Building socio-biophysical resilience: learning from smallholder farming community for adaptation CLIMATE VARIABILITY AND AGRICULTURE R. Selvaraju Tamil Nadu Agricultural University, Coimbatore 641 003, Tamil Nadu, INDIA
AIM To utilize the local coping strategies (including indigenous knowledge) and modern technologies (climate prediction, system analysis and participatory methods) to improve decision making for climatic risk management in agriculture To utilize the ability to predict climate variability and change on range of scales to improve decision making using climatic risk management strategies in agriculture
Targeted Agricultural Systems Shifting cultivation slash and burn (4-25 years cycle) Fallow systems ( 3 4 years cycle) Ley systems (grain grass/legume long term rotations) Dominant systems in SAT Rainfed upland cultivation (drylands) Arable upland irrigated farming (garden land) Arable intensive irrigated systems (wet lands)
Insight into socio-economic FEASIBILITY Insight into technical POSSIBILITY Insight into climatic PROCESSES Program Concept : True end-to-end applications Rural Sociology Agricultural Systems Science Climate Science Government national / regional Farm economics Dynamic climate modelling FARMER Systems analysis Seasonal climate forecasts
Methods and Tools Seasonal Climate Forecasting: Probabilistic, ENSO indices, analogues Agricultural Systems: Management responses, Mechanistic Cropping System models, Simple Crop Water Balance, Whole Farm Economic Modelling etc., Socio-economics : Physical description, User needs, Farm economics, Market price, Participatory Decision Making, Discussion Support Tools and Farmer s risk perception
inding Options: Link with local coping strategies op Diversification Multiple cropping systems (eg. Cotton, peanut-sorghum) Different maturity group varieties Intercropping Multi-storied cropping terprise mixing Crop-animal-tree interactions Off farm employment Indigenous Methods of Pest and Disease management Soil and moisture conservation practices at farm and catchments scale Price scenario and variability Methods also evolved to link financial institutions with the management strategies based on the past experiences
Traditional Climate Prediction Methods Only 10% of the traditional knowledge are related to seasonal rainfall prediction (n = 90) Rainfall on Sep.17-18 : Above average rainfall during Oct-Dec Lightning and thunder during April-May: Less chance of normal monsoon Heavy and steady wind during May lead to good rainfall in Oct-Nov. Rainbow over south east direction in June: Good monsoon Moon s crescent equal on both side during January Good rainfall during the year Termite fly appears in the evening: Heavy rainfall Many local knowledge on seasonal climate has the recreational value than the potential value
Tactical crop management Crop management options based on the climate information would make the system resilient Use of seasonal climate forecasts reduces the risk and captures the opportunity Value of risk reduction is greater than capturing the opportunity in smallholder farms 5000 4000 3000 2000 1000 0 1901 1911 1921 1931 1941 1952 1962 1972 1982 1992-1000 Tactical (forecast responsive) Vs fixed (nonresponsive) peanut plant population -2000
Value of climate application and Management Level The Information Value increases with the level of management Cropping Systems has greater resilience at low level of management, enabling sustainability Conflicting objectives a core issue affecting the systems ability to maintain the resilience due to over exploitation Profit Maximization Vs Sustainability Adaptation Options Changes with Farmers Risk Preference Crop diversification increases with risk averseness making the system more resilient For a highly risk averse farmer climate knowledge has no meaning; always he will diversify the enterprises
daptation options (eg.input application) may create greater equality due to varied level of management by the farmers respective of the agricultural systems ich farmer gains marginally; poor farmer is affected greatly tensive systems offers little scope for adaptation with respect management practices requires genetic manipulations cumulative income (%) 100 90 80 70 60 50 40 30 20 10 0 line of equal distribution rainfed irrigated wetlands 3 13 23 33 43 53 63 73 83 93
Adaptations reduces the vulnerability of the system to climatic risks Cashflow analysis (2002) 12000 10000 Forecast Non Responsive 8000 Forecast Responsive 6000 4000 2000 0-2000 -4000-6000 -8000 Apr 14-20 May5-11 May26-1 June 16-22 July7-13 July 28-3 Aug 18-24 Sep 8-14 Sep 29-5 Oct 20-26 Nov 10-16 Dec 1-7 Farm cash flow (Rs.) Weeks
Participatory Farm Decision Making - Use of Iterative techniques Use of Iterative techniques ensures combining scientific and indigenous knowledge of farmers When indigenous knowledge confirms with scientific understanding entire participatory risk management process will be successful Strong continuous south Westerly wind during may sign of good rainfall during Oct-Dec SST and SOI patterns confirms this understanding and farmers changed their crop choice
CLIMATE EDUCATION: uilding Knowledge and Skill for Climate Risk/ Opportunity Management Awareness is the first step for successful implementation of climate and agriculture programmes Skill of climatic risk management can be improved through climate education and awareness About 90 workshops conducted Need of the farmers participative methods 24% of the farmers acted based on forecasts and 16% were successful and improved the productivity Village level observatories helps to improve the understanding of the local climate eg. Seasonal cycles Rain gauges, Stevenson screen with thermometers and anemometers 5.0 4.5 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 Knowledge Change Before After
Capacity Building Developing self sustaining groups to manage climate variability at different agricultural systems Five training workshops conducted for researchers (3 international; 2 National) Training to the 1400 regional extension staff (linked to ongoing efforts on hi-tech Ag.training programmes) Awareness meetings to the water managers and public works department Directly working with farmers in a participative mode in the context of development as well as learning
The Challenge MESSAGE DISTARTION distorted information is worst than no forecast Probabilistic forecasting is a good option to go ahead understanding greater uncertainty in climate prediction understanding Spatial variability in rainfall is a greater issue that also needs attention Climate knowledge is only the information not technology that farmers require but greatly affect the performance of technology How to combine and evaluate the local indigenous knowledge with the scientific technologies? Climate communication aware and having ownership of problems and solutions
Summary Climate forecasting is one of many instruments that aims to reduce production uncertainty. It is one of many risk management tools that sometimes plays an important role in decisionmaking in different scales. to understand when to use this tool where and how is a complex and multi-dimensional problem (disciplines, scales, decision types etc). Participatory systems analysis needs to establish the role of climate forecasting in relation to other tools.