Variability of Extreme Wet Events over Malawi

  • Brigadier Libanda School of Civil Engineering and Geosciences, Newcastle University
  • Mie Zheng School of Civil Engineering and Geosciences, Newcastle University
  • Noel Banda Malawi Department of Climate Change and Meteorological Services
DOI: https://doi.org/10.5937/gp21-16075

Abstract


Adverse effects of extreme wet events are well documented by several studies around the world. These effects are exacerbated in developing countries like Malawi that have insufficient risk reduction strategies and capacity to cope with extreme wet weather. Ardent monitoring of the variability of extreme wet events over Malawi is therefore imperative. The use of the Expert Team on Climate Change Detection and Indices (ETCCDI) has been recommended by many studies as an effective way of quantifying extreme wet events. In this study, ETCCDI indices were used to examine the number of heavy, very heavy, and extremely heavy rainfall days; daily and five-day maximum rainfall; very wet and extremely wet days; annual wet days and simple daily intensity. The Standard Normal Homogeneity Test (SNHT) was employed at 5% significance level before any statistical test was done. Trend analysis was done using the nonparametric Mann-Kendall statistical test. All stations were found to be homogeneous apart from Mimosa. Trend results show high temporal and spatial variability with the only significant results being: increase in daily maximum rainfall (Rx1day) over Karonga and Bvumbwe, increase in five-day maximum rainfall (Rx5day) over Bvumbwe. Mzimba and Chileka recorded a significant decrease in very wet days (R95p) while a significant increase was observed over Thyolo. Chileka was the only station which observed a significant trend (decrease) in extremely wet rainfall (R99p). Mzimba was the only station that reported a significant trend (decrease) in annual wet-day rainfall total (PRCPTOT) and Thyolo was the only station that reported a significant trend (increase) in simple daily intensity (SDII). Furthermore, the findings of this study revealed that, during wet years, Malawi is characterised by an anomalous convergence of strong south-easterly and north-easterly winds.  This convergence is the main rain bringing mechanism to Malawi.

References

Alexandersson, H., Moberg, A. 1977. Homogenization of Swedish temperature data. Part I: homogeneity test for linear trends. International Journal of Climatology 17:25–34. doi:10.1002/(SICI)1097-0088(199701)17:1<25::AID-JOC103>3.0.CO;2-J

BBC. 2015. Malawi floods kill 170 and leave thousands homeless - BBC News. [online] Available at: http://www.bbc.co.uk/news/world-africa-30854140 [Accessed 6 Jun. 2017].

Benin, S., Thurlow, J., Diao, X., McCool, C., Simtowe, F. 2008. Agricultural growth and investment options for poverty reduction in Malawi. IFPRI Discussion Paper No. 00794 [online] Available at: http://ebrary.ifpri.org/cdm/ref/collection/p15738coll2/id/13440.

Benson, C., Clay, E., 1998. Drought and Sub-Saharan African Economies. Africa Region Findings & Good Practice Infobriefs; No. 118. World Bank, Washington, DC.

Bouwer, L. 2011. Have Disaster Losses Increased Due to Anthropogenic Climate Change? Bulletin of the American Meteorological Society, 92(1), pp.39-46.

Bradshaw, C., Sodhi, N., Peh, K., Brook, B. 2007. Global evidence that deforestation amplifies flood risk and severity in the developing world. Global Change Biology, 13(11), pp.2379-2395.

Christensen, J. 2007. Climate change 2007: the physical science basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge: Cambridge University Press, chapter Regional climate projections. pp. 847—940

Davies, R. 2017. Malawi - Floods in Karonga District Leave 4 Dead, Crops Destroyed - FloodList. [online] Available at: http://floodlist.com/africa/malawi-floods-karonga-april-2017 [Accessed 30 May 2017].

González-Rouco, J., Jiménez, J., Quesada, V., Valero, F. 2001. Quality Control and Homogeneity of Precipitation Data in the Southwest of Europe. Journal of Climate, 14(5), pp.964-978.

Hoell, A., Funk, C., Magadzire, T., Zinke, J., Husak, G. 2014. El Niño–Southern Oscillation diversity and Southern Africa teleconnections during Austral Summer. Climate Dynamics, 45(5-6), pp.1583-1599.

IPCC. 2012. Managing the risks of extreme events and disasters to advance climate change adaptation. A special report of working groups I and II of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, 996 pp

IPCC. 2014. Climate change (2007): synthesis report. Contribution of working groups I, II and III to the fifth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, 996

IPCC. 2001. Climate Change: The Scientific Basis. Contribution of Working Group 1 to the Third Assessment report of the Intergovernmental Panel on Climate Change. International Journal of Epidemiology, 32(2), pp.321-321.

IPCC. 2013. Climate Change: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change.

Javari, M. 2016. Trend and Homogeneity Analysis of Precipitation in Iran. Climate, 4(3), p.44.

Juma, B. 2017. Malawi - Floods in Northern Region Leave Several Dead and Force Thousands to Evacuate - FloodList. [online] Available at: http://floodlist.com/africa/malawi-floods-mzuzu-karonga-april-2016 [Accessed 30 May 2017].

Jury, M. 2013. Variability in the Tropical Southwest Indian Ocean and Influence on Southern African Climate. International Journal of Marine Science.

Jury, M., Gwazantini, M. 2002. Climate variability in Malawi, part 2: sensitivity and prediction of lake levels. International Journal of Climatology, 22(11), pp.1303-1312.

Kang, H.M., Fadhilah, Y. 2012 Homogeneity Tests on Daily Rainfall Series in Peninsular Malaysia. International Journal of Contemporary Mathematical Sciences, 7(1), 9 – 22.

Karl, P., Thurlow, J., Seventer, D.V. 2010. Droughts and Floods in Malawi Assessing the Economywide Effects. IFPRI Discussion Paper No. 00962 [online] Available at: http://www.ifpri.org/publication/droughts-and-floods-malawi [Accessed 30 May 2017].

Karl, T.R., Nicholls, N., Ghazi, A. 1999. CLIVAR/GCOS/WMO workshop on indices and indicators for climate extremes: workshop summary. Climate Change 42:3–7. doi:10.1023/A:1005491526870

Kaser, G. Hardy, D. Mölg, T. Bradley, R., Hyera, T. 2004. Modern glacier retreat on Kilimanjaro as evidence of climate change: observations and facts. International Journal of Climatology, 24(3), pp.329-339.

Kazembe, A., 2014. Determining the onset and cessation of seasonal rains in Malawi. Postgraduate thesis submitted to the Department of Meteorology, School of Physical Sciences, University of Nairobi. Available at: http://erepository.uonbi.ac.ke/bitstream/handle/11295/95407/Kazembe_Determining%20the%20onset%20and%20cessation%20of%20seasonal%20rains%20in%20Malawi.pdf?sequence=1&isAllowed=y

Kendall, M.G. 1975. Rank correlation methods, 4th edn. Griffin, London

Kumbuyo, C., Yasuda, H., Kitamura, Y., Shimizu, K. 2014. Fluctuation of rainfall time series in Malawi: An analysis of selected areas. Geofizika, 31(1), pp.13-28.

Lee, G., Helling, C., Dobbs-Dixon, I., Juncher, D., 2015. Modelling the local and global cloud formation on HD 189733b. Astronomy & Astrophysics, 580, p.A12.

Libanda, B., David, A., Banda, N., Wang, L., Ngonga, C., Linda, N. 2017. Predictor Selection Associated with Statistical Downscaling of Precipitation over Zambia. Asian Journal of Physical and Chemical Sciences. 1(2): 1-9, DOI: 10.9734/AJOPACS/2016/31545

Libanda, B., Nkolola, B., Musonda, B. 2015a. Rainfall Variability over Northern Zambia. Journal of Scientific Research & Reports, DOI:10.9734/JSRR/2015/16189

Libanda, B., Ogwang, B.A., Ongoma, V., Chilekana, N., Nyasa, L. 2015b. Diagnosis of the 2010 DJF flood over Zambia. Natural Hazards. DOI 10.1007/s11069-015-2069-z

Loomis, R. 1999. Feeding a World Population of More than Eight Billion People: A Challenge to Science. Crop Science, 39(4), p.1250.

Majidi, M., Alizadeh, A., Farid, A., Vazifedoust, M. 2015. Estimating Evaporation from Lakes and Reservoirs under Limited Data Condition in a Semi-Arid Region. Water Resources Management, 29(10), pp.3711-3733.

Mann, H.B. 1945. Non-parametric tests against trend. Econometrica 13:245–259.

Metmalawi, 2017. Malawi Meteorological Services. [online] Available at: http://www.metmalawi.com/climate/climate.php [Accessed 28 May 2017].

Mokrech, M., Kebede, A.S., Nicholls R.J., Wimmer, F., Feyen, L. 2014. An integrated approach for assessing flood impacts due to future climate and socio-economic conditions and the scope of adaptation in Europe, Climatic Change, 128(3-4), pp. 245–260.

ND-GAIN, 2017. Malawi | ND-GAIN Index. [online] Available at: http://index.gain.org/country/malawi [Accessed 7 Jun. 2017].

Ngongondo, C. 2006. An analysis of long-term rainfall variability, trends and groundwater availability in the Mulunguzi river catchment area, Zomba mountain, Southern Malawi. Quaternary International, 148(1), pp.45-50.

Ngongondo, C., Xu, C., Gottschalk, L., Alemaw, B. 2011. Evaluation of spatial and temporal characteristics of rainfall in Malawi: a case of data scarce region. Theoretical and Applied Climatology, 106(1-2), pp.79-93.

Ngwira A, Aune J, and Thierfelder C, (2014) DSSAT modelling of conservation agriculture maize response to climate change in Malawi. Soil and Tillage Research, 143, pp.85-94.

Nicholas N, and Wassila T, (2017) [online] Available at: http://www.cpc.ncep.noaa.gov/products/fews/AFR_CLIM/AMS_ARC2a.pdf [Accessed 30 May 2017].

Nicholson, S. 2000. The nature of rainfall variability over Africa on time scales of decades to millenia. Global and Planetary Change, 26(1-3), pp.137-158.

Nicholson, S., Klotter, D., Chavula, G. 2013. A detailed rainfall climatology for Malawi, Southern Africa. International Journal of Climatology, 34(2), pp.315-325.

Nicholson S.E., Yin X. 2002. Mesoscale patterns of rainfall, cloudiness and evaporation over the Great Lakes of Africa. In The East African Great Lakes: Limnology, Palaeolimnology and Biodiversity, Odada EO, Olago DO (eds). Kluwer Academic Publishers: Dordrecht, Holland. 93–119.

Ogwang, B.A., Guirong, T., Haishan, C. 2012. Diagnosis of September - November drought and the associated circulation anomalies over Uganda. Pakistan J Meteorol 9:11–24

Ongoma, V., Chen, H., Omony, G. 2016. Variability of extreme weather events over the equatorial East Africa, a case study of rainfall in Kenya and Uganda. Theoretical and Applied Climatology doi:10.1007/s00704-016-1973-9

Sen P.K. 1968. Estimates of the regression coefficient based on Kendall’s Tau. Journal of American Statistical Association 63:1379–1389. doi:10.2307/2285891

Vörösmarty, C., McIntyre, P., Gessner, M., Dudgeon, D., Prusevich, A., Green, P., Glidden, S., Bunn, S., Sullivan, C., Liermann, C., Davies, P., 2010. Global threats to human water security and river biodiversity. Nature, 467(7315), pp.555-561.

Westra, S., Fowler, H., Evans, J., Alexander, L., Berg, P., Johnson, F., Kendon, E., Lenderink, G., Roberts, N. 2014. Future changes to the intensity and frequency of short-duration extreme rainfall. Reviews of Geophysics, 52(3), pp.522-555.

Zaroug, M., Eltahir, E., Giorgi, F. 2014. Droughts and floods over the upper catchment of the Blue Nile and their connections to the timing of El Niño and La Niña events. Hydrology and Earth System Sciences, 18(3), pp.1239-1249.

Published
2017/12/19
Issue
Vol. 21 No. 4 (2017)
Section
Original Research