Sea Level Change. Mark A. Merrifield. Lead Author, AR5, Chapter 13. Yann Arthus-Bertrand / Altitude

Sea Level Change Mark A. Merrifield Lead Author, AR5, Chapter 13 Yann Arthus-Bertrand / Altitude

Third Order Draft Chapter 13 IPCC WGI Fifth Assessment Report Chapter 13: Sea Level Change Coordinating Lead Authors: John A. Church (Australia), Peter U. Clark (USA) Lead Authors: Anny Cazenave (France), Jonathan M. Gregory (UK), Svetlana Jevrejeva (UK), Anders Levermann (Germany), Mark A. Merrifield (USA), Glenn A. Milne (Canada), R. Steven Nerem (USA), Patrick D. Nunn (Australia), Antony J. Payne (UK), W. Tad Pfeffer (USA), Detlef Stammer (Germany), Alakkat S. Unnikrishnan (India) Contributing Authors: David Bahr (USA), Jason E. Box (USA), David H. Bromwich (USA), Mark Carson (Germany), William Collins (UK), Xavier Fettweis (Belgium), Piers Forster (UK), Alex Gardner (USA), W. Roland Gehrels (UK), Rianne Giesen (Netherlands), Peter J. Gleckler (USA), Peter Good (UK), Rune Grand Graversen (Sweden), Ralf Greve (Japan), Stephen Griffies (USA), Edward Hanna (UK), Mark Hemer (Australia), Regine Hock (USA), Simon J. Holgate (UK), John Hunter (Australia), Philippe Huybrechts (Belgium), Gregory Johnson (USA), Ian Joughin (USA), Georg Kaser (Austria), Caroline Katsman (Netherlands), Leonard Konikow (USA), Gerhard Krinner (France), Anne Le Brocq (UK), Jan Lenaerts (Netherlands), Stefan Ligtenberg (Netherlands), Christopher M. Little (USA), Ben Marzeion (Austria), Kathleen L. McInnes (Australia), Sebastian H. Mernild (USA), Didier Monselesan (Australia), Ruth Mottram (Denmark), Tavi Murray (UK), Gunnar Myhre (Norway), J.P. Nicholas (USA), Faezeh Nick (Norway), David Pollard (USA),Valentina Radi (Canada), Jamie Rae (UK), Markku Rummukainen (Sweden), Christian Schoof (Canada), Aimée Slangen (Netherlands), Jan H. van Angelen (Netherlands), Willem Jan van de Berg (Netherlands), Michiel van den Broeke (Netherlands), Miren Vizcaíno (Netherlands), Yoshihide Wada (Netherlands), Neil J. White (Australia), R.Winkelmann (Germany),!Jianjun Yin (USA), Masakazu Yoshimori (Japan), Kirsten Zickfeld (Canada) Review Editors: Jean Jouzel (France), Roderik van de Wal (Netherlands), Philip L. Woodworth (UK), Cunde Xiao (China)

Fig. 13.1 Fig. 13.1 AR5 advancements: incorporation of ice dynamics in projections assessment of regional sea level change

Global mean sea level (GMSL) the instrumental record Tide gauges Paleo records Satellite altimetry It is virtually certain that the rate of global mean sea level rise has increased from the 19th to the 20th century. Fig. 13.3e It is very likely that the mean rate was 1.7 [1.5 1.9] mm yr 1 between 1901 and 2010 for a total sea level rise of 0.19 [0.17 0.21] m. Between 1993 and 2010, the rate was very likely higher at 3.2 [2.8 3.6] mm yr 1. Text from the report highlighted in blue.

Contributions to global mean sea level rise (GMSLR) Observations since 1971 indicate that thermal expansion and glaciers (excluding the glaciers in Antarctica) explain 75% of the observed rise (high confidence). The contribution of the Greenland and Antarctic ice sheets has increased since the early 1990s, partly from increased outflow induced by warming of the immediately adjacent ocean. Since 1993, when observations of all sea level components are available, the sum of contributions equals the observed global mean sea level rise within uncertainties (high confidence).

Contributions to global mean sea level rise (GMSLR) 1993-2010 Data from Tab. 13.1 Fig. 13.6 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 61 63 Since 1993, when observations of all sea level components are available, the sum of contributions equals the observed global mean sea level rise within uncertainties (high confidence).

Models of global mean sea level rise (GMSLR) Fig. 13.7a,b Process-based model calculations of contributions to past sea level change from ocean thermal expansion, glacier mass loss and Greenland ice-sheet surface mass balance are consistent with available observational estimates over recent decades.

Process-based model projections of global mean sea level Fig. 13.8 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 The process-based projections of GMSL rise for each RCP scenario are based on results from 21 CMIP5 AOGCMs from which projections of surface air temperature (SAT) change and thermal expansion are available

Process-based model projections of global mean sea level Changes in glacier and ice-sheet SMB are calculated from the global mean SAT projections using parameterisations derived from the results of process-based models of these components. Possible ice-sheet dynamical changes by 2100 are assessed from the published literature, which as yet provides only a partial basis for making projections related to particular scenarios; therefore they are treated as independent of scenario, except that a higher rate of change is used for Greenland ice-sheet outflow under RCP8.5. FAQ13.2, Fig. 1

Results Process-based model projections of global mean sea level Fig. 13.10

Results Process-based model projections of global mean sea level For the period 2081 to 2100, compared to 1986 to 2005, global mean sea level rise is likely (medium confidence) to be in the 5-95% range of process-based models, which give 0.26 0.54 m for RCP2.6, 0.32 0.62 m for RCP4.5, 0.33 0.62 m for RCP6.0, and 0.45 0.81 m for RCP8.5.

Rapid increase in ice sheet outflow Box 13.2 Accelerated outflow Floating ice shelf Icebergs Based on current understanding, only the collapse of marine-based sectors of the Antarctic Ice Sheet, if initiated, could cause global mean sea level to rise substantially above the likely range during the 21st century. Grounded ice sheet Bedrock This potential additional contribution cannot be precisely quantified but there is medium confidence that it would not exceed more than several tenths of a meter of sea level rise during the 21st century.

Semi-empirical model projections of global mean sea level GMSL rise (m) in 2081-2100 relative to 1986-2005 RCP8.5 Likely range Process-based projection Despite their successful calibration and evaluation against the observed 20th century sea level record, there is low agreement in their projections and no consensus in the scientific community about the reliability of SEM projections, and there is low confidence in their projections The colours indicate different types of RCP-derived input data Fig. 13.12d

Projections of regional sea level change 2081-2100 relative to 1986-2000 Glaciers Ice-sheet SMB Fig. 13.20b RCP4.5 0.8 0.4 0.0-0.4 m Regional sea level changes result from ocean dynamical processes, movements of the sea floor, and changes in gravity due to water mass-redistribution (land ice and other terrestrial water storage). Fraction of total coastline excluding Greenland and Antarctica Fig. 13.22b About 70% of the coastlines worldwide are projected to experience sea level change within 20% of the global mean sea level change.

Sea level projections beyond 2100 It is virtually certain that global mean sea level rise will continue beyond 2100, with sea level rise due to thermal expansion to continue for many centuries. Longer term sea level rise depends on future emissions. The few available process-based models indicate global mean sea level rise by 2300 to be less than 1 m for greenhouse gas concentrations that peak and decline and do not exceed 500 ppm CO 2 -equivalent but 1 3 m for concentrations above 700 ppm CO 2 -equivalent (medium confidence). The available evidence indicates that global warming greater than a certain threshold would lead to the nearcomplete loss of the Greenland Ice Sheet over a millennium or more, causing a global mean sea level rise of about 7 m. Studies with fixed ice sheet topography indicate the threshold is greater than 2 C but less than 4 C of global mean surface temperature rise with respect to preindustrial. Fig. SPM.7a

Extreme sea level projections It is very likely that there will be a significant increase in the occurrence of future sea level extremes by 2050 and 2100. This increase will primarily be the result of an increase in mean sea level (high confidence), with the frequency of a particular sea level extreme increasing by an order of magnitude or more in some regions by the end of the 21st century. Fig. 13.25b The estimated multiplication factor (shown at tide gauge locations by red circles and triangles), by which the frequency of flooding events of a given height increase using regional projections of MSL for the RCP 4.5 scenario.

Wind wave projections ~2075-2100 compared with ~1980-2009 In general, there is low confidence in region-specific wind wave projections due to the low confidence in tropical and extratropical storm projections, and to the challenge of downscaling future wind fields from coarse-resolution climate models. Fig. 13.26a-c Percentage difference in a) annual, b) January-March, and c) July-September mean significant wave height.

Fig. 13.27 3 2 1 0 Feet above present sea level Summary Improved observations of recent sea level change models show reasonable agreement 21 st century projections include assessment of ice sheet dynamics Levels above likely range possible if marinebased sectors of Antarctic Ice Sheet collapse likely will add no more than several tenths of a meter during 21 st century Sea level assessments beyond 2100 Regional sea level projections