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2021 β10.9 β8.9 2051 12.3 27.9 2081 42.6 91.8 2111 75.6 177.2 |
2022 β10.2 β7.9 2052 13.2 29.7 2082 43.7 94.5 2112 76.7 180.3 |
2023 β9.5 β6.9 2053 14.1 31.6 2083 44.8 97.2 2113 77.9 183.5 |
2024 β8.8 β5.9 2054 15 33.5 2084 45.9 100 2114 79 186.8 |
2025 β8.1 β4.9 2055 15.9 35.4 2085 47.1 102.8 2115 80.1 190.1 |
2026 β7.4 β3.9 2056 16.8 37.3 2086 48.2 105.6 2116 81.2 193.4 |
2027 β6.7 β2.9 2057 17.7 39.3 2087 49.3 108.5 2117 82.2 196.8 |
2028 β6 β1.9 2058 18.6 41.2 2088 50.3 111.3 2118 83.3 200.2 |
2029 β5.3 β0.9 2059 19.5 43.2 2089 51.4 114.2 2119 84.4 203.7 |
2030 β4.6 0.2 2060 20.4 45.2 2090 52.4 117.2 2120 85.4 207.2 |
2031 β3.9 1.2 2061 21.4 47.1 2091 53.4 120.1 |
2032 β3.2 2.2 2062 22.3 49 2092 54.4 123 |
2033 β2.6 3.2 2063 23.3 51 2093 55.4 125.9 |
2034 β1.9 4.3 2064 24.3 52.9 2094 56.3 128.9 |
2035 β1.2 5.3 2065 25.3 54.9 2095 57.3 131.8 |
2036 β0.5 6.4 2066 26.3 56.9 2096 58.3 134.7 |
2037 0.2 7.6 2067 27.3 58.9 2097 59.3 137.6 |
2038 0.9 8.7 2068 28.3 60.9 2098 60.3 140.5 |
2039 1.6 9.9 2069 29.4 63 2099 61.3 143.3 |
2040 2.4 11.2 2070 30.4 65.2 2100 62.4 146.2 |
2041 3.2 12.4 2071 31.5 67.3 2101 63.5 148.9 |
2042 4.1 13.8 2072 32.6 69.6 2102 64.7 151.7 |
2043 5 15.1 2073 33.6 71.8 2103 65.9 154.4 |
2044 5.9 16.6 2074 34.7 74.2 2104 67.1 157.1 |
Appendix C. Mean Sea Level in Florida Bay |
MSL was determined by averaging data over the last seven years at three sea level stations across |
Florida Bay. Sea levels were first aggregated into daily averages, followed by a 30-day moving average |
at each station. The MSL estimate consists of an average of these three stations from 1 July 2008β1 July |
2015, as shown in Figure A1, and this MSL value of 0.97 ft NGVD29 or β14.8 cm NAVD88 (β0.49 feet |
NAVD88) is used as the starting point of the projections in 2015. |
J. Mar. Sci. Eng. 2017, 5, 31 21 of 26 |
Figure A1. Thirty-day moving averages of daily mean sea level at Murray Key (MK), Peterson Key |
(PK) and Little Madeira Bay (LM) in Florida Bay. The dashed line is the mean of all three datasets. |
Appendix D. Processes Not Included in the Projections |
The mean sea level projections presented in this paper represent the contemporary state-of-the-art |
in local sea level rise forecasts. However, knowledge of all processes and feedbacks driving sea levels |
is limited, and the models on which these projections are based are necessarily incomplete. The models |
do not have the spatial resolution and physical process representation required to resolve fine-scale |
oceanographic processes such as tides and changes in the Florida Current. This means that inundation |
will be observed during high tides and peaks of seasonal sea level cycles several years before the |
projected dates when mean sea level reaches a specific land elevation. |
Appendix D.1. Tides and Seasonal Cycles |
Tides represent the most regular and familiar sea level changes at a coast, but are highly variable |
in height and timing depending on regional and local bathymetric features. Along the Cape Sable |
region, tides produce a water level change of up to 70 cm (2.3 ft) in daily and monthly cycles. There is |
also a regional yearly cycle of water level from atmospheric and oceanographic forcings producing |
water level changes of 30β40 cm (Appendix C). |
Appendix D.2. Florida Current |
The Florida Current is one of the strongest and most climatically-important ocean currents forming |
the headwater of the Gulf Stream [39]. As the Florida Current fluctuates in intensity, sea levels along |
the Atlantic coast of Florida respond to a geostrophic balance by falling when the current increases |
and rising when the current decreases [40]. |
The Gulf Stream and Florida Current are components of the Atlantic Meridional Overturning |
Circulation (AMOC), a component of the global ocean conveyor belt. Climate models agree that as the |
ocean warms and fresh meltwater is added, there will be a decline in the strength of the AMOC [41]. |
A weakening AMOC is expected to result in a weakening of the Florida Current and a subsequent |
increase in sea levels. The extent of this change is difficult to forecast, but recent evidence suggests that |
a 10% decline in transport has contributed 60% of the roughly 7-cm increase in sea level at Vaca Key |
over the last decade [10]. Continued reduction of the AMOC and Florida Current could be expected to |
contribute an additional 10β15 cm of sea level rise to South Florida over this century. This potential is |
J. Mar. Sci. Eng. 2017, 5, 31 22 of 26 |
not reflected in the sea level rise projections, but should be considered by authorities and planners that |
use them. |
Appendix D.3. Storm Surge |
Although sea level rise and increases in coastal flooding are important physical stresses on South |
Floridaβs natural areas, it is the infrequent, high-impact storm surge events that drastically change |
the landscape over the course of a few hours. For example, Hurricane Wilma in 2005 had a profound |
impact on the ecology of the Cape Sable region of Everglades National Park [42,43] producing extensive |
damage at the Flamingo Visitor Center of Everglades National Park, permanently closing the Flamingo |
Lodge and Buttonwood Cafe. |
Storm surge is highly dependent on the severity and path of the storm, as well as the local |
bathymetric and topographic features of the coast, and since they occur infrequently, it is difficult |
to develop robust predictions of these rare events. A popular approach is to fit an extreme-value |
probability distribution to the highest water levels observed at a water level monitoring gauge. |
However, gauges have short periods of record, typically a few decades at most, and they fail or are |
destroyed during extreme storms such that peak water levels are not recorded. A predictive storm |
surge database, SurgeDat, was developed in part to address this shortcoming by providing a statistical |
combination of data from multiple events within an area of interest [44]. SurgeDat records storm surge |
water levels from all available sources, often from post-event high-water marks where gauge data |
are not available. SurgeDat then applies a statistical regression to estimate storm surge recurrence |
intervals. A recurrence interval is the length of time over which one can expect a storm surge to meet |
or exceed a specific inundation level. A familiar example is the 100-year flood level, which is really |
a 100-year recurrence interval at the specified flood level. In other words, in any one year, there is a |
1/100, or 1% chance that the flood level will be matched or exceeded. An excellent discussion of this |
can be found at the United States Geological Survey web page water.usgs.gov/edu/100yearflood.html. |
Relevant to South Florida, a subset of SurgeDat storm surge events was selected within a 25-mile |
radius of 25.2β¦ N, 80.7β¦ W to represent Florida Bay impacts and is tabulated in Table A3. Based on |
these events, the SurgeDat projection for storm surge recurrence intervals are shown in Figure A2 and |
tabulated in Table A4, suggesting that a 180-cm (6 ft) surge event can be expected every 20 years. This |
same level of sea level rise is not anticipated to occur until at least 2100. |
Table A3. SurgeDat database entries for a 25-mile radius centered on 25.2β¦ N, 80.7β¦ W in Florida Bay. |
Storm Name Year Longitude Latitude Surge (m) Datum Location |
Katrina 2005 β81.0369 25.1294 1.22 Extreme SW Florida |
Rita 2005 β80.7200 24.8605 1.22 NGVD29 Middle and Upper Keys |
Wilma 2005 β81.0352 25.3523 2.50 Shark River 3 |
Gordon 1994 β80.5139 25.0108 1.22 Above Sea Level Upper Florida Keys |
Andrew 1992 β80.9120 25.1431 1.50 Flamingo |
David 1979 β80.6263 24.9231 0.61 Above Normal Islamorada |
Gladys 1968 β80.5135 25.0110 0.15 Above Normal Tavernier |
Inez 1966 β80.5297 24.9976 1.10 Above Normal Plantation Key |
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