V. MEERESSPIEGEL
26. Wie stark steigt der Meeresspiegel?
1. IPCC (2019): Special Report on the Ocean and Cryosphere in a Changing Climate (SROCC): Summary for Policymakers (SPM), https://www.ipcc.ch/srocc/
2. IPCC (2019): Special Report on the Ocean and Cryosphere in a Changing Climate: main SROCC report.
3. Wahl, T., Haigh, I. D., Woodworth, P. L., Albrecht, F., Dillingh, D., Jensen, J., Nicholls, R. J., Weisse, R., Wöppelmann, G. (2013): Observed mean sea level changes around the North Sea coastline from 1800 to present: Earth-Science Reviews 124, 51-67.
4. Richter, A., Groh, A., Dietrich, R. (2012): Geodetic observation of sea-level change and crustal deformation in the Baltic Sea region: Physics and Chemistry of the Earth, Parts A/B/C 53-54, 43-53.
5. Limkilde Svendsen, P., Andersen, O. B., Aasbjerg Nielsen, A. (2016): Stable reconstruction of Arctic sea level for the 1950–2010 period: Journal of Geophysical Research: Oceans 121 (8), 5697-5710.
6. Palanisamy, H., Cazenave, A., Meyssignac, B., Soudarin, L., Wöppelmann, G., Becker, M. (2014): Regional sea level variability, total relative sea level rise and its impacts on islands and coastal zones of Indian Ocean over the last sixty years: Global and Planetary Change 116, 54-67.
7. Zerbini, S., Raicich, F., Prati, C. M., Bruni, S., Del Conte, S., Errico, M., Santi, E. (2017): Sea-level change in the Northern Mediterranean Sea from long-period tide gauge time series: Earth-Science Reviews 167, 72-87.
8. Frederikse, T., Jevrejeva, S., Riva, R. E. M., Dangendorf, S. (2018): A Consistent Sea-Level Reconstruction and Its Budget on Basin and Global Scales over 1958–2014: Journal of Climate 31 (3), 1267-1280.
9. Hay, C. C., Morrow, E., Kopp, R. E., Mitrovica, J. X. (2015): Probabilistic reanalysis of twentieth-century sea-level rise: Nature 517 (7535), 481-484.
10. Hamburger Bildungsserver (2020): Aktueller Meeresspiegelanstieg: https://wiki.bildungsserver.de/klimawandel/index.php/Aktueller_Meeresspiegelanstieg
11. Vignudelli, S., Birol, F., Benveniste, J., Fu, L.-L., Picot, N., Raynal, M., Roinard, H. (2019): Satellite Altimetry Measurements of Sea Level in the Coastal Zone: Surveys in Geophysics 40 (6), 1319-1349.
12. Dean, R. G., Houston, J. R. (2013): Recent sea level trends and accelerations: Comparison of tide gauge and satellite results: Coastal Engineering 75, 4-9.
13. Baur, O., Kuhn, M., Featherstone, W. E. (2013): Continental mass change from GRACE over 2002–2011 and its impact on sea level: Journal of Geodesy 87 (2), 117-125.
14. NOAA (2013): The Budget of Recent Global Sea Level Rise 2005–2012: https://www.star.nesdis.noaa.gov/socd/lsa/SeaLevelRise/documents/NOAA_NESDIS_Sea_Level_Rise_Budget_Report_2012rev1.pdf
15. Dangendorf, S., Calafat, F. M., Arns, A., Wahl, T., Haigh, I. D., Jensen, J. (2014): Mean sea level variability in the North Sea: Processes and implications: Journal of Geophysical Research: Oceans 119 (10).
16. Chambers, D. P., Merrifield, M. A., Nerem, R. S. (2012): Is there a 60-year oscillation in global mean sea level?: Geophys. Res. Lett. 39 (18), L18607.
17. Scafetta, N. (2014): Multi-scale dynamical analysis (MSDA) of sea level records versus PDO, AMO, and NAO indexes: Climate Dynamics 43 (1), 175-192.
18. Fadil, A., Denys, P., Tenzer, R., Grenfell, H. R., Willis, P. (2013): New Zealand 20th century sea level rise: Resolving the vertical land motion using space geodetic and geological data: Journal of Geophysical Research: Oceans 118 (11), 6076-6091.
19. Hansen, J. M., Aagaard, T., Binderup, M. (2012): Absolute sea levels and isostatic changes of the eastern North Sea to central Baltic region during the last 900 years: Boreas 41 (2), 180-208.
20. Hamlington, B. D., Leben, R. R., Strassburg, M. W., Nerem, R. S., Kim, K.-Y. (2013): Contribution of the Pacific Decadal Oscillation to global mean sea level trends: Geophysical Research Letters 40 (19), 5171-5175.
21. Strassburg, M. W., Hamlington, B. D., Leben, R. R., Manurung, P., Lumban Gaol, J., Nababan, B., Vignudelli, S., Kim, K. Y. (2015): Sea level trends in Southeast Asian seas: Clim. Past 11 (5), 743-750.
22. Zhang, X., Church, J. A. (2012): Sea level trends, interannual and decadal variability in the Pacific Ocean: Geophysical Research Letters 39 (21).
23. Cheng, X., Li, L., Du, Y., Wang, J., Huang, R.-X. (2013): Mass-induced sea level change in the northwestern North Pacific and its contribution to total sea level change: Geophysical Research Letters 40 (15), 3975-3980.
24. Moon, J.-H., Song, Y. T., Bromirski, P. D., Miller, A. J. (2013): Multidecadal regional sea level shifts in the Pacific over 1958–2008: Journal of Geophysical Research: Oceans 118 (12), 7024-7035.
25. Albrecht, F., Pizarro, O., Montecinos, A., Zhang, X. (2019): Understanding Sea Level Change in the South Pacific During the Late 20th Century and Early 21st Century: Journal of Geophysical Research: Oceans 124 (6), 3849-3858.
26. Merrifield, M. A., Thompson, P. R., Lander, M. (2012): Multidecadal sea level anomalies and trends in the western tropical Pacific: Geophysical Research Letters 39 (13).
27. World Bank (2013): Turn down the heat: Climate extremes, regional impacts, and the case for resilience: A Report for the World Bank by the Potsdam Institute for Climate Impact Research and Climate Analytics, https://www.worldbank.org/en/topic/climatechange/publication/turn-down-the-heat-climate-extremes-regional-impacts-resilience
28. World Bank (2013): Warmer World Threatens Livelihoods in South East Asia: 19.6.2013, https://www.worldbank.org/en/news/press-release/2013/06/19/warmer-world-threatens-livelihoods-in-south-east-asia
29. University of Arizona (2016): Pacific Sea Level Predicts Global Temperature Changes 18.8.2016, https://uanews.arizona.edu/story/pacific-sea-level-predicts-global-temperature-changes
30. Peyser, C. E., Yin, J., Landerer, F. W., Cole, J. E. (2016): Pacific sea level rise patterns and global surface temperature variability: Geophysical Research Letters 43 (16), 8662-8669.
31. Royston, S., Watson, C. S., Legrésy, B., King, M. A., Church, J. A., Bos, M. S. (2018): Sea-Level Trend Uncertainty With Pacific Climatic Variability and Temporally-Correlated Noise: Journal of Geophysical Research: Oceans 123 (3), 1978-1993.
32. Moon, J.-H., Song, Y. T., Lee, H. (2015): PDO and ENSO modulations intensified decadal sea level variability in the tropical Pacific: Journal of Geophysical Research: Oceans 120 (12), 8229-8237.
33. Hamlington, B. D., Cheon, S. H., Thompson, P. R., Merrifield, M. A., Nerem, R. S., Leben, R. R., Kim, K.-Y. (2016): An ongoing shift in Pacific Ocean sea level: Journal of Geophysical Research: Oceans 121 (7), 5084-5097.
34. Hamlington, B. D., Leben, R. R., Kim, K.-Y., Nerem, R. S., Atkinson, L. P., Thompson, P. R. (2015): The effect of the El Niño-Southern Oscillation on U.S. regional and coastal sea level: Journal of Geophysical Research: Oceans 120 (6), 3970-3986.
35. Cazenave, A., Dieng, H.-B., Meyssignac, B., von Schuckmann, K., Decharme, B., Berthier, E. (2014): The rate of sea-level rise: Nature Climate Change 4 (5), 358-361.
36. Boening, C., Willis, J. K., Landerer, F. W., Nerem, R. S., Fasullo, J. (2012): The 2011 La Niña: So strong, the oceans fell: Geophysical Research Letters 39 (19).
37. Fasullo, J. T., Boening, C., Landerer, F. W., Nerem, R. S. (2013): Australia’s unique influence on global sea level in 2010–2011: Geophysical Research Letters 40 (16), 4368-4373.
38. Calafat, F. M., Chambers, D. P., Tsimplis, M. N. (2012): Mechanisms of decadal sea level variability in the eastern North Atlantic and the Mediterranean Sea: Journal of Geophysical Research: Oceans 117 (C9).
39. Li, F., Jo, Y.-H., Liu, W. T., Yan, X.-H. (2012): A dipole pattern of the sea surface height anomaly in the North Atlantic: 1990s–2000s: Geophysical Research Letters 39 (15).
40. Tsimplis, M. N., Calafat, F. M., Marcos, M., Jordà, G., Gomis, D., Fenoglio-Marc, L., Struglia, M. V., Josey, S. A., Chambers, D. P. (2013): The effect of the NAO on sea level and on mass changes in the Mediterranean Sea: Journal of Geophysical Research: Oceans 118 (2), 944-952.
41. Landerer, F. W., Volkov, D. L. (2013): The anatomy of recent large sea level fluctuations in the Mediterranean Sea: Geophysical Research Letters 40 (3), 553-557.
42. Masina, M., Lamberti, A. (2013): A nonstationary analysis for the Northern Adriatic extreme sea levels: Journal of Geophysical Research: Oceans 118 (9), 3999-4016.
43. Karabil, S., Zorita, E., Hünicke, B. (2017): Mechanisms of variability in decadal sea-level trends in the Baltic Sea over the 20th century: Earth Syst. Dynam. 8 (4), 1031-1046.
44. Henry, O., Prandi, P., Llovel, W., Cazenave, A., Jevrejeva, S., Stammer, D., Meyssignac, B., Koldunov, N. (2012): Tide gauge-based sea level variations since 1950 along the Norwegian and Russian coasts of the Arctic Ocean: Contribution of the steric and mass components: J. Geophys. Res. 117 (C6), C06023.
45. Shaviv, N. J. (2008): Using the oceans as a calorimeter to quantify the solar radiative forcing: Journal of Geophysical Research 113, 1-13.
46. Martínez-Asensio, A., Tsimplis, M. N., Calafat, F. M. (2016): Decadal variability of European sea level extremes in relation to the solar activity: Geophysical Research Letters 43 (22), 11,744-711,750.
47. Howard, D., Shaviv, N. J., Svensmark, H. (2015): The solar and Southern Oscillation components in the satellite altimetry data: Journal of Geophysical Research: Space Physics 120 (5), 3297-3306.
48. Hansen, J. M., Aagaard, T., Kuijpers, A. (2015): Sea-Level Forcing by Synchronization of 56- and 74-Year Oscillations with the Moon’s Nodal Tide on the Northwest European Shelf (Eastern North Sea to Central Baltic Sea): Journal of Coastal Research, 1041-1056.
49. Jevrejeva, S., Moore, J. C., Grinsted, A., Matthews, A. P., Spada, G. (2014): Trends and acceleration in global and regional sea levels since 1807: Global and Planetary Change 113, 11-22.
50. Houston, J. R., Dean, R. G. (2011): Sea-Level Acceleration Based on U.S. Tide Gauges and Extensions of Previous Global-Gauge Analyses: Journal of Coastal Research 27 (3), 409-417.
51. Watson, P. J. (2017): Acceleration in European Mean Sea Level? A New Insight Using Improved Tools: Journal of Coastal Research 33 (1), 23-38, 16.
52. Universität Siegen (2013): „Die Ergebnisse geben uns eine gewisse Planungssicherheit für den Küstenschutz“ 18.7.2013, https://www.uni-siegen.de/start/news/forschung/536040.html
53. Watson, P. J. (2011): Is There Evidence Yet of Acceleration in Mean Sea Level Rise around Mainland Australia?: Journal of Coastal Research 27, 368-377.
54. Hannah, J., Bell, R. G. (2012): Regional sea level trends in New Zealand: J. Geophys. Res. 117 (C1), C01004.
55. Hamlington, B. D., Frederikse, T., Nerem, R. S., Fasullo, J. T., Adhikari, S. (2020): Investigating the Acceleration of Regional Sea Level Rise During the Satellite Altimeter Era: Geophysical Research Letters 47 (5), e2019GL086528.
56. University of Southampton (2014): Back to the future to determine if sea level rise is accelerating: 9.5.2014, https://www.southampton.ac.uk/news/2014/05/09-back-to-the-future-determine-sea-level-rise-accelerating.page
57. Dangendorf, S., Marcos, M., Müller, A., Zorita, E., Riva, R., Berk, K., Jensen, J. (2015): Detecting anthropogenic footprints in sea level rise: Nature Communications 6 (1), 7849.
58. Palanisamy, H., Meyssignac, B., Cazenave, A., Delcroix, T. (2015): Is anthropogenic sea level fingerprint already detectable in the Pacific Ocean?: Environmental Research Letters 10 (8), 084024.
59. Haigh, I. D., Wahl, T., Rohling, E. J., Price, R. M., Pattiaratchi, C. B., Calafat, F. M., Dangendorf, S. (2014): Timescales for detecting a significant acceleration in sea level rise: Nature Communications 5 (1), 3635.
60. Jordà, G. (2014): Detection time for global and regional sea level trends and accelerations: Journal of Geophysical Research: Oceans 119 (10), 7164-7174.
61. Bordbar, M. H., Martin, T., Latif, M., Park, W. (2015): Effects of long-term variability on projections of twenty-first century dynamic sea level: Nature Climate Change 5 (4), 343-347.
62. Wenzel, M., Schröter, J. (2014): Global and regional sea level change during the 20th century: Journal of Geophysical Research: Oceans 119 (11), 7493-7508.
63. Sallenger, A. H., Doran, K. S., Howd, P. A. (2012): Hotspot of accelerated sea-level rise on the Atlantic coast of North America: Nature Climate Change 2 (12), 884-888.
64. Vermeer, M., Rahmstorf, S., Kemp, A., Horton, B. (2012): On the differences between two semi-empirical sea-level models for the last two millennia: Clim. Past Discuss. 2012, 3551-3581.
65. Kenigson, J. S., Han, W. (2014): Detecting and understanding the accelerated sea level rise along the east coast of the United States during recent decades: Journal of Geophysical Research: Oceans 119 (12), 8749-8766.
66. Valle-Levinson, A., Dutton, A., Martin, J. B. (2017): Spatial and temporal variability of sea level rise hot spots over the eastern United States: Geophysical Research Letters 44 (15), 7876-7882.
67. University of Florida (2017): East Coast’s rapidly rising seas explained: 9.8.2017, https://news.ufl.edu/articles/2017/08/east-coasts-rapidly-rising-seas-explained.html
68. Domingues, R., Goni, G., Baringer, M., Volkov, D. (2018): What Caused the Accelerated Sea Level Changes Along the U.S. East Coast During 2010–2015?: Geophysical Research Letters 45 (24), 13,367-313,376.
69. Goddard, P. B., Yin, J., Griffies, S. M., Zhang, S. (2015): An extreme event of sea-level rise along the Northeast coast of North America in 2009–2010: Nature Communications 6 (1), 6346.
70. Wahl, T., Chambers, D. P. (2015): Evidence for multidecadal variability in US extreme sea level records: Journal of Geophysical Research: Oceans 120 (3), 1527-1544.
71. University of Arizona (2015): Sea Level Spiked for Two Years Along NE North America: 24.2.2015, https://uanews.arizona.edu/story/sea-level-spiked-for-two-years-along-ne-north-america
72. Ezer, T., Atkinson, L. P., Corlett, W. B., Blanco, J. L. (2013): Gulf Stream’s induced sea level rise and variability along the U.S. mid-Atlantic coast: Journal of Geophysical Research: Oceans 118 (2), 685-697.
73. Kopp, R. E. (2013): Does the mid-Atlantic United States sea level acceleration hot spot reflect ocean dynamic variability?: Geophysical Research Letters 40 (15), 3981-3985.
74. Brain, M. J., Kemp, A. C., Horton, B. P., Culver, S. J., Parnell, A. C., Cahill, N. (2015): Quantifying the contribution of sediment compaction to late Holocene salt-marsh sea-level reconstructions, North Carolina, USA: Quaternary Research 83 (1), 41-51.
75. E&E News (2012): Ancient N.C. records show sea-level rise is related to warmer temperatures: 19.6.2012, https://www.eenews.net/stories/1059966091
76. Armstrong, S. B., Lazarus, E. D. (2019): Masked Shoreline Erosion at Large Spatial Scales as a Collective Effect of Beach Nourishment: Earth’s Future 7 (2), 74-84.
77. Universität Siegen (2015): Natürliche Meeresspiegel-Schwankungen unterschätzt: 29.7.2015, https://www.uni-siegen.de/start/news/oeffentlichkeit/643701.html
78. Kopp, R. E., Kemp, A. C., Bittermann, K., Horton, B. P., Donnelly, J. P., Gehrels, W. R., Hay, C. C., Mitrovica, J. X., Morrow, E. D., Rahmstorf, S. (2016): Temperature-driven global sea-level variability in the Common Era: Proceedings of the National Academy of Sciences 113 (11), E1434-E1441.
79. Elliff, C. I., Silva, I. R. (2017): Coral reefs as the first line of defense: Shoreline protection in face of climate change: Marine Environmental Research 127, 148-154.
80. Lambeck, K., Rouby, H., Purcell, A., Sun, Y., Sambridge, M. (2014): Sea level and global ice volumes from the Last Glacial Maximum to the Holocene: Proceedings of the National Academy of Sciences 111 (43), 15296-15303.
81. Klimaretter.info (2014): Kiribati kauft Land für Klimaflüchtlinge: 22.6.2014, http://www.klimaretter.info/wohnen/hintergrund/16608-kiribati-kauft-land-fuer-klimafluechtlinge
82. Webb, A. P., Kench, P. S. (2010): The dynamic response of reef islands to sea-level rise: Evidence from multi-decadal analysis of island change in the Central Pacific: Global and Planetary Change 72, 234-246.
83. Kench, P. S., Ford, M. R., Owen, S. D. (2018): Patterns of island change and persistence offer alternate adaptation pathways for atoll nations: Nature Communications 9 (1), 605.
84. Kench, P. S., Thompson, D., Ford, M. R., Ogawa, H., McLean, R. F. (2015): Coral islands defy sea-level rise over the past century: Records from a central Pacific atoll: Geology 43 (6), 515-518.
85. Mann, T., Bayliss-Smith, T., Westphal, H. (2016): A Geomorphic Interpretation of Shoreline Change Rates on Reef Islands: Journal of Coastal Research 32 (3), 500-507, 508.
86. ZMT (2016): Versinkende Inseln: Bedroht der Meeresspiegelanstieg das Takuu-Atoll im Pazifik?: 30.1.2016, https://www.leibniz-zmt.de/de/neuigkeiten/nachrichten-aktuelles/archiv-news/30-1-16-versinkende-inseln-bedroht-der-meeresspiegelanstieg-das-takuu-atoll-im-pazifik.html
87. Ford, M. (2013): Shoreline changes interpreted from multi-temporal aerial photographs and high resolution satellite images: Wotje Atoll, Marshall Islands: Remote Sensing of Environment 135, 130-140.
88. Ford, M. R., Kench, P. S. (2016): Spatiotemporal variability of typhoon impacts and relaxation intervals on Jaluit Atoll, Marshall Islands: Geology 44 (2), 159-162.
89. Kench, P. S., McLean, R. F., Owen, S. D., Tuck, M., Ford, M. R. (2018): Storm-deposited coral blocks: A mechanism of island genesis, Tutaga island, Funafuti atoll, Tuvalu: Geology 46 (10), 915-918.
90. Geological Society of America (2018): Catastrophic construction: Storms can build reef islands in atoll regions: 17.9.2018, https://www.geosociety.org/GSA/News/pr/2018/18-31.aspx
91. Die Presse (2014): Geomorphologie: Das Klima lässt die Inseln nicht untergehen!: 4.8.2014, https://www.diepresse.com/3849398/geomorphologie-das-klima-lasst-die-inseln-nicht-untergehen
92. Biribo, N., Woodroffe, C. D. (2013): Historical area and shoreline change of reef islands around Tarawa Atoll, Kiribati: Sustainability Science 8 (3), 345-362.
93. Duvat, V. K. E. (2019): A global assessment of atoll island planform changes over the past decades: WIREs Climate Change 10 (1), e557.
94. University of Southampton (2015): Mangroves help protect against sea level rise: 23.7.2015, https://www.southampton.ac.uk/news/2015/07/mangroves-help-protect-against-sea-level-rise.page
95. Huang, T., Rapp, H. (2010): Coastal Erosion on MajuroAtoll, Marshall Islands: MSc Thesis, Lund University, http://lup.lub.lu.se/luur/download?func=downloadFile&recordOId=1670491&fileOId=1670494
96. Ford, M. (2012): Shoreline Changes on an Urban Atoll in the Central Pacific Ocean: Majuro Atoll, Marshall Islands: Journal of Coastal Research, 11-22.
97. Xue, C. (2001): Coastal Erosion and Management of Majuro Atoll, Marshall Islands Journal of Coastal Research 17 (4), 909-918.
98. Shenk, J. (2011): The Island Pesident: Dokumentarfilm, produziert von Actual Films, https://en.wikipedia.org/wiki/The_Island_President
99. Dunne, R. P., Barbosa, S. M., Woodworth, P. L. (2012): Contemporary sea level in the Chagos Archipelago, central Indian Ocean: Global and Planetary Change 82-83, 25-37.
100. Florida Tech (2015): New Study from Florida Tech Finds Pacific Reef Growth Can Match Rising Sea: 22.7.2015, https://newsroom.fit.edu/2015/07/22/new-study-from-florida-tech-finds-pacific-reef-growth-can-match-rising-sea/
101. Woesik, R. v., Golbuu, Y., Roff, G. (2015): Keep up or drown: adjustment of western Pacific coral reefs to sea-level rise in the 21st century: Royal Society Open Science 2 (7), 150181.
102. Donner, S. D. (2015): Sind Inselstaaten akut gefährdet?: Spektrum.de, 19.5.2015, https://www.spektrum.de/magazin/sind-inselstaaten-akut-gefaehrdet/1343335
103. University of Auckland (2019): Sea level rise may not drown low-lying Pacific atolls: 16.7.2019, https://www.scimex.org/newsfeed/sea-level-rise-may-not-spell-the-end-for-low-lying-pacific-atolls
104. Tuck, M. E., Kench, P. S., Ford, M. R., Masselink, G. (2019): Physical modelling of the response of reef islands to sea-level rise: Geology 47 (9), 803-806.
105. Kelman, I., Orlowska, J., Upadhyay, H., Stojanov, R., Webersik, C., Simonelli, A. C., Procházka, D., Němec, D. (2019): Does climate change influence people’s migration decisions in Maldives?: Climatic Change 153 (1), 285-299.
106. Herald Sun (2018): Who are the real ‚Deniers‘, Fran?: 18.10.2018, https://www.heraldsun.com.au/blogs/andrew-bolt/who-are-the-real-deniers-fran/news-story/16c8da4aee1bfc53c15ae47b804f9b71
107. Inside Climate News (2017): An Island Nation Turns Away from Climate Migration, Despite Rising Seas: 20.11.2017, https://insideclimatenews.org/news/20112017/kiribati-climate-change-refugees-migration-pacific-islands-sea-level-rise-coconuts-tourism
108. Kaltesonne.de (2017): Leiterin des ARD-Afrika-Studios Nairobi liegt in Ghana voll daneben: Peinliche Verwechslung von Küstenströmungen mit Klimawandel: 14.6.2017, https://kaltesonne.de/leiterin-des-afrika-studios-nairobi-liegt-in-ghana-voll-daneben-peinliche-verwechslung-von-kustenstromungen-mit-klimawandel/
109. Kaltesonne.de (2019): Um Antwort wird gebeten: Der Fall „Ghoramara“: 25.1.2019, https://kaltesonne.de/um-antwort-wird-gebeten-der-fall-ghoramara/
110. Kaltesonne.de (2017): SRF-Afrika-Korrespondent Wülsner liegt in Ghana voll daneben: Peinliche Verwechslung von Küstenströmungen mit Klimawandel: 14.1.2017, https://kaltesonne.de/srf-afrika-korrespondent-wulsner-liegt-in-ghana-voll-daneben-verwechslung-von-kustenstromungen-mit-klimawandel/
111. Jun, Y., Meng, R., Johar, G. V. (2017): Perceived social presence reduces fact-checking: Proceedings of the National Academy of Sciences 114 (23), 5976-5981.
112. Lamont-Doherty Earth Observatory (2018): Urbanization Is Cutting off Life Support to NYC’s Wetlands: 24.9.2018, https://www.ldeo.columbia.edu/news-events/urbanization-cutting-life-support-nyc%E2%80%99s-wetlands
113. Duke University (2015): Coastal Marshes More Resilient to Sea-Level Rise Than Previously Believed: 18.12.2015, https://today.duke.edu/2015/12/marshresilience
114. Kirwan, M. L., Temmerman, S., Skeehan, E. E., Guntenspergen, G. R., Fagherazzi, S. (2016): Overestimation of marsh vulnerability to sea level rise: Nature Climate Change 6 (3), 253-260.
115. Virginia Institute of Marine Science (2016): Study predicts salt marshes will persist despite rising seas: 24.2.2016, https://www.vims.edu/newsandevents/topstories/2016/salt_marsh_resilience.php
116. Villanova University (2018): New Study by Villanova University Biologists Finds Mangrove Expansion may Help Coastal Ecosystems Keep Pace with Sea Level Rise in Warmer Future: 29.8.2018, https://www1.villanova.edu/villanova/media/pressreleases/2018/0829.html
117. Donchyts, G., Baart, F., Winsemius, H., Gorelick, N., Kwadijk, J., van de Giesen, N. (2016): Earth’s surface water change over the past 30 years: Nature Climate Change 6 (9), 810-813.
118. Luijendijk, A., Hagenaars, G., Ranasinghe, R., Baart, F., Donchyts, G., Aarninkhof, S. (2018): The State of the World’s Beaches: Scientific Reports 8 (1), 6641.
119. Hanebuth, T. J. J., Kudrass, H. R., Linstädter, J., Islam, B., Zander, A. M. (2013): Rapid coastal subsidence in the central Ganges-Brahmaputra Delta (Bangladesh) since the 17th century deduced from submerged salt-producing kilns: Geology 41 (9), 987-990.
120. Zou, L., Kent, J., Lam, N. S.-N., Cai, H., Qiang, Y., Li, K. (2016): Evaluating Land Subsidence Rates and Their Implications for Land Loss in the Lower Mississippi River Basin: Water 8 (1), 10.
121. Higgins, S. A., Overeem, I., Steckler, M. S., Syvitski, J. P. M., Seeber, L., Akhter, S. H. (2014): InSAR measurements of compaction and subsidence in the Ganges-Brahmaputra Delta, Bangladesh: Journal of Geophysical Research: Earth Surface 119 (8), 1768-1781.
122. Shirzaei, M., Bürgmann, R. (2018): Global climate change and local land subsidence exacerbate inundation risk to the San Francisco Bay Area: Science Advances 4 (3), eaap9234.