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Ginger (Zingiber Officinale) is an important commercial spice crop grown from
very ancient times in India. Because of its valued aroma and lemon flavour, it has
spread to tropical and subtropical regions from the Indo-China region and became one
of the earliest oriental spices known to Europe (Nybe and Miniraj, 2005). Species
diversity and yield of spices are threatened due to the ever increasing temperature and
changes in precipitation pattern. Since spices are grownboth in plains and high altitudes,
it is important to assess the long term climatic changes within a region and its influence
on productivity (Sing, 2008).
The present experiment was aimed to study the impact of climate change on
growth and yield aspects of ginger crop under climate change scenarios of RCP 4.5 and
8.5. Ginger varieties, Maran and Varada were raised at Instructional Farm (IF)
Vellanikkara, by adopting split plot design. The experiment was laid out with four
dates of planting (15th May, 1st June, 15th June and1
st July) as main plot treatment and
two varieties (Maran and Varada) as sub plot treatments. Fourreplications were given
for the experiment. The crop weather relationship was analysed with correlation with
the help of SPSS software. Principal Component Analysis (PCA), a multivariate
statistical technique was done in order to reduce the multicollinarity of large data sets
of weather variables to substantially smaller sets of new variables. The developed
principal components were utilized for model development using stepwise regression
analysis. The future climate was estimated by climate change projections generated
using CCSM4 models for 2030, 2050 and 2080based on scenarios RCP 4.5 and 8.5.
The life cycle of ginger was characterized by four distinct stages, ie., sowing to
50% germination, 50% germination to active tillering, active tillering to bulking and
bulking to physiological maturity. Duration taken for each phenophases found to vary
for all the four date of planting in both Maran and Varada. The May 15th date of
planting took more days to germinate compared to other date of plantings. The number
of days taken for sowing to germination was positively correlated with maximum
temperature, minimum temperature, rainfall and soil temperature in both varieties. The
number of days taken to attain physiological maturity also foundto be more in May 15th
planted crop.
The weather experienced during various phenophases have significant influence
on yield and other yield attributes of ginger crop. It was found that the yield of both
varieties of ginger havepositive correlation with minimum temperature at all the four
phenophases except bulking t o physiological maturity. Maximum temperature
observed at sowing to germination was positively correlated with yield of both Maran
and Varada. At active tillering to bulking stage, rainfall, rainy days and minimum
temperature showed a significant positive correlation with yield, but maximum
temperature, wind speed and solar radiation showed a significant negative correlation
with yield.
The Principal Component Analysis was carried out for ginger varieties Maran
and Varadaby using the weather parameters experienced in four stages ie., sowing to
50% germination, 50% germination to active tillering, active tillering to bulking and
bulking to physiological maturity. Weather parameters considered include maximum
temperature (Tmax), minimum temperature (Tmin), rainfall (RF), rainy days (RD),
relative humidity (RH), wind speed (WS) and solar radiation (SRAD). The statistical
model was developed with principal components as independentand yield as dependent
variable.
Projected climatic conditions of Vellanikkara, Thrissur under climate change
scenarios of RCP 4.5 and 8.5 were downscaled from CCSM4 model. The projected
climate of near century (2010-2039), midcentury (2040-2069) and end of century
(2070-2099) were downscaled for the study. The projected yield of the ginger variety
Maran was found to decrease at all planting datesexcept July 1
st under both the RCP 4.5
and 8.5 scenarios. Under RCP 4.5 scenario, more reductionwas reported at the end of
the century on May 15th (38%), June 1st (29%) and June 15th (54.5%) dates of planting.
July 1
st planted crop reported increase in projected yield under near, mid and end of
centuries. More increase in yield was observed in midcentury (17.7%). Under RCP 8.5
scenario,May 15th (50.2%) and June 1st (20.3%) dates of planting reported the highest
percentage of yield reduction during midcentury. June 15th date of planting, recorded
the highest yield reduction of 52.6% at the end of the century. July 1st planting date
recorded increase in yield and it was more in end of century (15.5%). In case of
Varada, under RCP 4.5 scenario, more yield reduction was reported at the end of
century during May 15th (24%) and June 1
st (7.2%) dates of planting. DuringJune 15th
planting dates, near and end of century reported the same yield reduction of 24.9%.
TheJuly 1
st planted crop reported an increase in yield, which was more (15.5%) during
end of century. Under RCP 8.5 scenario, more yield reduction was observed in
midcentury on May 15th (28.8%) date of planting. June 1st (6.6%) and June 15th
(19.9%) dates of planting reported more reduction in end of century. July 1
st reported
more increase of 24% in end of century.