1. International Conference on Climate Change Impact of Sea Level Rise on storm surge in Hong Kong and the Pearl River Delta by WONG, Agnes K.M. LAU, Alexis K.H. GRAY, Joseph P. (The Hong Kong University of Science and Technology) 31 May 2007

2. Did you know that the Pearl River Delta is already under threat from severe flooding?

3. Guangzhou in flood due to heavy rain.

4. Guangzhou in flood due to astronomical tide: School is cancelled for 100,000 students 190 flood events have been recorded in PRD over the last 40 years (Huang et al, 2004) June 2005 NOT rain related

5. Coastal Flooding Astronomical tide Shape of coast Accumulated rain water Tropical cyclone Global warming (sea level rise)  Storm surge

6.  The abnormal rise in the ocean level associated with typhoon landfall. Storm Surge

7. Global Situation Intergovernmental Panel on Climate Change (IPCC) report in 2007:  An average rate of 1.8mm/yr for 1961-2003  Faster rate of 3.1mm/yr for 1993-2003  Total sea level rise for 20th century is estimated to be 0.17m

8. Time series of global mean sea level IPCC 2007 10cm 22cm

9. Local Situation The observed rate of sea level rise in Hong Kong is faster than the global average report by the IPCC (2007) Rate of sea level rise (mm/yr) HK Global (IPCC, 2007) 1961 – 2003 2.81.8 1993 – 2003 7.23.1 (HKO, 2004)

10. IPCC (2007) Report  Storm surges are especially serious when they coincide with high tide. Changes in the frequency of occurrence (i.e. return period ) are affected both by changes in mean sea level and in the meteorological phenomena causing the extremes. There is evidence for an increase in the occurrence of extreme high water worldwide related to storm surges

11. HKO’s findings Hong Kong Observatory (HKO) research in 2004:  The 50 yr return period would be shortened to about 3 yrs if the sea level rises by 48cm in 2100  A 50yr event could even become an annual event if sea level rises by 88cm

12. Practical use of return period  Formation levels for reclamations - streets and pavements  Flood defence levels for critical facilities - building basements, MTR  Crest levels for seawalls and river banks  Tailwater levels and other hydraulic design - stormwater and sewage systems S. Buttling & M.L. Chalmers

13.  Normally, the extreme environmental conditions for structures having a design life of 50 years should be taken as those having return periods of 100 years. Design Life Port Works Design Manual : Part 1

14. Objective of this study To see how the probability of destructive flooding ( return period of extreme flooding events ) changes with increasing mean sea level To understand the relationship between sea level rise and storm surge

15. Data  Sea Level records around HK from HKO  Period: 1965 - 2006

16. Methodology  Gumbel cumulative distribution - extreme value type I  Parameter estimation with the moment method It is used to find the maximum of a number of samples of various distributions. It is useful in predicting the chance that an extreme flood will occur.

17. 20 yr 100 yr Significant increase in extreme value in last 20 years Extreme value ranged between 3 to 4 meters

18. Current 20 year event IPCC Sea level rise estimate for 2050 IPCC Sea level rise estimate for 2100 If the MSL reaches the lower limit of IPCC’s predication for 2050, a 20-yr event would become a 10-yr event If the MSL reaches the lower limit of IPCC’s predication for 2100, the return period would be decreased to less than 5 yrs Current return period for a 3.2 m event (20 yr)

19. Current 100 year event IPCC Sea level rise estimate for 2050 IPCC Sea level rise estimate for 2100 If the MSL reach the lower limit of IPCC’s predication for 2050, the structure’s design life would be halved Event level used for a marine work with a 50yr design life If the MSL reach the lower limit of IPCC’s predication for 2100, the structure’s design life would be reduced by roughly 75%

20. Population annually affected by flood Robert J. Nicholls 2004 Constant Protection In Phase Evolving Protection

21. Land Use Map in PRD Red – highly developed area Current Situation

22. Land Use Map in PRD Red – highly developed area Flooding of 3m

23. Land Use Map in PRD Red – highly developed area Flooding of 4m

24. Economic Impacts RegionPredicted losses for a 30cm rise (2000) in RMB Predicted losses for a 30cm rise (2030) in RMB Predicted losses for a 1m rise (2000) in RMB Predicted losses for a 1m rise (2030) in RMB PRD22.6 Billion56 Billion104.4 Billion262.5 Billion Economic Losses from sea level rise in the PRD Warrick, Barrow & Wigley

25. Summary & Discussion The PRD is already susceptible to severe flooding The observed sea level rise in the region is faster than the global average The sea level rise projected by the IPCC results in a significant decrease in the return period in the region, implying a significant reduction of the design life of coastal constructions We need to act swiftly to mitigate the flooding potential caused by climate change

26. Action Items Building regulations should be reviewed to reflect the potential risks related to climate change Environmental responsible policies should be adopted to reduce our contribution to Global Warming Further research work should be done to better understand the rise of sea level and its impact on the region

27. Acknowledgment  Prof. S.C. Kot for his guidance  Dr. Jimmy Chan for his graphics  Hong Kong Observatory for provision of historical sea level data around Hong Kong