Climate variability and Rubber production in Kerala

Transcription

1 231 Chapter 9 Climate variability and Rubber production in Kerala 9.1 TREND IN AREA, PRODUCTION AND PRODUCTIVITY Area under rubber was just 62.6 thousand ha in It has increased by 727 per cent and reached thousand ha in The area under rubber has been steadily increasing over the years (Fig. 9.1). Decadal area indicated that it was in increasing over the decades. During , area under rubber was 83 thousand ha which has increased to 49 thousand ha in The percentage increase in area was more (79%) from the decade to , followed by to (56 %) and to (41 per cent). The increase in area was the least in the recent decade 21-9 (9.6 per cent). Tri-decadal area has increased significantly by 179 per cent. Rubber Production also has been in upward trend since Increase in area was tremendous over a period of six decades. The increase in production was 396 thousand tonnes from 1952 to 29. Decadal production was in increasing trend. The lowest production (21 thousand tonnes) was in the decade The production during the decade 21-9 was 684 thousand tonnes. The percentage increase in decadal production was the highest in (155 per cent), followed by (141 per cent) and (114 per cent). The least increase in production was recorded in

2 Productivity (Kg/ha) Year Production (' tonnes) Area (' ha) (51 per cent), followed by (63 per cent). The tri-decadal production of rubber has registered an increase of 589 per cent. 6 5 % increase: % increase: % increase: Fig. 9.1 Area, production and productivity of rubber in Kerala As in the case of production, productivity of rubber has been increasing over the decades. The average productivity of rubber during was only 271 Kg/ha. It has reached 1393 Kg/ha in Tri-decadal productivity also has registered an increase of 155 per cent (Fig.9.2)

3 Productivity (Kg/ha) Productivity (Kg/ha) Production (' tonnes) Production (' tonnes) Area (' ha) Area (' ha) % increase: % increase: % increase: Fig.9.2 Decadal and Tri-decadal trend in area, production and productivity of rubber in Kerala 9.2 RAINFALL REGIMES OF RUBBER Rubber plants are traditionally grown under rainfed conditions. Irrigation is practiced only in nurseries. Under rainfed conditions, monthly rainfall should be sufficient to meet the water requirement of the crop. In the tropical monsoon climate, the potential evapotranspiration rate is about 4 mm per day (Monteith, 1977) and therefore, an amount of 125 mm per month is considered essential to maintain optimum growth of plants. In traditional

4 Rainfall (mm) Rainfall (mm) 234 rubber growing areas like Kerala, annual rainfall ranges from 1 to 4 mm. The distribution pattern of rainfall in Kerala is such that it is having two peaks one in southwest monsoon season and another one in post monsoon period. However, the bimodal pattern of distribution of rainfall is restricted from central and southern districts where the influences of both the monsoons are felt. Rubber being a crop requires well distributed rainfall during its yielding phase may not perform well under a unimodal rainfall regime. That is why, rubber production is comparatively low in areas where unimodel rainfall is seen such as northern districts of Kerala. Heavy rainfall from June to September followed by weak rainfall in October - November is the rainfall scenario of Kannur and Kasaragod districts. If the pre-monsoon showers fail most of the plantation crops are subjected to soil moisture stress under rainfed conditions. However, such long dry spells are not conducive to rubber as it yields poor under dryspell / drought situation. This is more so in northern Kerala consisting of Kannur and Kasaragod districts where the rubber area is comparatively poor (Fig. 9.3). 7 6 S.Kerala Bi-modal 12 1 N.Kerala Uni-modal Rubber yield is likely to be better Rubber yield is likely to be poor 1 2 Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Fig.9.3 Rainfall regimes of rubber in Kerala

5 Temperature ( C) THERMAL REGIME OF RUBBER Temperature is one of the key environmental factors which influence plant growth. Rubber, being a crop adapted to moderate temperatures, gets affected by extremes in temperatures. Higher temperature results in higher rates of evapotranspiration and thereby to severe soil moisture stress in the absence of rainfall. Rubber is grown extensively across the midlands of Kerala. It can thrive well and produce better in the midlands of Kerala where the thermal environment is conducive to its growth. The mean annual maximum temperature across the midlands is 32.6 C while it is 22.8 C in the case of mean annual minimum temperature. The mean maximum temperature in the midlands of Kerala where the crop is grown extensively varies between 29.2 C in July and 36.7 C in March. In the case of minimum temperature it varied between 21.3 C in January and 24.4 C in April (Fig.9.4). The thermal environment in Kerala in general, midlands of the State in particular is conducive for the growth and development of rubber Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Fig.9.4 Thermal regime of rubber in Kerala 9.4 CLIMATE VARIABILITY AND RUBBER PRODUCTION The rate of increase in rubber productivity was affected during (-24.3%), followed by (-8.3%), (2.2%), (13.5%) and 24-8 (18.9%). The percentage decline in productivity of rubber could be

6 % increase in productivity (Kg/ha) 236 attributed to the adverse weather situations prevailed during that period was severe flood year as far as Kerala is concerned. Severe flood due to continuous rainfall and more number of rainy days led to low productivity, though it was not very evident from the productivity chart. Continuous rainfall adversely affects rubber production. Tapping is adversely affected in the event of heavy rainfall and extended number of rainy days. Similarly, during and there was a decline in the rate of increase of yield (Fig. 9.5) was the warmest and hottest decade in Kerala, which might have influenced adversely the rubber yield during that decade y =.1836x Average: 21.5% Fig.9.5 Pentad-wise rate of increase in rubber productivity in Kerala The productivity of rubber showed a different pattern when the increase in productivity was considered on decade-wise. It was the lowest (6.7%) during followed by 31.7% in the recent decade 21-9 (Fig.9.6). It is interesting tot note that the above pentads fell under these decades.

7 % increase in productivity (Kg/ha) Average : 43.8% 73.5 y = -.7x Fig.9.6 Decadal rate of increase in rubber productivity in Kerala 9.5 CLIMATE CHANGE IMPACTS ON RUBBER Area, production and productivity of rubber have been increasing over a period of time. Rubber cultivating area since has increased by 727 per cent while it was 396 per cent in the case of production. The increase in the case of productivity was 392 per cent. Tri-decadal area under rubber cultivation has registered an increase of 179 per cent while it was 589 per cent in the case of production. The increase was 155 per cent in the case of productivity (See Figs.9.1& 9.2). Overall, area, production and productivity of rubber have been increasing over the decades. Despite increase in temperature, aridity index, number of droughts, decline in rainfall and moisture index (index of climate shifts), (Figs 9.7 & 9.8) the rubber productivity was in increasing trend. It indicated that the long term increase in temperature is unlikely to affect rubber yield adversely. At the same time, the prolonged dryspells during summer due to absence of rainfall during northeast monsoon and failure of summer showers is likely to affect rubber productivity adversely as seen in recent years. Abrupt changes in weather may affect the productivity of the crop as noticed in 27-8, during

8 238 which the yield declined (1471 Kg/ha) due to continuous rainfall and more number of rainy days when compared to that of previous year 26-7 (1554 Kg/ha). Climate change in the form of climate variability, especially unpredictable, irregular and deficient rainfall pattern adversely affects the growth and productivity of natural rubber. Changes in rainfall pattern triggers fungal infection of leaves, which adversely affects productivity. The Country s production has declined to 8, 25, tonnes in 27-8 from 8,52, tonnes in the previous year, according to official sources. Kerala, the main rubber growing state, witnessed about 3, tonnes fall in production at 7.53 lakh tonnes from previous year (The Business Standard, 3 rd March, 211). Heavy and extended rainfall with good number of rainy days hampered the tapping in rubber. Similarly, the yield in rubber is likely to be declined in due to the extended rains in post monsoon. Of course, soil erosion, soil degradation and insect, pest and diseases affect the yield of rubber which is again determined by the weather vagaries. Rise in temperature may not have much role in determining rubber productivity as the thermal regime of rubber is not subjected to frequent fluctuations even during summer. It is rainfall- its quantum, distribution and number of rainy days which determine the yield decline in rubber. Rubber growing areas in south Kerala suffered due to heavy rainfall which extended up to December 21. Good quality planting material having tolerance to drought and pest and disease attack are to be used extensively to combat the changes in weather in the contest of climate change and global warming to sustain rubber production in the country. In short, it revealed that rubber yield is not affected due to long term changes in temperature, but is likely to be affected due to short term monsoon uncertainties like prolonged rain during monsoon, followed by extended rain during post monsoon as seen in 27 and 21. Similarly, prolonged dryspells during summer may adversely

9 No. of droughts No. of droughts Moisture Index (%) Moisture Index (%) Aridity Index (%) Aridity Index (%) Annual rainfall (mm) Rainfall (mm) 239 affect rubber yield under rainfed conditions. Therefore, detailed studies in these directions are to be taken up with experimental data systematically collected for this purpose Fig.9.7 Decadal and tri-decadal trends in rainfall, aridity index, moisture index and number of droughts

10 Temperature range ( C) Temperature range( C) Mean temperature ( C) Temperature ( C) Minimum temperature ( C) Tempererature ( C) Maximum temperature ( C) Temperature ( C) Fig.9. 8 Decadal and tri-decadal variations in temperature