan, and Their Intensities: Resources and Environment 3 (5), 115-128.

36. Ni, X., Zhang, Q., Ma, D., Wu, L., Ren, F. (2015): Climatology and trends of tropical cyclone high wind in mainland China: 1959–2011: Journal of Geophysical Research: Atmospheres 120 (24), 12378-12393.

37. Hoarau, K., Bernard, J., Chalonge, L. (2012): Intense tropical cyclone activities in the northern Indian Ocean: International Journal of Climatology 32 (13), 1935-1945.

38. Yu, K., Zhao, J., Roff, G., Lybolt, M., Feng, Y., Clark, T., Li, S. (2012): High-precision U-series ages of transported coral blocks on Heron Reef (southern Great Barrier Reef) and storm activity during the past century: Palaeogeography, Palaeoclimatology, Palaeoecology 337-338, 23-36.

39. Bureau of Meteorology (2020): Tropical Cyclone Trends: http://www.bom.gov.au/cyclone/climatology/trends.shtml

40. van Soelen, E. E., Wagner-Cremer, F., Damsté, J. S. S., Reichart, G. J. (2013): Reconstructing tropical cyclone frequency using hydrogen isotope ratios of sedimentary n-alkanes in northern Queensland, Australia: Palaeogeography, Palaeoclimatology, Palaeoecology 376, 66-72.

41. Weinkle, J., Landsea, C., Collins, D., Musulin, R., Crompton, R. P., Klotzbach, P. J., Pielke, R. (2018): Normalized hurricane damage in the continental United States 1900–2017: Nature Sustainability 1 (12), 808-813.

42. Pielke, R. (2019): No, Hurricanes Are Not Bigger, Stronger and More Dangerous: Forbes 15.11.2019, https://www.forbes.com/sites/rogerpielke/2019/11/15/no-hurricanes-are-not-bigger-stronger-and-more-dangerous/#4f9c2e794d9e

43. Parth Sarthi, P., Agrawal, A., Rana, A. (2015): Possible future changes in cyclonic storms in the Bay of Bengal, India under warmer climate: International Journal of Climatology 35 (7), 1267-1277.

44. Yoshida, K., Sugi, M., Mizuta, R., Murakami, H., Ishii, M. (2017): Future Changes in Tropical Cyclone Activity in High-Resolution Large-Ensemble Simulations: Geophysical Research Letters 44 (19), 9910-9917.

45. Murakami, H., Hsu, P.-C., Arakawa, O., Li, T. (2014): Influence of Model Biases on Projected Future Changes in Tropical Cyclone Frequency of Occurrence: Journal of Climate 27 (5), 2159-2181.

46. Kim, H.-S., Vecchi, G. A., Knutson, T. R., Anderson, W. G., Delworth, T. L., Rosati, A., Zeng, F., Zhao, M. (2014): Tropical Cyclone Simulation and Response to CO2 Doubling in the GFDL CM2.5 High-Resolution Coupled Climate Model: Journal of Climate 27 (21), 8034-8054.

47. Walsh, K. J. E., Camargo, S. J., Vecchi, G. A., Daloz, A. S., Elsner, J., Emanuel, K., Horn, M., Lim, Y.-K., Roberts, M., Patricola, C., Scoccimarro, E., Sobel, A. H., Strazzo, S., Villarini, G., Wehner, M., Zhao, M., Kossin, J. P., LaRow, T., Oouchi, K., Schubert, S., Wang, H., Bacmeister, J., Chang, P., Chauvin, F., Jablonowski, C., Kumar, A., Murakami, H., Ose, T., Reed, K. A., Saravanan, R., Yamada, Y., Zarzycki, C. M., Vidale, P. L., Jonas, J. A., Henderson, N. (2015): Hurricanes and Climate: The U.S. CLIVAR Working Group on Hurricanes: Bulletin of the American Meteorological Society 96 (6), 997-1017.

48. Lim, Y.-K., Schubert, S. D., Reale, O., Lee, M.-I., Molod, A. M., Suarez, M. J. (2015): Sensitivity of Tropical Cyclones to Parameterized Convection in the NASA GEOS-5 Model: Journal of Climate 28 (2), 551-573.

49. Sugi, M., Yoshida, K., Murakami, H. (2015): More tropical cyclones in a cooler climate?: Geophysical Research Letters 42 (16), 6780-6784.

50. Wang, L. C., Behling, H., Lee, T. Q., Li, H. C., Huh, C. A., Shiau, L. J., Chang, Y. P. (2014): Late Holocene environmental reconstructions and their implications on flood events, typhoon, and agricultural activities in NE Taiwan: Clim. Past 10 (5), 1857-1869.

51. Liu, K. S., Chan, J. C. L. (2013): Inactive Period of Western North Pacific Tropical Cyclone Activity in 1998–2011: Journal of Climate 26 (8), 2614-2630.

52. McCloskey, T. A., Liu, K.-b. (2013): A 7000 year record of paleohurricane activity from a coastal wetland in Belize: The Holocene 23 (2), 278-291.

53. Brandon, C. M., Woodruff, J. D., Lane, D. P., Donnelly, J. P. (2013): Tropical cyclone wind speed constraints from resultant storm surge deposition: A 2500 year reconstruction of hurricane activity from St. Marks, FL: Geochemistry, Geophysics, Geosystems 14 (8), 2993-3008.

54. Nott, J., Forsyth, A. (2012): Punctuated global tropical cyclone activity over the past 5,000 years: Geophysical Research Letters 39 (14).

55. Balaguru, K., Foltz, G. R., Leung, L. R. (2018): Increasing Magnitude of Hurricane Rapid Intensification in the Central and Eastern Tropical Atlantic: Geophysical Research Letters 45 (9), 4238-4247.

56. Pacific Northwest National Laboratory (2018): Powerful hurricanes strengthen faster now than 30 years ago: 7.5.2018, https://www.pnnl.gov/news/release.aspx?id=4504

57. Zhang, W., Vecchi, G. A., Murakami, H., Villarini, G., Delworth, T. L., Yang, X., Jia, L. (2018): Dominant Role of Atlantic Multidecadal Oscillation in the Recent Decadal Changes in Western North Pacific Tropical Cyclone Activity: Geophysical Research Letters 45 (1), 354-362.

58. Zhang, R., Delworth, T. L. (2006): Impact of Atlantic multidecadal oscillations on India/Sahel rainfall and Atlantic hurricanes: Geophysical Research Letters 33 (17).

59. Klotzbach, P., Gray, W., Fogarty, C. (2015): Active Atlantic hurricane era at its end?: Nature Geoscience 8 (10), 737-738.

60. Goldenberg, S. B., Landsea, C. W., Mestas-Nuñez, A. M., Gray, W. M. (2001): The Recent Increase in Atlantic Hurricane Activity: Causes and Implications: Science 293 (5529), 474-479.

61. Chenoweth, M., Divine, D. (2012): Tropical cyclones in the Lesser Antilles: descriptive statistics and historical variability in cyclone energy, 1638–2009: Climatic Change 113 (3), 583-598.

62. Katsuki, K., Yang, D.-Y., Seto, K., Yasuhara, M., Takata, H., Otsuka, M., Nakanishi, T., Yoon, Y., Um, I.-K., Cheung, R. C. W., Khim, B.-K., Kashima, K. (2016): Factors controlling typhoons and storm rain on the Korean Peninsula during the Little Ice Age: Journal of Paleolimnology 55 (1), 35-48.

63. Katsuki, K., Yang, D.-Y., Lim, J., Lee, J.-Y., Asahi, H., Han, M. (2017): Multi-centennial-scale changes in East Asian typhoon frequency during the mid-Holocene: Palaeogeography, Palaeoclimatology, Palaeoecology 476, 140-146.

64. Girishkumar, M. S., Thanga Prakash, V. P., Ravichandran, M. (2015): Influence of Pacific Decadal Oscillation on the relationship between ENSO and tropical cyclone activity in the Bay of Bengal during October–December: Climate Dynamics 44 (11), 3469-3479.

65. Liu, Y.-C., Chen, H.-F., Liu, X., Chang, Y.-P. (2017): Insight into tropical cyclone behaviour through examining maritime disasters over the past 1000 years based on the dynastic histories of China – A dedication to Ocean Researcher V: Quaternary International 440, 72-81.

66. Klotzbach, P. J. (2012): El Niño-Southern Oscillation, the Madden-Julian Oscillation and Atlantic basin tropical cyclone rapid intensification: Journal of Geophysical Research: Atmospheres 117 (D14).

67. Liu, K.-b., Shen, C., Louie, K.-s. (2001): A 1,000-Year History of Typhoon Landfalls in Guangdong, Southern China, Reconstructed from Chinese Historical Documentary Records: Annals of the Association of American Geographers 91 (3), 453-464.

68. Zhang, Q., Zhang, W., Lu, X., Chen, Y. D. (2012): Landfalling tropical cyclones activities in the south China: intensifying or weakening?: International Journal of Climatology 32 (12), 1815-1824.

69. Maue, R. N. (2011): Recent historically low global tropical cyclone activity: Geophysical Research Letters 38, 1-6.

70. Kubota, H., Chan, J. C. L. (2009): Interdecadal variability of tropical cyclone landfall in the Philippines from 1902 to 2005: Geophys. Res. Lett. 36 (12), L12802.

71. Wang, L., Huang, R., Wu, R. (2013): Interdecadal variability in tropical cyclone frequency over the South China Sea and its association with the Indian Ocean sea surface temperature: Geophysical Research Letters 40 (4), 768-771.

72. University of Arizona (2016): Shipwrecks, Tree Rings Reveal Caribbean Hurricanes: 7.3.2016, https://uanews.arizona.edu/story/shipwrecks-tree-rings-reveal-caribbean-hurricanes

73. Haig, J. E.-A., Nott, J. (2016): Solar forcing over the last 1500 years and Australian tropical cyclone activity: Geophysical Research Letters 43 (6), 2843-2850.

74. Rojo-Garibaldi, B., Salas-de-León, D. A., Sánchez, N. L., Monreal-Gómez, M. A. (2016): Hurricanes in the Gulf of Mexico and the Caribbean Sea and their relationship with sunspots: Journal of Atmospheric and Solar-Terrestrial Physics 148, 48-52.

75. Trouet, V., Harley, G. L., Domínguez-Delmás, M. (2016): Shipwreck rates reveal Caribbean tropical cyclone response to past radiative forcing: Proceedings of the National Academy of Sciences 113 (12), 3169-3174.

76. Pazos, M., Mendoza, B. (2013): Landfalling Tropical Cyclones along the Eastern Pacific Coast between the Sixteenth and Twentieth Centuries: Journal of Climate 26 (12), 4219-4230.

77. University of Southampton (2015): Global Climate on Verge of Multi-Decadal Change: 27.5.2015, https://www.sciencedaily.com/releases/2015/05/150527133932.htm

78. Donnelly, J. P., Hawkes, A. D., Lane, P., MacDonald, D., Shuman, B. N., Toomey, M. R., van Hengstum, P. J., Woodruff, J. D. (2015): Climate forcing of unprecedented intense-hurricane activity in the last 2000 years: Earth’s Future 3 (2), 49-65.

79. AGU (2015): Monster hurricanes reached U.S. Northeast during prehistoric periods of ocean warming: 11.2.2015, https://news.agu.org/press-release/monster-hurricanes-reached-u-s-northeast-during-prehistoric-periods-of-ocean-warming/

80. Ercolani, C., Muller, J., Collins, J., Savarese, M., Squiccimara, L. (2015): Intense Southwest Florida hurricane landfalls over the past 1000 years: Quaternary Science Reviews 126, 17-25.

81. Tiroler Tageszeitung (2015): Präsident: Klimawandel hat zu Desaster auf Vanuatu beigetragen: 16.3.2015, https://www.tt.com/artikel/9767297/praesident-klimawandel-hat-zu-desaster-auf-vanuatu-beigetragen

82. Reuters (2015): Vanuatu provides lessons in cyclone survival: 19.3.2015, https://uk.reuters.com/article/us-weather-vanuatu-cyclone-lessons/vanuatu-provides-lessons-in-cyclone-survival-idUKKBN0MF06Z20150319.

83. Maue, R. (2020): Global Tropical Cyclone Activity: http://climatlas.com/tropical/

84. phys.org (2011): Tornadoes whipped up by wind, not climate: officials: 28.4.2011, https://phys.org/news/2011-04-tornadoes-climate.html

85. Wikipedia (2019): Annual count of strong to violent tornadoes in the U.S. from 1955 to 2018: https://commons.wikimedia.org/wiki/File:Tornado_count_annual.svg

86. USGCRP (2017): Climate Science Special Report: Fourth National Climate Assessment, Volume I, U.S. Global Change Research Program, Washington, DC, USA.

87. Moore, T. W. (2018): Annual and seasonal tornado trends in the contiguous United States and its regions: International Journal of Climatology 38 (3), 1582-1594.

88. Edwards, R. (2020): The online tornado FAQ: Storm Prediction Center, NOAA, https://www.spc.noaa.gov/faq/tornado/

89. Simmons, K. M., Sutter, D., Pielke, R. (2013): Normalized tornado damage in the United States: 1950–2011: Environmental Hazards 12 (2), 132-147.

90. Lepore, C., Tippett, M. K., Allen, J. T. (2017): ENSO-based probabilistic forecasts of March–May U.S. tornado and hail activity: Geophysical Research Letters 44 (17), 9093-9101.

91. Allen, J. T., Molina, M. J., Gensini, V. A. (2018): Modulation of Annual Cycle of Tornadoes by El Niño–Southern Oscillation: Geophysical Research Letters 45 (11), 5708-5717.

92. University of Missouri (2013): Pacific Ocean Temperature Influences Tornado Activity in U.S., MU Study Finds: 10.10.2013, https://munewsarchives.missouri.edu/news-releases/2013/1010-pacific-ocean-temperature-influences-tornado-activity-in-u-s-mu-study-finds/

93. VICE (2013): A Warmer Pacific Ocean Leads to More Tornadoes: 18.10.2013, https://www.vice.com/en_us/article/jp5eqx/a-warmer-pacific-ocean-leads-to-more-tornadoes

94. Haeseler, S., Lefebvre, C., Friedrich, A. (2015): Unwetter mit Tornados richten am 5. Mai 2015 schwere Schäden in Norddeutschland an: DWD, https://www.dwd.de/DE/presse/hintergrundberichte/2015/Unwetter_Tornado_Norddeutschland_PDF.pdf?__blob=publicationFile&v=2

95. NOAA (2020): Tornados: Historical Records and Trends https://www.ncdc.noaa.gov/climate-information/extreme-events/us-tornado-climatology/trends

96. Bundesamt für Seeschifffahrt und Hydrographie (2007): Sturmfluthäufigkeit und -intensität in der Nord- und Ostsee: 26.9.2007, https://www.wattenrat.de/aktuell/aktuell251.htm

97. Gönnert, G. (2003): Sturmfluten und Windstau in der Deutschen Bucht: Charakter, Veränderungen und Maximalwerteim 20. Jahrhundert: Die Küste 67, 185-365.

98. Ritter, A. (1904): Befreiung. Neue Gedichte von Anna Ritter, Stuttgart, Berlin, Cotta’sche Buchhandlung Nachf.