Abstract
Drier parts of Kenya’s Central Highlands endure persistent crop failure and declining agricultural productivity. These have, in part, attributed to high temperatures, prolonged dry spells and erratic rainfall. Understanding spatial-temporal variability of climatic indices such as rainfall at seasonal level is critical for optimal rain-fed agricultural productivity and natural resource management in the study area. However, the predominant setbacks in analysing hydro-meteorological events are occasioned by either lack, inadequate, or inconsistent meteorological data. Like in most other places, the sole sources of climatic data in the study region are scarce and only limited to single stations, yet with persistent missing/unrecorded data making their utilization a challenge. This study examined seasonal anomalies and variability in rainfall, drought occurrence and the efficacy of interpolation techniques in the drier regions of eastern Kenyan. Rainfall data from five stations (Machang’a, Kiritiri, Kiambere and Kindaruma and Embu) were sourced from both the Kenya Meteorology Department and on-site primary recording. Owing to some experimental work ongoing, automated recording for primary dailies in Machang’a have been ongoing since the year 2000 to date; thus, Machang’a was treated as reference (for period of record) station for selection of other stations in the region. The other stations had data sets of over 15 years with missing data of less than 10 % as required by the world meteorological organization whose quality check is subject to the Centre for Climate Systems Modeling (C2SM) through MeteoSwiss and EMPA bodies. The dailies were also subjected to homogeneity testing to evaluate whether they came from the same population. Rainfall anomaly index, coefficients of variance and probability were utilized in the analyses of rainfall variability. Spline, kriging and inverse distance weighting interpolation techniques were assessed using daily rainfall data and digital elevation model in ArcGIS environment. Validation of the selected interpolation methods were based on goodness of fit between gauged (observed) and generated rainfall derived from residual errors statistics, coefficient of determination (R 2), mean absolute errors (MAE) and root mean square error (RMSE) statistics. Analyses showed 90 % chance of below cropping-threshold rainfall (500 mm) exceeding 258.1 mm during short rains in Embu for 1 year return period. Rainfall variability was found to be high in seasonal amounts (e.g. coefficient of variation (CV) = 0.56, 0.47, 0.59) and in number of rainy days (e.g. CV = 0.88, 0.53) in Machang’a and Kiritiri, respectively. Monthly rainfall variability was found to be equally high during April and November (e.g. CV = 0.48, 0.49 and 0.76) with high probabilities (0.67) of droughts exceeding 15 days in Machang’a. Dry spell probabilities within growing months were high, e.g. 81 and 60 % in Machang’a and Embu, respectively. Kriging interpolation method emerged as the most appropriate geostatistical interpolation technique suitable for spatial rainfall maps generation for the study region.
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References
Aghajani GH (2007) Agronomical analysis of the characteristics of the precipitation (Case study: Sazevar, Iran). Pak J Biol Sci 10(8):1353–1358
Akponikpè PBI, Michels K, Bielders CL (2008) Integrated nutrient management of pearl millet in the Sahel using combined application of cattle manure, crop residues and mineral fertilizer. Exp Agric 46:333–334
Amissah-Arthur A, Jagtap S, Rosen-Zweig C (2002) Spatio-temporal effects of El Niño events on rainfall and maize yield in Kenya. Int J Climatol 22:1849–1860
Anyamba A, Tucker CJ, Eastman JR (2001) NDVI anomaly pattern over Africa during the 1997/98 ENSO warm event. Int J Remote Sens 24:2055–2067
Araya A, Stroosnijder L (2011) Assessing drought risk and irrigation needs in Northern Ethiopia. Agric Water Manag 151:425–436
Barron J, Rockstrom J, Gichuki F, Hatibu N (2003) Dry spell analysis and maize yields for two semi-arid locations in East Africa. Agric Meteorol 17:23–37
Bayazit N (1981) “A comprehensive theory of participation in planning and design (P&D),” Design: Science: Method. IPC Business Press Ltd, Guildford, Surrey, pp 30–47
Belachew A (2000) Dry-spell analysis for studying the sustainability of rain-fed agriculture in Ethiopia: the case of the arbaminch area. Addis Ababa: International Commission on Irrigation and Drainage (ICID). Institute for the Semi-Arid Tropics, and: Direction de la meteorology nationale du Niger. 116p
Botha JJ, Anderson JJ, Groenewald DC, Mdibe N, Baiphethi MN, Nhlabatsi NN, Zere TB (2007) On-farm application of in-field rainwater harvesting techniques on small plots in the Central Region of South Africa. The Water Research Commission Report, South Africa
Burroughs P, McDonald A (1998) Principles of geographical information systems: land resources assessment. Oxford University Press, New York
Cohen JM, Lewis DB (1987) Role of government in combating food shortages: lessons from Kenya 1984–85. In: Glantz MH (Ed) Drought and Hunger in Africa: denying famine a future. Cambridge University Press, Cambridge, pp 269–296
Dai AG, Lamb PJ, Trenberth KE, Hulme M, Jones PD, Xie PP (2004) The recent Sahel drought is real. Int J Climatol 24:1323–1331
Enders CK (2010) Applied missing data analysis. The Guilford Press, New York, ISBN 978-1-60623-639-0
ESRI (2010) The definition of spline interpolation. ESRI: Redlands, CA. http://resources.arcgis.com/glossary/term/2484. Accessed 10th Feb 2015
Hansen JW, Indeje M (2004) Linking dynamic seasonal climate Forecasts with crop simulation for maize yield prediction in semi-arid Kenya. Agric For Meteorol 125:143–157
Heine GW (1986) A controlled study of some two-dimensional interpolation methods. COGS Comput Contrib 3(2):60–72
Huff FA, Changnon Jr SA (1973) Precipitation modification by major urban areas. Bull Am Meteorol Soc 54:1220–1232
Hulme M (2001) Climatic perspectives on SSA desiccation: 1973–1998. Glob Environ Chang 11:19–29
Hutchinson CF (1996) The Sahelian desertification debate: a view from the American South-West. J Arid Environ 33:519–524
Jaetzold R, Schmidt H, Hornet ZB, Shisanya, CA (2007) “Farm management handbook of Kenya”. Natural conditions and farm information, vol 11/C, 2nd ed. Ministry of agriculture/GTZ, Nairobi (Eastern Province)
Jury MR (2002) Economic impacts of climate variability in South Africa and development of resource prediction models. J Appl Meteorol 41:46–55
Kimani SK, Nandwa SM, Mugendi DN, Obanyi SN, Ojiem J, Murwira HK, Bationo A (2003) Principles of integrated soil fertility management. In: Gichuri MP, Bationo A, Bekunda MA, Goma HC, Mafongoya PL, Mugendi DN, Murwuira HK, Nandwa SM, Nyathi P, Swift MJ (eds) Soil fertility management in Africa: a regional perspective. Academy Science Publishers (ASP); Centro Internacional de Agricultura Tropical (CIAT); Tropical Soil Biology and Fertility (TSBF), Nairobi, pp 51–72
KMD, Kenya Meteorological Department, (2015) Climate change and pollution monitoring. [Web]. http://www.meteo.go.ke/cmp/index.html. Accessed 10th Feb 2015
Kosgei JR (2008) Rainwater harvesting systems and their influences on field scale soil hydraulic properties, water fluxes and crop production. Ph.D Thesis. University of KwaZulu-Natal, Pietermaritzburg, South Africa
Kumar KK, Rao TVR (2005) Dry and wet spells at Campina Grande-PB. Rev Brasil Meteorol 20(1):71–74
Li L, Zhang S, Li X, Christie P, Yang S, Tang C (2003) Inter-specific facilitation of nutrient uptakes by intercropped maize and faba bean. Nutr Cycl Agro-ecosyst 65:61–71
MATLAB (Matrix Laboratory) (2013) The Empirical Cumulative Distribution Function: ECDF. Web.http://www.mathworks.com/help/stats/ecdf.html. Accessed 12th July 2013
Meehl GA, Stocker TF, Collins WD, Friedlingstein P, Gaye AT, Gregory JM, Kitoh A, Knutti R, Murphy JM, Noda A, Raper RL, Watterson IG, Zhao ZC (2007) Global climate projections. In: Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL (eds) 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 University Press, Cambridge
Micheni AN, Kihanda FM, Warren GP, Probert ME (2004) Testing the APSIM model with experiment data from the long term manure experiment at Machang’a (Embu), Kenya. In: Delve RJ, Probert ME (eds) Modeling nutrient management in tropical cropping systems. Australian Center for International Agricultural Research (ACIAR), Canberra, pp 110–117, No 114
Mugalavai EM, Kipkorir EC, Raes D, Rao MS (2008) Analysis of rainfall onset, cessation and length of growing season for western Kenya. Agric For Meteorol 148:1123–1135
Mugwe J, Mugendi D, Odee D, Otieno J (2009) Evaluation of the potential of organic and inorganic fertilizers of the soil fertility of humic hit sol in the Central Highlands of Kenya. Soil Use Manag 25:434–440
Mutai CC, Ward MN, Coleman AW (1998) Towards the prediction of the east Africa short rains based on sea surface temperature—atmospheric coupling. Int J Climatol 18:975–997
Mzezewa J, Misi T, Ransburg L (2010) Characterization of rainfall at a semi-arid ecotope in the Limpopo Province (South Africa) and its implications for sustainable crop production. http://www.wrc.org.za. Accessed 7th June 2013
Ngetich KF, Mucheru-muna M, Mugwe JN, Shisanya CA, Diels J, Mugendi DN (2014) Length of growing season, rainfall temporal distribution, onset and cessation dates in the Kenyan highlands. Agric For Meteorol 188:24–32
Nicholson SE (2001) Climatic and environmental change in Africa during the last two centuries. Clim Res 17:123–144
Ovuka M, Lindqvist S (2000) Rainfall variability in Murang’a district, Kenya: Meteorological data and farmers’ perception. Geografiska Annaler Ser A Phys Geogr 82(1):107–119
Philip GM, Watson DF (1987) Neighborhood-based-interpolation. Geobyte 2(2):12–16
Phillips J, McIntyre B (2000) ENSO and interannual rainfall variability in Uganda: implications for agricultural management. Int J Climatol 20:171–182
Raes D, Willems P, Baguidi F (2006) “RAINBOW—a software package for analyzing data and testing the homogeneity of historical data sets”. Proceedings of the 4th International Workshop on ‘Sustainable management of marginal dry lands’. Islamabad, Pakistan, 27–31 January 2006
Recha C, Makokha G, Traoré PS, Shisanya C, Sako A (2011) Determination of seasonal rainfall variability, onset and cessation in semi-arid Tharaka District
Rockstrom J, De Rouw A (1997) Water, nutrients and slope position in on-farm pearl millet cultivation in the Sahel. Plant Soil 195:311–327
Seleshi Y, Zanke U (2004) Recent changes in rainfall and rainy days in Ethiopia. Int J Clim 24:973–983
Shisanya CA (1990) The 1983–1984 drought in Kenya. J East Afr Resour Dev 20:127–148
Sivakumar MVK (1991) Empirical-analysis of dry spells for agricultural applications in SSA Africa. J Clim 5:532–539
Tilahun K (2006) Analysis of rainfall climate and evapo-transpiration in arid and semi-arid regions of Ethiopia using data over the last half century. J Arid Environ 64:474–487
Tucker CJ, Anyamba A (2005) Analysis of Sahelian vegetation dynamics using NOAA-AVHRR NDVI data from 1981–2003. J Arid Environ 63:596–614
Yan H, Nix HA, Hutchinson MF, Booth TH (2005) Spatial interpolation of monthly mean climate data for China. Int J Climatol 25:1369–1379. doi:10.1002/joc.1187
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Kisaka, M.O., Mucheru-Muna, M., Ngetich, F.K. et al. Potential of deterministic and geostatistical rainfall interpolation under high rainfall variability and dry spells: case of Kenya’s Central Highlands. Theor Appl Climatol 124, 349–364 (2016). https://doi.org/10.1007/s00704-015-1413-2
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DOI: https://doi.org/10.1007/s00704-015-1413-2