This paper is based on the results of a pilot project conducted to strengthen Nigerian Meteorological Agency’s (NIMET) capacity to provide reliable planting date forecast in Nigeria. This aspect of the project aimed at understanding traditional knowledge base and farmers’ prediction methods, community perceptions of impacts of rainfall variability, coping strategies and opportunities in Sokoto, Kano, Jigawa, Kaduna, Bauchi states of Nigeria. Based on prevalence of drought, a community was selected for survey in each of the five states. Semi-structured interview and focus group discussion were used to sources for information. The survey indicates that the farmers had good understanding of weather and climatic dynamics of their community. The farmers in the study locations characterize a year into five seasons based on the atmospheric temperature as felt by the body, changes in wind direction, farming activities, and the behavioral changes of some animal and birds and phenological changes in plant species. Rainfall variability in the community has altered the farming systems, either in terms of changes in cropping pattern, elimination/reduction in the level of producing some crops or introduction of new crop varieties that are drought resistant and early maturing, and diversification of source of livelihood (non-farm activities). Impacts of rainfall variability in the communities were asserted to include; poor yield, low prices of crop/livestock, low dowry for their daughters, high cost of labor as a result of migration to urban centers, inadequate water for dry season farming, low income, low standard of living, and high level of poverty. Farmers recommended an integration of traditional proven methods of rainfall prediction with scientific methods to evolve reliable forecast that will reduce risks in their rainfed farming systems.
Crop production in Nigeria is essentially rainfed. Agriculture is therefore heavily dependent on the seasonal characteristics of rainfall which has been shown to diminish in amount and duration as one move from the south to the northern part of the country. Current evidence clearly shows that rainfall variability is a real threat and that the need for action today cannot be ignored [1-3]. Agricultural development has been affected by natural climate variability and extreme climate events which have caused significant decline in productivity resulting in food insecurity and poverty among rural communities. Precipitation changes are currently insufficient for many crops that water scarcity increasingly constrains production [
Five communities within 5 - 70 km from the nearby main town were purposively selected from each of the Agricultural Development Program (ADP) zones in each State based on reported high incidence of dry spell after the onset of rains. These sites are Gangara in Kaduna state (11˚20’N, 07˚23’E; 660 m above sea level) about 37 km north of Zaria on the Zaria-Funtua road; Shantake (12˚10’N, 08˚31’E; 469 m above sea level) in Makoda local government area of Kano state, Nigeria. The village is about 50 km north of Kano town along the Kano-Daura highway; Yan’dutse in Jigawa state (12˚11’N, 9˚15’E; 397 mm above sea level) about 95 km northeast of Kano and 70 km north of Dutse (Jigawa State Capital) along Kano—Gujungu high way; Kasarawa (12˚58’N, 05˚12’E; 298 m above sea level) in Wamako local government area of Sokoto state, about 5 km south of Sokoto town and Dabarndak (09˚34’N, 10˚00’E; 641 m above sea level) in Dass local government area of Bauchi state, Nigeria. The selected sites in Kaduna and Bauchi state are in the northern Guinea Savanna zone while those of Kano, Jigawa and Sokoto states are in the Sudan savanna agroecological zone. The community survey involved the characterization of the community in terms of the traditional prediction of onset of rains/planting season, consequences of wrong predictions of onset of planting season and coping strategies/opportunities. A village was purposively selected in each state with the assistance of the Sasakawa Global 2000 an NGO, Extension staff of the Agricultural Development Project (ADP), and researcher from the University within the state. The survey used participatory methodology tool like semi-structured interview with the community (25 - 60 in attendance)
and focus group discussion for studying the traditional knowledge basis on weather and climate prediction. The ages of people that participated in the community group interview ranged from 25 - 75 years while the range for the focus group discussion was 45 - 75 years. Themes and probing checklists were prepared in advance and the participants were guided in the discussion. A series of Participatory Rural Appraisal (PRA) exercises such as livelihood analysis, seasonal calendar of activities and priority ranking were organized with the community and focus group of selected individuals who seems to be most knowledgeable about traditional methods for rainfall predictions. Focus group discussion (FGD) was used to clarify the needs, constraints and coping strategies on weather and climate of the community. Through a process of triangulation, the views expressed in the FGD, community discussion were consolidated and analyzed using descriptive statistics.
The survey indicates that the farmers had good understanding of weather and climate of their community. They have developed a variety of traditional indicators for predicting weather situation to make farm management decisions and those relating to other means of livelihoods (
The people used several indicators to predict the onset of rainfall and planting season in the community. The traditional forecast knowledge has been adapted to local conditions and its requirement is dependent on physical observations like behavior of birds, flowering or flushing times of some trees species, prevailing wind directions and cloud patterns. Breman and Kessler [
the most important determinants of the presence of foliage and fruits on the woody plants of the West African semi-arid region.
The most popular and reliable method of predicting possibility of onset of rainfall within a week or two, according to farmers is based on changes in wind direction from the west towards the east. If it rains before the wind changes direction, this rain is usually considered a false rain, and so farmers do not plant no matter the intensity of the rainstorm. The period when complete defoliation of the “Gawo” (Fadherbia albida) tree occurs is rated next in term of reliability of prediction in the community. Lastly, they also use a method that depends on counting days from the last effective rains of the previous season. It assumes that, rain is bound to fall in the 7th month from the last effective rain of the previous year. However, if around that time rain falls without a change in wind direction, it is assumed to be a false rain. In addition to these local predictions knowledge base, the farmers in some states (Kano, Jigawa, and Kaduna) also have access to scientific forecast from their extension agents, radio and television, though they claim to depend more on their traditional forecast. Farmers use these predictions for land clearing and land preparation. Ridging starts after yet another heavy rain. Planting of drought resistant crops like millet, and sorghum also starts at this time. The documentation of farming systems with their complexities in relation to livelihood patterns have also been suggested to offer strategies for mitigation and adaptation to climate change [
Onset of rains may triggers planting of drought tolerant crops such as millet (Pennisetum glaucum L.R. Br.) and sorghum (Sorghum bicolor). But farmers tarry to plant input intensive and drought sensitive food and cash crops. They wait for rains to establish and use following indicators to determine establishment of rain and onset of planting:
• It rains frequently with heavy thunder and lightning; the soil remains soft and moist for an extended period
• After sunset, reddish horizon reflects in the east, this usually comes along with rain.
• Termite’s nuptial flight only occurs when the rains are fully established.
• Kulba (snake-like lizard) makes a lot of noise when rains are fully established.
• Cricket (Acheta domesticus) makes loud chirping courtship calls (noise) and dig holes.
• Appearance of a species of reptile which when mature looks like a lizard.
• Appearance of algae growth on walls of residential buildings.
• African Guinea fowl (Numida meleagris galeata) lays egg every day.
• Continuous croaking of toads (Bufo regularis) inside wells or under trees.
Once rains are established, planting may commence if the soil is moist (determined by using a local hoe called sungumi to dig the soil and determine the depth of moist soil) or after a heavy rainstorm. Farming communities surveyed agreed that their traditional forecasting methods often work for predicting the onset of rainfall and planting season but rarely for the distribution of rainfall within the year. The farmers’ prediction skills have also improved over the years as people are actually trained in this act by traditional religious teachers within and outside the communities. In Kaduna state for instance, farmers look out for chameleon (Chamaeleo chamaeleon) on the field after the first heavy rain. If chameleons are observed, it is believed that it will take sometime before the next rain, in which case they have to wait for another heavy rain before planting. It was emphasized in Bauchi state that appearance of small army worms-Spodoptera exempta or S. littoralis (moth larvae) after early season rains indicates a possibility of dry spell. In south-eastern Kenya, the main indicators for farmers to start land preparation and planting were reported to include budding of certain trees, high temperature and relative humidity, animal behaviors, wind direction and the smell of rain [
Year-to-year rainfall variability is perceived as a major constraint to increased agricultural production. Farmers recalled that the seasons have become less predictable than in the past. Droughts are frequent—about 3 in every 10 years. Rainfall variability in the community has altered the farming systems, either in terms of changes in cropping pattern, elimination/reduction in the level of producing some crops or introduction of new crop varieties that are drought resistant and early maturing. Nyong et al. [
• The farmers affirmed that in a bad year, replanting occurred as many as four times a year. In which case, farmer’s who have already applied fertilizer may replant without another application if he cannot afford it. Apart from the additional cost of inorganic fertilizer, there may also be the need to source for seed and pay for labor (if using hired labor) leading to additional cost of production.
• Low yield: In case of delay in rainfall, the yield loss may not be appreciable if the rain resume early enough. However, if the length of growing season reduces drastically as result of the delay, it could cause a yield loss of up to 50%. In case of drought, the yield loss could be as high as 90%.
• Low rainfall could dry up sources of water for domestic use and for livestock. This also affects the health status of the people in the community as they revert on any source (clean or unclean) of water for domestic use. Common ailments resulting from inadequate water supply due to low rainfall are malaria, guinea worm, typhoid, and cholera.
• Delay in rainfall affect dry season farming, particularly where the people depends on residual soil water stored from the previous season rains.
• Severe drought in the community may also cause temporary migration to other communities or urban centre to farm or trade. It was reported that some of these migrants are the carriers of viruses causing ailments like HIV into the communities.
• Inadequate rainfall or water required for crop growth usually lead to poor quality of grains leading to poor milling and low prices and consequently low income and standard of living.
• Low rainfall affects growth of animals due to inadequate feed and water. This ultimately reduces their stock (sale of the animals at very low prices or movement of animals out of the community in search of feed and water).
• Dowry for daughters ready for marriage is low due to low prices of poor quality crops and livestock and consequent low income.
The indigenous knowledge base in some part of West Africa with the use of biological and social data have also helped in the adoption of mitigation strategies and conservation of biodiversity that may have resulted from climate change [
• Evolving contingency cropping systems—when rains are delayed, they use early maturing crop varieties or change the crops grown—instead of millet, use early maturing dwarf sorghum variety (Mace da kunya in Sokoto) once it germinates and starts growing, it can withstand drought till harvest time.
• Rainfall variability in the communities has also altered the farming systems, either in terms of changes in cropping pattern, elimination/reduction in the level of production of some crops or introduction of new crop varieties that are drought resistant and early maturing.
• Relay cropping was a common practice in the communities about ten years ago but this has been eliminated as a result of low distribution of rainfall. For instance, the farmers used to cultivate millet and harvest before planting cowpea (Vigna unguiculata). Some farmers even use the proceeds from millet to invest in cowpea production. With reduction in the amount of rain, all these crops are now intercropped on the same plot.
• The level of sugarcane production has decreased as a result of reduction in the quantity of water for irrigation. They now cultivate more vegetables like pepper, onion, tomato which does not require as much water as sugarcane.
• Migration of pastoralists and their animals out of the community in search of feed and water. In case of drought, arable farmers also move to areas where there are no problems with rainfall for rainfed farming and return after the season.
• Diversification of income—trading, artisans, digging tube wells for money, packing sand and selling etc.
This paper has attempted to assess farmers’ knowledge and skills on rainfall prediction, variability and coping strategies. It is evident from the findings of the survey that farmers have evolved several indicators for predicting onset of rains and planting season. However, the people were of the opinion that the level of accuracy is lower now than before with the erratic nature of weather in the present days. This is a clear evidence of the reality of global climate change phenomenon in the survey area. In case of wrong prediction or poor rainfall, farmers were forced to adapt various coping strategies to sustain their livelihood. Even where the communities have access to scientific weather forecast, some farmers still adhered to forecast of local experts in making farm management decision. Farmers therefore recommended an integration of traditional proven methods of rainfall prediction with scientific methods to evolve reliable forecast that will reduce risks in their rain fed farming systems.
The International START Secretariat supported this work under the START/PACOM Award 2005 for a project through a grant from the US NSF (GEO-0203288 “Capacity Building for Global Change”). We also like to acknowledge the contribution of Professor. S. A. Ibrahim, Drs. J. M. Jibrin, A. I. Yakubu, and S. Miko who are researcher from the University within the states were the study was carried out. Their active participation in the community survey is duly acknowledged. We appreciate the contribution of the extension agents of SG 2000, (NGO working in the state) during the field work.