Plan
Comptes Rendus

External geophysics, climate
Identification of trends in rainfall, rainy days and 24 h maximum rainfall over subtropical Assam in Northeast India
[Identification des tendances dans la pluviosité, les jours de pluie et les chutes de pluie maximum en 24 h dans l’Assam sub-tropical de l’Inde nord-orientale]
Comptes Rendus. Géoscience, Volume 344 (2012) no. 1, pp. 1-13.

Résumés

Trends in rainfall, rainy days and 24 h maximum rainfall are investigated using the Mann-Kendall non-parametric test at twenty-four sites of subtropical Assam located in the northeastern region of India. The trends are statistically confirmed by both the parametric and non-parametric methods and the magnitudes of significant trends are obtained through the linear regression test. In Assam, the average monsoon rainfall (rainy days) during the monsoon months of June to September is about 1606 mm (70), which accounts for about 70% (64%) of the annual rainfall (rainy days). On monthly time scales, sixteen and seventeen sites (twenty-one sites each) witnessed decreasing trends in the total rainfall (rainy days), out of which one and three trends (seven trends each) were found to be statistically significant in June and July, respectively. On the other hand, seventeen sites witnessed increasing trends in rainfall in the month of September, but none were statistically significant. In December (February), eighteen (twenty-two) sites witnessed decreasing (increasing) trends in total rainfall, out of which five (three) trends were statistically significant. For the rainy days during the months of November to January, twenty-two or more sites witnessed decreasing trends in Assam, but for nine (November), twelve (January) and eighteen (December) sites, these trends were statistically significant. These observed changes in rainfall, although most time series are not convincing as they show predominantly no significance, along with the well-reported climatic warming in monsoon and post-monsoon seasons may have implications for human health and water resources management over bio-diversity rich Northeast India.

Les tendances à propos de la pluviosité, des jours de pluie et des chutes de pluie maximum en 24 heures ont été recherchées, par utilisation du test Mann-Kendall non paramétrique, dans vingt-quatre sites de l’Assam sub-tropical dans la région nord-orientale de l’Inde. Les tendances sont statistiquement confirmées par les méthodes paramétriques et non paramétriques et les magnitudes de tendances significatives sont obtenues au moyen du test de régression linéaire. En Assam, la pluviosité moyenne de mousson (jours de pluie) pendant les mois de mousson de juin à septembre est d’environ 1606 mm (70) qui tient compte d’environ 70 % (64 %) de la pluviosité annuelle (jours de pluie). À l’échelle mensuelle, seize et dix-sept sites (sur vingt et un sites) témoignent de tendances à la diminution de la pluviosité totale (jours de pluie), parmi lesquelles on trouve une à trois tendances (sur sept) statistiquement significatives en juin et juillet respectivement. D’un autre côté, dix-sept sites témoignent de tendances à l’augmentation de la pluviosité au mois de septembre, mais aucune n’était statistiquement significative. En décembre (février), dix-huit (vingt-deux) sites indiquent des tendances à la diminution (augmentation) de la pluviosité totale, parmi lesquelles cinq (trois) tendances sont statistiquement significatives. Pour les jours de pluie au cours des mois de novembre à janvier, vingt-deux sites ou plus témoignent de tendances à la diminution en Assam, mais pour neuf (novembre), douze (janvier) et dix-huit (décembre) sites, ces tendances sont statistiquement significatives. Ces changements observés dans la pluviosité, quoique la plupart des séries temporelles ne soient pas convaincantes puisqu’elles ne sont pas significatives au cours du réchauffement climatique bien établi lors des saisons de mousson ou de post-mousson, peuvent avoir des implications pour la santé humaine et la gestion des ressources en eau sur tout le Nord-Est de l’Inde, dont la biodiversité est riche.

Métadonnées
Reçu le :
Accepté le :
Publié le :
DOI : 10.1016/j.crte.2011.11.002
Keywords: Trend, Mann-Kendall non-parametric test, Rainfall, Rainy days, 24 hours maximum rainfall, Assam, Northeast India
Mot clés : Tendances, Test Mann-Kendall non paramétrique, Pluviosité, Jours de pluie, Chute de pluie maximum en 24 h, Assam, Inde nord-orientale

Deepak Jhajharia 1 ; Brijesh K. Yadav 2 ; Sunil Maske 3 ; Surajit Chattopadhyay 4 ; Anil K. Kar 3

1 Department of Agricultural Engineering, North Eastern Regional Institute of Science and Technology (Deemed University), Nirjuli, Itanagar-791109, Arunachal Pradesh, India
2 Department of Land, Air and Water Resources, University of California, Davis, CA 95616-8628, USA
3 Department of Hydrology, Indian Institute of Technology, Roorkee, Roorkee-247667, Uttarakhand, India
4 Department of Computer Application, Pailan College of Management and Technology, West Bengal University of Technology, Kolkata 700104, West Bengal, India
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Deepak Jhajharia; Brijesh K. Yadav; Sunil Maske; Surajit Chattopadhyay; Anil K. Kar. Identification of trends in rainfall, rainy days and 24 h maximum rainfall over subtropical Assam in Northeast India. Comptes Rendus. Géoscience, Volume 344 (2012) no. 1, pp. 1-13. doi : 10.1016/j.crte.2011.11.002. https://comptes-rendus.academie-sciences.fr/geoscience/articles/10.1016/j.crte.2011.11.002/

Version originale du texte intégral

1 Introduction

Hydrological processes are usually regarded as stationary; however, there is growing evidence of trends, which may be related to anthropogenic influences and natural features of climate system (IPCC, 2007). Serious concerns are drawn on the catastrophic nature of floods, droughts and storms, caused due to the significant variations in the regional climate including the rainfall pattern taking place on regional level. Trends in precipitation have been observed for last one century in many parts of globe. Over this period, precipitation increased significantly in eastern parts of North and South America, northern Europe and northern and central Asia whereas precipitation declined in the Sahel, the Mediterranean, southern Africa and parts of southern Asia (IPCC, 2007). Increasing trends were reported by Suppiah and Hennessy (1998) over Australia and by Burns et al. (2007) over New York, USA. On the other hand, decreasing trends in rainfall are reported by Buffoni et al. (1999) in Central-South Italy, in Kenya (Kipkorir, 2002) and in Northeast of Brazil (Silva, 2004). While mixed trends of increasing and decreasing rainfall are observed by Modarres and Silva (2007) in Iran and more.

The Asian monsoon circulation influences most of the tropics and subtropics of the eastern Hemisphere and a major portion of the Earth's population. The southwest (summer) and the northeast (winter) monsoons influence weather and climate between 30 N and 30 S over the African, Indian and Asian land masses (Reddy and Salvekar, 2003). The variability in the monsoon rainfall depends heavily upon the sea surface temperature anomaly over the Indian Ocean (Clark et al., 2000). The elements of the monsoon system include (Krishnamurti and Bhalme, 1976):

  • • the pressure of the monsoon trough, pressure of the Mascarene high;
  • • the cross-equatorial low-level jet, Tibetan high, tropical easterly jet;
  • • the monsoon cloud cover, monsoon rainfall, dry static stability of the lower troposphere;
  • • the moist static stability of the lower troposphere.

In the context of climate change, it is important to determine whether the characteristics of Indian summer monsoon are changing as well. The necessity for trend analysis of Indian summer monsoon rainfall has been emphasized by Guhathakurta and Rajeevan (2008). Rainfall trend over the Indian subcontinent and its relation with El Niño and the Southern Oscillation has been discussed in Sarkar et al. (2004), where it has been revealed that the effect of the El Niño and the Southern Oscillation has increased in recent years but has failed to influence the Indian rainfall because of the stronger circulation pattern prevailing over India during the last few decades. Bhaskaran et al. (1995) and May (2002) revealed a considerable increase in moisture transport into India and identified this increase as a possible cause of increase in extreme precipitation events over India. Sen Roy and Balling (2004) observed an increase in extreme rainfall events in India and also found that the increase is strongest in a region extending from the northwestern Himalayas in Kashmir through most of the Deccan Plateau in the southern peninsular region of India. Goswami et al. (2006) showed that the Northeast and the west coast of India are regions of high mean and high variability of rainfall events and revealed the strong influence of local orography on the rainfall over both regions. Trends in rainfall in the regional scale over India were investigated by Parthasarathy and Dhar (1974), where the trends in rainfall over 31 subdivisions of India were investigated using the sixty years data. Parthasarathy and Dhar (1974) witnessed positive trends over the central India and parts of Northeast and Northwest India. Likewise, some studies on rainfall analysis over different parts of India are also available in literature (Kothyari and Singh, 1996; Mirza et al., 1998; Parthasarathy, 1984; Parthasarathy and Dhar, 1978; Rupa et al., 1992; Singh et al., 2008). Malaria is major public health concern in the Northeast India that continues to dampen the equitable socio-economic development of the region (Dev et al., 2003). Among seven sister states of Northeast India, Assam witnessed much of the research investigations related to malaria epidemiology and control (Dev, 2009). A significant temporal change in the rainfall pattern of a subtropical region plays an important role in the seasonal and annual variability of mosquito-borne parasitic disease like malaria (Pascual et al., 2008; Zhou et al., 2004). The focal outbreaks of Plasmodium falciparum malaria frequently occur in the Northeast India particularly during the rainy season, i.e., during the months of April to September. It is believed that any rise in the minimum temperature caused by global warming might increase the incidence of P. falciparum malaria substantially (Dev and Dash, 2007). A handful of studies have indicated the usefulness of studying the influence of climate change on vector production and malaria transmission over various parts of India. Some significant examples in this direction are: Bhattacharya et al. (2006); Dev (2009); Dev et al. (2010); Singh and Sharma (2002); Singh et al. (2004). Dev (2009) reported no significant association between absolute rainfall and inter annual variation in malaria cases in Assam, Northeast India. Given these studies, the necessity for studying the rainfall pattern and investigation of the intrinsic trend with the summer monsoon rainfall time series over Assam is urgently required. However, the rainfall trend analysis over different sites of subtropical Assam under the humid climatic conditions is not available in the literature. On the other hand, studies related with pan evaporation (Jhajharia et al., 2009; McVicar et al., 2012), reference evapotranspiration (Jhajharia et al., 2011; McVicar et al., 2012), wind speed (McVicar et al., 2012), temperature (Chattopadhyay et al., 2011; Jhajharia and Singh, 2011; Jhajharia et al., 2007), and diurnal temperature range and sunshine duration (Jhajharia and Singh, 2011) over the subtropical and bio-diversity rich region of the Northeast India are available in the literature. Jhajharia et al. (2009), Jhajharia et al. (2011) and McVicar et al. (2012) report decreasing trends in pan evaporation and reference evapotranspiration over different sites of the Northeast India, respectively. Jhajharia et al. (2011) have reported that the seasonal decreases in ETO have been more significant in the pre-monsoon season, which indicates the presence of an element of a seasonal cycle over Northeast India. Steady decreases in wind speed are witnessed in almost all the time scales over most of the sites as well. Temperature increases were observed mainly in the monsoon and post-monsoon seasons, whereas decreasing trends in sunshine duration were observed mainly on annual, seasonal (winter and pre-monsoon) and monthly (January, February and March) time scales in Northeast region (Jhajharia and Singh, 2011). However, a detailed study of trends in rainfall, rainy days and 24 h maximum rainfall is lacking to a large extent on monthly and seasonal time scales over Assam, Northeast India. Rainfall, mainly in the monsoon season, causes severe damage to human life, crops, and disruption of life and infrastructure in the Northeast region. Mitra (2004) assessed the total damage caused by the floods during 1953 to 1995 in Assam and reported that the floods of 1987, 1988, 1992 and 1995 were quite severe and had devastating effects on the fragile ecosystems in the region. The natural causes may have contributed marginally to the changes in vegetation type. However, it is the activities of man that may have led to the irreversible transformation in landscapes and resulted in the loss of regions’ unique bio-diversity. Thus, there is an urgent need to investigate the rainfall pattern of the region for making the long term strategic plan to minimize and or restore the damaged ecosystem. In the present study, the trends in rainfall, rainy days and 24 h maximum rainfall are investigated on monthly, seasonal and annual time scales through the non-parametric Mann-Kendall test at 5% of significance level at twenty fours sites of Assam from the northeastern region of India for last fifty years. The magnitude of the trend in rainfall is obtained by fitting a linear trend line using the least-squares regression method, and the slope of linear fit provides the rate of increase or decrease in rainfall. The trend determined is again tested in terms of its statistical significance using the t-test (parametric approach) at 5% significance level. The present work has the aroma of newness in the following aspects:

  • • trend analysis of Indian summer monsoon rainfall has been executed in several studies (Kothyari and Singh, 1996; Mirza et al., 1998; Parthasarathy, 1984; e.g. Parthasarathy and Dhar, 1978; Rupa et al., 1992; Singh et al., 2008). Some studies are also available on the trend analysis of rainfall time series over South India (e.g. Raj and Azeez, 2010, 2011). However, a detailed study on the trend analysis of the summer monsoon rainfall over Northeast India is not available in the literature till date. Therefore, the present study has attempted to analyze the trends in rainfall in different durations: annual; month: January to December; and seasonal: winter, pre-monsoon, monsoon and post-monsoon over different sites of Assam located in the Northeast India;
  • • most of the available studies on rainfall trend analysis are based on parametric approaches. However, the present study has adopted the non-parametric approach (the Mann-Kendall test) while carrying out the trend analysis. The trends are statistically confirmed by the parametric method as well.

2 Material and methods

2.1 Rainfall data of Assam

Assam, one of the seven-sister states of Northeast India, is located in the northeastern region of India (see Fig. 1). There is a rain-shadow effect in the Assam valley lying between the Himalayas to the north and other ranges to the south and east. On the southern slopes of the Khasi-Jaintia hills, annual rainfall is over 10,000 mm, while on the north in the Brahmaputra valley it decreases to less than 2000 mm (Rao, 1981). The northeastern region of India is one of the highest rainfall-receiving regions on the Earth. The region has some of the sub-continent's last remaining rain forests and the region represents a diverse monsoon rainfall regime under wet humid conditions. The monsoon rainfall increases from south to north and also from west to east over subtropical Assam. Pre-monsoon rains are caused mainly by the depressions moving from the west and by local convectional storms. Rainfall is quite low in the winter and post-monsoon seasons (Barthakur, 2004). The monthly data of rainfall and rainy days of twenty-four stations of Assam were obtained from India Meteorological Department (IMD), Pune and Tocklai Tea Research Station, Jorhat. The 24 stations of Assam, which were considered for the present study, are listed in Table 1. Fig. 1 shows the spatial distribution of all the twenty-four stations in the four zones (based on latitude and longitude) of Assam, i.e., lower Assam, middle Assam, upper Assam and southern Assam. The data of 24 h maximum rainfall of various sites were obtained from IMD Pune as well. The monthly datasets of rainfall and rainy days were used to compute the annual and seasonal (winter, pre-monsoon, monsoon and post-monsoon) time series as per the standard practice of IMD. It may be noted that the seasonal and annual time series were derived from the monthly datasets by averaging over the said seasons and years respectively.

Fig. 1

Spatial distribution of rain gauge stations over different regions of subtropical Assam, Northeast India. Number IV represents the fourth region between 24°–26° N and 92°–94° E.

Distribution spatiale des stations à jauge pluviale sur différentes régions de l’Assam sub-tropical, en Inde nord-orientale. Le numéro IV représente la quatrième région entre 24 et 26° N et 92 et 94° E.

Table 1

Détail des stations localisées dans les quatre régions d’Assam, en Inde nord-orientale.

Sl. No Station District Lat. (N) Long. (E) Period
Region I (Lat. 26°–28° N and Long. 89°–92° E)
1 Dhubri Dhubri 26° 01′ 89° 59′ 1951–2003
2 Goalpara Goalpara 26° 11′ 90° 38′ 1954–2003
3 Goibargaon Nalbari 26° 91° 1976–2003
4 Guwahati Kamrup 26° 11′ 91° 45′ 1951–2003
5 Rangia Kamrup 26° 27′ 91° 37′ 1957–2003
6 Mathungari Barpeta 26° 90° 1977–2003
7 Panbari Bongaigaon 26° 90° 1976–2003
Region II (Lat. 26°–28° N and Long. 92°–94° E)
8 Dharmatal Marigaon 26° 92° 1976–2003
9 Gohpur Sonitpur 26° 53′ 93° 38′ 1958–1999
10 Golaghat Golaghat 26° 31′ 93° 59′ 1954–2003
11 Majbat Darrang 26° 45′ 92° 21′ 1954–2001
12 Tezpur Sonitpur 26° 37′ 92° 47′ 1951–2003
13 Thakurbari Sonitpur 26° 48′ 92° 42′ 1973–2000
Region III (Lat. 26°–28° N and Long. 94°–96° E)
14 Digboi Tinsukia 27° 24′ 95° 37′ 1954–2003
15 Lilabari Lakhimpur 27° 14′ 94° 07′ 1954–2003
16 Margherita Tinsukia 27° 18′ 95° 40′ 1979–2000
17 Neamatighat Jorhat 26° 94° 1976–2003
18 Tocklai Jorhat 26° 47′ 94° 12′ 1965–2000
19 Sibsagar Sibsagar 26° 59′ 94° 38′ 1951–2003
Region IV (Lat. 24°–-26° N and Long. 92°–94° E)
20 Halflong N.Cachar Hills 25° 10′ 93° 01′ 1951–2001
21 Kheronighat Karbi Anglong 25° 92° 1976–2003
22 Lumding Nowgaon 25° 45′ 93° 11′ 1951–2003
23 Silchar Cachar 24° 49′ 92° 48′ 1951–2003
24 Silcoorie Cachar 24° 50′ 92° 48′ 1965–2000

2.2 Methods of trend analysis

Trends in the data can be identified by using parametric or non-parametric methods, and both the methods are widely used. The non-parametric methods do not require normality of time series and are less sensitive to outliers and missing values. The non-parametric methods are widely used for analyzing the trends in several hydrologic series, for example, rainfall, temperature, pan evaporation, wind speed, etc. (Chattopadhyay et al., 2011; Dinpashoh et al., 2011; Fu et al., 2004; Hirsch et al., 1982; Jhajharia and Singh, 2011; Jhajharia et al., 2009, 2011; Tebakari et al., 2005; Yu et al., 1993). One of the problems in detecting and interpreting trends in hydrologic data is the confusing effect of serial dependence. Specifically, if there is a positive serial correlation in the time series, then the non-parametric test suggests a significant trend in a time series (Partal and Kahya, 2006). Lack of persistence in Indian rainfall is established in earlier studies like Chattopadhyay (2007) and Rakhecha and Soman (1994). Partal and Kahya (2006) suggested pre-whitening of persistent data before non-parametric test for trend. In the present case, because of lack of persistence, any such pre-whitening is not required. In the present, the non-parametric Mann-Kendall (MK) method (Mann, 1945; Kendall, 1975) is used for identifying the trends in rainfall because it is distribution-free and has a higher power than many other commonly used tests (Hess et al., 2001). The MK test, one of the most commonly used non-parametric method, is based on the test statistic, S, defined as follows:

S=k=1n1j=k+1nsgn(xjxk)(1)
where n is the number of observations and xj is the jth observation and sgn(.) is the sign function which can be defined as
sgnθ=1ifθ>00ifθ=01ifθ<0(2)

The mean and variance of the S statistic, under the assumption that the data are independent and identically distributed, are given by the following expressions:

ES=0(3)
VS=nn12n+5i=1mtiti12ti+518(4)
where m is the number of groups of tied ranks, each with ti tied observations. The MK statistic, designated by Z, can be computed as
Z=S1VarSS>00S=0S+1VarSS<0(5)

The values of MK test statistic are computed and it may be seen that, if the value lies within the limits (–) 1.96 and (+) 1.96, i.e., Z1α/2ZZ1α/2, then the null hypothesis of no trend can be accepted at the 5% (α) level of significance using a two-tailed test. Otherwise, the null hypothesis can be rejected and the alternative hypothesis can be accepted at the significant level of α, i.e., 5%. If Z > 1.96, there is increasing trend; and if Z < − 1.96, there is decreasing trend.

In this study, the trend-analyses were also carried out through linear regression test, a commonly used parametric method on annual, monthly and seasonal basis. A linear trend is fitted using the least-squares regression method and the slope of linear fit provides the rate of increase or decrease in rainfall. The linear trend is expressed as y(t) = a × t + b, where t is the time and ‘a’ and ‘b’ are constants. The trend determined, a, is tested in terms of its statistical significance using the t-test, where t=aσa with σa the expected standard deviation of a. If

t>t(1α2;n2),
there is a trend in the data at α % of significance level. The linear regression is used to determine the magnitude of the trend. The slope obtained during the linear regression analysis indicates the trend in the data, i.e., either increasing, or decreasing. The change in total rainfall is obtained by multiplying slope with total duration of rainfall data.

3 Results and discussion

The monthly data are used to compute seasonal and annual time series of rainfall and rainy days. The statistical parameters of total rainfall and number of rainy days, i.e., mean (M), standard deviation (S), coefficient of variation (CV), coefficient of skewness (CS) and coefficient of kurtosis (CK) are calculated to describe the characteristics of rainfall over subtropical Assam (Tables 2a–b). The average annual rainfall and the number of rainy days are 2321.5 mm and 110 for the considered period, which categorizes Assam as a high rainfall region. The pre-monsoon and monsoon rainfall contribute about 26% and 70% to the total annual rainfall. The mean rainy days in pre-monsoon and monsoon seasons are 32 and 70 respectively. The CV of annual rainfall (35.74%) and monsoon season (39.33%) is quite low as compared to the CV of the winter, pre-monsoon and post-monsoon seasons. Similarly, the variability in the rainy days is much higher during the winter and post-monsoon seasons compared to the monsoon season.

Table 2a

Paramètres statistiques de pluviosité totale, utilisés pour la caractérisation de la variabilité de la pluviosité sur l’Assam.

Time scale M (mm) S (mm) C V C S C K
Annual 2321.5 829.7 35.74 0.70 0.60
Winter 65.60 66.00 100.61 1.80 3.50
Pre-monsoon 598.20 296.4 49.55 1.50 4.70
Monsoon 1606.5 631.8 39.33 1.20 3.00
Post-monsoon 51.14 62.10 121.43 3.50 16.80
January 28.36 41.71 147.07 3.49 17.05
February 37.24 42.26 113.48 2.38 8.20
March 92.77 117.00 126.12 3.74 18.23
April 178.13 115.14 64.64 1.82 7.22
May 327.33 183.44 56.04 0.80 0.51
June 429.19 261.42 60.91 1.53 5.51
July 422.89 231.42 54.72 1.38 3.37
August 338.73 177.79 52.49 1.32 3.78
September 271.82 172.39 63.42 2.15 11.15
October 143.87 108.49 75.41 1.46 3.35
November 36.01 56.26 156.23 4.06 21.47
December 15.13 18.41 121.68 1.60 3.08
Table 2b

Paramètres statistiques du nombre de jours de pluie sur l’Assam.

Time scale M S C V C S C K
Annual 110 21.62 19.65 0.02 –0.25
Winter 5 3.52 70.40 0.98 0.90
Pre-monsoon 32 8.39 26.22 0.06 0.45
Monsoon 70 14.45 20.64 –0.11 0.11
Post-monsoon 3 2.28 76.00 0.74 0.17
January 2 1.71 85.50 1.04 0.69
February 3 2.54 84.67 1.08 1.05
March 6 3.87 64.50 1.00 0.96
April 11 4.36 39.64 0.38 0.10
May 15 4.91 32.73 –0.04 0.10
June 17 5.09 29.94 –0.36 0.03
July 18 5.26 29.22 –0.34 –0.08
August 15 4.81 32.07 0.13 –0.12
September 13 4.10 31.54 0.10 –0.32
October 7 3.52 50.29 0.52 –0.04
November 2 1.63 81.50 0.98 0.71
December 1 1.40 140.00 1.23 1.20

The monsoon rainfall anomaly is also examined using the averaged monsoon data of whole Assam (Fig. 2). The excess rainfall is observed when the percentage monsoon rainfall departure is greater than 19% from its normal (Mooley et al., 1982). During the considered period, Assam experienced five excess (1974, 1983, 1987, 1988 and 1993) and seven deficient (1961, 1967, 1975, 1976, 1994, 2001 and 2002) monsoon. Mooley and Parthasarathy (1982) identified 1972, 1966, 1965 and 1951 among the worst monsoon failure years for India. Likewise, Mooley et al. (1982) observed 1961 and 1975 as the second and the sixth worst flood years for all India. Contrary to the All India observations, Assam received deficient monsoon rainfall in 1961 and 1975 and excess monsoon rainfall in 1966.

Fig. 2

Anomaly in monsoon rainfall (% of mean) of Assam during the last half century.

Anomalie pour la pluviosité de mousson (% en moyenne) de l’Assam pendant le dernier demi-siècle.

3.1 Trends in rainfall

The Z statistic obtained through the MK test for the total rainfall in the annual and seasonal time scales are shown in Table 3 for the different sites of Assam. It can be inferred from Table 3 that both upward and downward trends were experienced for total rainfall at twenty different sites located in Assam. On annual time scale, the number of sites witnessing increasing rainfall is more or less equal to those witnessing decreasing rainfall. But, only three sites, namely, Haflong, Neamatighat and Goibargaon stations witnessed statistically significant trend obtained through the MK test at 5% level of significance. Out of these three stations, Neamatighat and Haflong (Goibargaon) observed significant decreasing (increasing) trends. The annual rainfall time series for two sites, which witnessed both increasing and decreasing trends (Goibargaon and Neamatighat) are given in Figs. 3 and 4, respectively. Similarly, the number of sites witnessing increasing rainfall is more or less equal to those witnessing decreasing rainfall in three different seasons, i.e., pre-monsoon, monsoon and post-monsoon under the humid climatic conditions of Assam. However, seven stations (one station, i.e., Neamatighat) witnessed statistically significant increasing (decreasing) trends in total rainfall in the following seasons: winter at four sites; monsoon at one site; and post-monsoon at two stations (pre-monsoon, monsoon and post-monsoon) located in the northeastern region of India. The sample time series of total rainfall in winter and post-monsoon seasons at different stations of Assam are shown in Figs. 5, 6 and 7, respectively. The dashed and solid lines represent the linear trend in seasonal rainfall, and the equation gives the magnitude of rates of changes (shown by the values of slope) in total seasonal rainfall at these sites. Jhajharia et al. (2007) reported decreasing trends in annual rainfall at the rate of 2.4 mm/year at Agartala (Tripura). The trends in annual rainfall at Agartala were in agreement with the decreasing trends observed in the cloud amount over Agartala. The results of trends in total rainfall witnessed in this study over twenty-four stations of Assam are in accordance with the findings of Jhajharia et al. (2009, 2011). Jhajharia et al. (2011) have reported no significant trends in rainfall in annual duration and all the four different seasons at Margherita, Thakurbari, Tocklai and Silcoorie. Similarly, Jhajharia et al. (2009) have reported no statistically significant trends in yearly rainfall at Chuapara (Nagrakata) and mixed trends in seasonal rainfall at Agartala of Northeast India.

Table 3

Valeurs Z obtenues par utilisation du test Mann-Kendall pour la pluviosité totale à l’échelle annuelle et saisonnière sur l’Assam, Inde nord-orientale.

S. No Name of site Annual Winter Pre-monsoon Monsoon Post-Monsoon
1 Dharamtalla 0.36 0.39 –0.55 0.47 –0.67
2 Dhubri 0.83 2.85 1.24 0.30 2.35
3 Digboi –0.49 –0.37 0.26 –0.99 0.36
4 Goalpara 1.38 2.40 –1.30 1.65 2.57
5 Gohpur –0.22 1.77 –0.62 –0.66 1.56
6 Goibargaon 2.05 0.00 1.07 2.09 –0.10
7 Golaghat –1.00 0.26 –0.82 –0.19 0.13
8 Guwahati 0.78 1.80 0.97 –0.18 0.69
9 Haflong –2.65 –0.63 1.41 1.60 –0.33
10 Kheronighat 1.20 2.10 1.02 0.26 1.05
11 Lilabari –0.54 0.60 –1.55 0.20 –0.90
12 Lumding 0.06 2.09 1.24 –0.95 1.26
13 Majbat –1.19 0.48 –0.97 –0.52 0.00
14 Mathungari –1.82 –0.92 –1.76 –1.62 –1.80
15 Neamatighat –3.12 0.83 –2.25 –2.96 –2.17
16 Panbari 1.72 0.29 1.19 1.40 –0.55
17 Rangia –0.32 0.20 –0.19 –0.69 –0.90
18 Sibsagar 0.18 1.63 –0.35 0.10 –0.06
19 Silchar 0.18 1.93 0.03 –0.57 1.58
20 Tezpur 1.12 1.35 –0.05 1.40 –0.30
Fig. 3

Annual and monsoon rainfall series over Goibargaon. The solid and broken curves represent the rainfall time series in annual and monsoon season, respectively. The solid and dashed lines represent the trends in annual and monsoon rainfall, respectively.

Séries de pluviosité annuelle et de mousson sur Goibargaon. Les courbes continues et discontinues représentent les séries temporelles de pluviosité par saison de mousson et par année, respectivement. Les lignes continues et en tiretés représentent les tendances pour les pluviosités annuelles et de mousson, respectivement.

Fig. 4

Annual and monsoon series of rainfall over Neamatighat. The broken and solid curves represent the rainfall time series in annual and monsoon season, respectively. The dashed and solid lines represent the trends in annual and monsoon rainfall, respectively.

Séries de pluviosités annuelles et de mousson sur Neamatighat. Les courbes continues et discontinues représentent les séries temporelles de pluviosité par saison de mousson et par année, respectivement. Les lignes continues et en tiretés représentent les tendances par saison de mousson et par année, respectivement.

Fig. 5

Rainfall series of two stations in winter season. The curves and the lines represent the actual rainfall time series and the linear trends in winter rainfall, respectively.

Séries de pluviosité pour deux stations pendant l’hiver. Les courbes et les lignes représentent les séries temporelles de pluviosité actuelles et les tendances linéaires de la pluviosité d’hiver, respectivement.

Fig. 6

Post-monsoon rainfall series of two stations. The curves and the lines represent the actual rainfall time series and the linear trends in post-monsoon rainfall, respectively.

Séries de pluviosité post-mousson de deux stations. Les courbes et les lignes représentent les séries temporelles de pluviosité actuelles et les tendances linéaires de la pluviosité en période de post-mousson, respectivement.

Fig. 7

Trends in rainfall in winter and post-monsoon seasons over two sites of subtropical Assam. Post M, GHY and MATHUNG denote post-monsoon, Guwahati and Mathungari, respectively.

Tendances de la pluviosité en saison hivernale et de post-mousson sur deux sites de l’Assam sub-tropical. Post M, Ghy et MATHUNG correspondent à la période post-mousson, à Guwahati et à Mathungari, respectivement.

On monthly time scales, sixteen and seventeen sites (seventeen sites) witnessed decreasing (increasing) trends in the total rainfall, out of which one and three trends (none) were found to be statistically significant in June and July, respectively (September). In the month of December (February), eighteen (twenty-two) sites witnessed decreasing (increasing) trends in total rainfall, out of which five (three) trends were statistically significant (for details see Table 4). The sample time series of total rainfall in different months at different stations of Assam are shown in Figs. 8 and 9. Therefore, the results of analysis of trends in monthly rainfall over different stations of Assam reveal similar kind of trend results as that of the seasonal rainfall, i.e., the majority of the stations observed statistically non-significant trends. The occurrences of reasonably stable trends witnessed in total rainfall over different sites in Assam are positive sign in view of the growing of crops, like, paddy, tea (Camellia sinensis L.) and forest products like bamboo that play a very important role in the economy of Assam. However, the observed increasing trends in temperature in monsoon and post-monsoon seasons, as reported by Jhajharia and Singh (2011), and Jhajharia et al. (2009, 2011), over different tea growing sites in Assam and other areas of Northeast India would affect the production of tea and other crops.

Table 4

Nombre de stations observant des tendances significatives à la diminution et à l’augmentation de la pluviosité totale et des jours de pluie à l’échelle mensuelle, et utilisant le test Mann-Kendall.

Month Decreasing trends Increasing trends No trends
Rainfall No. of rainy days Rainfall No. of rainy days Rainfall No. of rainy days
January 0 12 0 0 24 12
February 0 1 3 0 21 23
March 0 0 1 0 23 24
April 1 2 0 0 23 22
May 2 5 1 0 21 19
June 1 7 1 0 22 17
July 3 7 0 0 21 17
August 0 3 1 0 23 21
September 0 3 1 0 23 21
October 0 5 0 0 24 19
November 0 9 1 0 23 15
December 5 18 0 0 19 6
Fig. 8

Rainfall series of Tezpur and Guwahati in the month of February.

Séries de pluviosité de Tezpur et Guwahati au mois de février.

Fig. 9

Rainfall series of Goibargaon in the months of June and August.

Séries de pluviosité de Goibargaon aux mois de juin et d’août.

3.2 Trends in rainy days and 24 h maximum rainfall

As per the guidelines of IMD, a rainy day is defined as that day which receives rainfall amount of more than 2.4 mm. The Z statistic obtained through the MK test for the rainy days in the annual and seasonal time scales for twenty different sites of Assam are shown in Table 5. It can be inferred from Table 5 that both upward and downward trends were experienced in rainy days at different stations of Assam. On annual time scale, only two stations (Majbat and Mathungari) witnessed statistically significant decreasing trends in the rainy days at 5% level of significance. Similarly on seasonal time scale, eight and six stations witnessed statistically significant decreasing trends obtained through the MK test at 5% level of significance in the number of rainy days in monsoon and post-monsoon seasons, respectively. The results of analysis of trends in rainy days in winter and pre-monsoon seasons reveal that the majority of the stations observed statistically non-significant trends obtained through the MK test at 5% level of significance in the rainy days.

Table 5

Valeurs Z obtenues grâce au test Mann-Kendall pour les jours de pluie et les chutes de pluie maximum en 24 h sur l’Assam, Inde nord-orientale.

S. No. Name of site Rainy Days 24 hours Max. rainfall
Annual Winter Pre-monsoon Monsoon Post-monsoon
1 Dharamtalla 0.04 –0.29 –0.92 0.72 –1.58 0.50
2 Dhubri 0.15 1.04 0.10 –0.63 0.35 –1.32
3 Digboi –1.09 –1.20 –0.34 –2.15 –1.68 –0.74
4 Goalpara 0.03 0.16 –0.93 –0.96 –0.19 –1.62
5 Gohpur 0.34 –0.12 –0.62 –0.43 0.29 0.55
6 Goibargaon 0.83 –1.03 0.75 0.32 –1.97 1.19
7 Golaghat –1.61 –1.23 –1.30 –1.40 –2.00 –1.23
8 Guwahati –0.42 0.06 –0.75 –1.67 –1.67 0.17
9 Haflong –1.80 0.77 –1.92 –2.28 –0.38 –2.03
10 Kheronighat 0.02 1.43 –0.04 –0.68 –1.09 0.55
11 Lilabari –0.06 –0.96 0.13 0.54 –2.12 0.11
12 Lumding –0.58 0.72 0.39 –2.39 –0.75 –1.75
13 Majbat –2.80 –1.16 –1.52 –2.82 –1.69 –0.49
14 Mathungari –2.17 –2.53 -0.52 –2.22 –2.25 –0.75
15 Neamatighat –1.15 0.43 –0.55 –2.02 –2.53 –1.07
16 Panbari 0.40 –0.66 0.24 –0.24 –1.45 0.03
17 Rangia –0.61 –1.53 0.19 –0.96 –1.02 –2.09
18 Sibsagar –1.37 0.11 –0.20 –2.75 –1.44 –1.07
19 Silchar –1.12 0.28 –0.75 –2.07 0.69 –1.57
20 Tezpur –0.14 –0.34 –0.55 –0.43 –2.65 0.85

A list of station numbers observing different types of trends obtained by using the Mann-Kendall test in the number of rainy days on monthly time scales is given in Table 4. On monthly time scales, twenty-one sites each witnessed decreasing trends in the rainy days in June and July, out of which seven trends each were found to be statistically significant. Twenty-two or more sites witnessed decreasing trends for the rainy days during the months of November to January in Assam, but for nine (November), twelve (January) and eighteen (December) sites, these trends were statistically significant. Table 4 shows that the majority of statistically significant (decreasing) trends at 5% level of significance occurred in the months of December and January. The significant decreases in the number of rainy days over different sites of Assam for the months of January, June, July and December are given in Table 6. The most significant decreases in the rainy days occurred in the month of December in the range of 0.5 to 5, with a maximum decrease of 5 days over Margherita. The sample time series of the number of rainy days on seasonal, monthly and annual time scales for different stations of Assam, which witnessed significant trends at 5% level of significance, are shown in Fig. 10.

Table 6

Diminutions significatives dans le nombre de jours de pluies, obtenues au moyen du test de régression linéaire, sur les stations d’Assam sub-tropical en Inde nord-orientale.

Station January June July November December
Goibargaon –0.5 n.s n.s –1 –1
Guwahati –0.5 –2 n.s –0.5 –0.5
Kheronighat n.s n.s –2 0 –0.5
Lilabari –0.5 0 n.s –1 –1
Margherita –1 –1 –4 n.s –5
Mathungari –1 n.s n.s n.s –2
Naematighat n.s –2 –4 –1 –3
Panbari –0.5 n.s n.s n.s –1
Silcoorie –1 –3 –1 –2 –0.5
Tezpur –0.5 –2 –2 –1 –1
Thakurbari n.s n.s 0 n.s –1
Tocklai –1 –1 0 –3 –1
Fig. 10

Tends in the number of rainy days in different durations at various sites over subtropical Assam in Northeast India. MONS and POST M denote monsoon and post-monsoon, respectively.

Tendances à propos du nombre de jours de pluie pour différentes durées sur des sites variés de l’Assam sub-tropical, en Inde nord-orientale. MONS et POST M désignent les périodes de mousson et de post-mousson, respectivement.

The 24 h maximum rainfall is defined as the highest amount of total rainfall (in millimeter) occurring in a day in particular year over a particular station. The data of 24 h maximum rainfall for twenty sites were obtained from IMD, Pune. The values of Z statistic obtained through the MK test for the 24 h maximum rainfall are shown in Table 5 for twenty sites of Assam. It can be inferred from Table 5 that both upward and downward trends are experienced in the 24 h maximum rainfall in Assam. Only two stations witnessed statistically significant trends obtained by using the Mann-Kendall test in the 24 h maximum rainfall over Assam. The decreasing trends in the 24 h maximum rainfall events at 5% level of significance were observed at Rangia and Haflong. The 24 h maximum rainfall has decreased to 43 mm at Rangia and 68 mm at Halflong for the total period of records available at these two sites of subtropical Assam.

4 Summary and discussion

The rainfall dataset of twenty-four stations from Assam are used to investigate annual, monthly, and seasonal (winter, pre-monsoon, monsoon and post-monsoon) trends in rainfall, rainy days and 24 h maximum rainfall. Trends in total rainfall and rainy days are identified using the Mann-Kendall non-parametric method, which are also confirmed by the parametric approach. On monthly time scale, at least sixteen sites of Assam witnessed decreasing trends in total rainfall in June, July and December, out of which a few trends were found to be statistically significant at 5% significance level. On the other hand, seventeen and twenty-two sites witnessed increasing trends in total rainfall in September and February, but only three trends were found to be statistically significant in February. Similarly on annual and seasonal time scales, both increases and decreases in rainfall were witnessed, however most time series were statistically non-significant at 5% significance level. Kumar et al. (2010) reported increasing trends in annual rainfall over half of the sub-divisions out of total 30 sub-divisions in India using the data of 135 years (1871–2005), but the trends were statistically significant for only three sub-divisions (Haryana, Punjab and Coastal Karnataka). On the other hand, only one sub-division (Chhattisgarh) indicated a significant decreasing trend out of 15 sub-divisions showing decreasing trend in annual rainfall over India.

In case of 24 h maximum rainfall, all but two sites witnessed no trend over Assam. Rangia and Haflong witnessed significant decreasing trends in 24 h maximum rainfall. At least twenty-one sites witnessed decreasing trends in rainy days during the months of June, July and November to January, but the trends were found to be statistically significant for seven or more sites in Assam in these months. On seasonal time scales, the majority of sites in Assam witnessed decreasing trends in rainy days, but the trends were statistically significant at about half of the sites in Assam mainly in the monsoon and post-monsoon seasons. Since the observed changes in rainfall and rainy days in Assam are not encouraging as the trends witnessed for most of the sites are statistically non-significant, therefore, the data of stations from the other states of the Northeast India may be used to identify the trends in rainfall to strengthen the findings of the present study.

Global warming arising from anthropogenic-driven emissions of greenhouse gases is an important issue that needs attention in view of the recent climatic changes. Most of the observed increases in temperature since the mid-20th century are very likely due to the observed increase in greenhouse gas concentrations (IPCC, 2007). Jhajharia and Singh, 2011; Jhajharia et al., 2007, 2009, 2011; MoEF, 2004, reported increasing trends in temperature over different sites of Northeast India. The CO2 emissions over Assam have increased from 590 thousand metric tons of Carbon in 1980 to 1470 in 1990 (Ghoshal and Bhattacharyya, 2008). This increase in CO2 emissions may be due to the increased use of fossil fuels, land use changes i.e. urbanization, deforestation, shifting cultivation, etc. The substantial decline in forest cover from 25,160 km2 in 1987 to 23,688 km2 in 1999 over Assam (FSI, 2001) is also a matter of concern due to its potential ability of carbon sequestering. Concurrently, the increase in the human population of Assam, rose from 8.029 million in 1951 to 26.659 million in 2001 has put tremendous pressure on land resources resulting in deforestation of the large areas in this region (Ramakrishnan, 1994, 2001). The area under shifting cultivation has increased from 4160 km2 to 7276 km2 over Assam from 1975 to 1984 (FSI, 1989). Therefore, the warming may be very likely response of the main anthropogenic drivers like population growth, deforestation, industrialization and changes in land use by altering the atmospheric concentrations of greenhouse gases in Assam. Also, the potential impact of the rising temperature may be linked with the rainfall pattern observed over Assam in the present study. Trenberth (1998) found that an increase in temperature leads to increase in moisture holding capacity of the air. This increased moisture content may favor more intense rainfall and decrease in rainy days keeping rainfall stable during the considered time span. Suppiah and Hennessy (1998) reported that inter-annual fluctuations in heavy rainfall, total rainfall and dry days were strongly related to changes in maximum temperature and cloud cover in Australia. The role of deforestation in the climate change is a highly contentious issue and it needs adequate attention. The species-rich subtropical rain forests of Northeast India recognized as one of the 25 global biodiversity hotspots are highly susceptible to man-made disturbances and human influences have pushed many species to the brink of extinction, which is a cause of great concern. The observed changes in rainfall along with the well-reported climatic warming in monsoon and post-monsoon seasons in Northeast India may have implications for human health and water resources management. A detailed study of climatic parameters, i.e. temperature, radiation, evaporation, humidity, etc. along with the observed rainfall patterns will help in combating the adverse impacts on rainfed agriculture and forest dependent communities due to climate change induced changes over subtropical Assam.

Acknowledgements

The authors also acknowledge the India Meteorological Department (Pune) and Tocklai Tea Research Station (Jorhat) for providing the data used in the present study. The authors thank the editor and two anonymous reviewers for their insightful comments.


Bibliographie

[Barthakur, 2004] M. Barthakur Weather and Climate (V.P. Singh; N. Sharma; C.S.P. Ojha, eds.), The Brahmaputra Basin Water Resources, Kluwer Academic Publishers, 2004, pp. 17-23

[Bhaskaran et al., 1995] B. Bhaskaran; J.F.B. Mitchell; J.R. Lavery; M. Lal Climatic response of the Indian subcontinent to doubled CO2 concentrations, Int. J. Climatol., Volume 15 (1995), pp. 873-892

[Bhattacharya et al., 2006] S. Bhattacharya; C. Sharma; R.C. Dhiman; A.P. Mitra Climate change and malaria in India, Current Science, Volume 90 (2006), pp. 369-375

[Buffoni et al., 1999] L. Buffoni; M. Maugeri; T. Nanni Precipitation in Italy from 1833 to 1996, Theor. Appl. Climatol., Volume 63 (1999), pp. 33-40

[Burns et al., 2007] D.A. Burns; J. Klaus; M.R. McHale Recent climate trends and implications for water resources in the Catskill Mountain region, New York, USA, J. Hydrol., Volume 336 (2007), pp. 155-170

[Chattopadhyay, 2007] S. Chattopadhyay Feed forward Artificial Neural Network model to predict the average summer-monsoon rainfall in India, Acta Geophysica, Volume 55 (2007), pp. 369-382

[Chattopadhyay et al., 2011] S. Chattopadhyay; D. Jhajharia; G. Chattopadhyay Univariate modeling of monthly maximum temperature time series over Northeast India: neural network versus Yule-walker equation based approach, Meteorological Applications, Vol., Volume 18 (2011), pp. 70-82 | DOI

[Clark et al., 2000] O.C. Clark; J.E. Cole; P.J. Webster Indian Ocean SST and Indian summer monsoon rainfall: predictive relationships and their decadal variability, Climate, Volume 14 (2000), pp. 2503-2519

[Dev, 2009] V. Dev Integrated disease vector control of malaria: a success story based in Assam, northeastern India, ICMR Bulletin, Volume 39 (2009), pp. 21-28

[Dev and Dash, 2007] V. Dev; A.P. Dash Rainfall and malaria transmission in north-eastern India, Ann. Trop. Med. Parasitol., Volume 101 (2007) no. 5, pp. 457-459 | DOI

[Dev et al., 2003] V. Dev; P.C. Bhattacharyya; R. Talukdar Transmission of malaria and its control in the Northeastern Region of India, J. Assoc. Physicians India, Volume 51 (2003), pp. 1073-1076

[Dev et al., 2010] V. Dev; B.M. Sangma; A.P. Dash Persistent transmission of malaria in Garo hills of Meghalaya bordering Bangladesh, North-East India, Malaria Journal, Volume 9 (2010), p. 263 | DOI

[Dinpashoh et al., 2011] Y. Dinpashoh; D. Jhajharia; A. Fakheri-Fard; V.P. Singh; E. Kahya Trends in reference evapotranspiration over Iran, J. Hydrol., Volume 399 (2011), pp. 422-433 | DOI

[FSI, 1989] Forest Survey of India (FSI) State of forest report, Ministry of Environment and Forest, Govt of India, Dehradun, 1989

[FSI, 2001] Forest Survey of India (FSI) State of forest report 2001, Ministry of environment and forest, Govt of India, Dehradun, 2001

[Fu et al., 2004] G. Fu; S. Chen; C. Liu; D. Shepard Hydro-climatic trends of the Yellow river basin for the last 50 years, Climate Change, Volume 65 (2004), pp. 149-178

[Ghoshal and Bhattacharyya, 2008] Ghoshal, T., Bhattacharyya, R., 2008. State level carbon dioxide emissions of India 1980–2000. Contemporary Issues Ideas Social Sci. April, 1-47.

[Goswami et al., 2006] B.N. Goswami; V. Venugopal; D. Sengupta; S. Madhusoodanan; P.K. Xavier Increasing trend of extreme rain events over India in a warming environment, Science, Volume 314 (2006), pp. 1442-1445

[Guhathakurta and Rajeevan, 2008] P. Guhathakurta; M. Rajeevan Trends in the rainfall pattern over India, Int. J. Climatol., Volume 28 (2008), pp. 1453-1469

[Hess et al., 2001] A. Hess; H. Lyer; W. Malm Linear trend analysis: a comparison of methods, Atmospheric Environment, Volume 35 (2001), pp. 5211-5222

[Hirsch et al., 1982] R.M. Hirsch; J.R. Slack; R.A. Slack Techniques of trend analysis for monthly water quality data, Water Resour. Res., Volume 18 (1982) no. 1, pp. 107-121

[IPCC, 2007] IPCC, 2007. 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, United Kingdom and New York, NY, USA, 996 p.

[Jhajharia and Singh, 2011] D. Jhajharia; V.P. Singh Trends in temperature, diurnal temperature range and sunshine duration in Northeast India, Int. J. Climatol., Volume 31 (2011), pp. 1353-1367 | DOI

[Jhajharia et al., 2007] D. Jhajharia; S. Roy; G. Ete Climate and its variation-a case study of Agartala, J. Soil Water Conservation, Volume 6 (2007) no. 1, pp. 29-37

[Jhajharia et al., 2009] D. Jhajharia; S.K. Shrivastava; D. Sarkar; S. Sarkar Temporal characteristics of pan evaporation trends under the humid conditions of Northeast India, Agric. Forest Meteorol., Volume 149 (2009), pp. 763-770

[Jhajharia et al., 2011] D. Jhajharia; Y. Dinpashoh; E. Kahya; V.P. Singh; A. Fakheri-Fard Trends in reference evapotranspiration in the humid region of Northeast India, Hydrol. Process (2011) (In Press) | DOI

[Kendall, 1975] M.G. Kendall Rank Correlation Methods, Charles Griffin, London, 1975

[Kipkorir, 2002] E.C. Kipkorir Analysis of rainfall climate on the Njemps Flats, Baringo District, Kenya, J. Arid Environ., Volume 50 (2002), pp. 445-458

[Kothyari and Singh, 1996] U.C. Kothyari; V.P. Singh Rainfall and temperature trends in India, Hydrol. Process, Volume 10 (1996), pp. 357-372

[Krishnamurti and Bhalme, 1976] T. Krishnamurti; H. Bhalme Oscillations of a monsoon system.Part I, Observational aspects, J. Atmos. Sci., Volume 33 (1976), pp. 1937-1954

[Kumar et al., 2010] V. Kumar; S.K. Jain; Y. Singh Analysis of long-term rainfall trends in India, Hydrol. Sci. J., Volume 55 (2010) no. 4, pp. 484-496

[Mann, 1945] H.B. Mann Non-parametric tests against trend, Econometrica, Volume 33 (1945), pp. 245-259

[May, 2002] W. May Simulated changes of the Indian summer monsoon under enhanced greenhouse gas conditions in a global time-slice experiment, Geophys. Res. Lett., Volume 29 (2002) | DOI

[McVicar et al., 2012] T.R. McVicar; M.L. Roderick; R.J. Donohue; L.T. Li; T.G. Van Niel; A. Thomas; J. Grieser; D. Jhajharia; Y. Himri; N.M. Mahowald; A.V. Mescherskaya; A.C. Kruger; S. Rehman; Y. Dinpashoh Global review and synthesis of trends in observed terrestrial near-surface wind speeds: implications for evaporation, J. Hydrol., Volume 416–417 (2012), pp. 182-205

[Mirza et al., 1998] M.Q. Mirza; R.A. Warrick; N.J. Ericksen; G.J. Kenny Trends and persistence in the precipitation in the Ganges, Brahmaputra and Meghna river basins, Hydrol. Sci. J., Volume 43 (1998) no. 6, pp. 845-858

[Mitra, 2004] A.K. Mitra Flood Management (V.P. Singh; N. Sharma; C.S.P. Ojh, eds.), The Brahmaputra Basin Water Resources, Kluwer Academic Publishers, 2004, pp. 535-558

[Modarres and Silva, 2007] R. Modarres; V.P.R. Silva Rainfall trends in arid and semi-arid regions of Iran, J. Arid Environ., Volume 70 (2007), pp. 344-355

[MoEF, 2004] Ministry of Environment and Forest (MoEF) India's initial national communication to the United Nations Framework Convention on climate change., Govt. of India, New Delhi, 2004 (pp 266)

[Mooley and Parthasarathy, 1982] D.A. Mooley; B. Parthasarathy Fluctuations in the deficiency of the summer monsoon over India, and their effect on economy, Arch. Met. Geoph. Biokl., Ser. B, Volume 30 (1982), pp. 383-398

[Mooley et al., 1982] D.A. Mooley; B. Parthasarathy; N.A. Sontakke An index of summer monsoon rainfall excess over India and its variability: 1871–1978, Arch. Met. Geoph. Biokl., Ser. B, Volume 31 (1982), pp. 301-311

[Partal and Kahya, 2006] T. Partal; E. Kahya Trend analysis in Turkish precipitation data, Hydrol. Process, Volume 20 (2006), pp. 2011-2026

[Parthasarathy, 1984] Parthasarathy, B., 1984. Inter-annual and long term variability of Indian summer monsoon rainfall. Proceedings of the Indian Academy of Sciences (Earth Planetary Sciences) 93, 371–385.

[Parthasarathy and Dhar, 1974] B. Parthasarathy; O.N. Dhar Secular variations of regional rainfall over India, Quart. J. R. Met. Soc., Volume 100 (1974), pp. 245-257

[Parthasarathy and Dhar, 1978] Parthasarathy, B., Dhar, O.N., 1978. Climate fluctuations over Indian region–Rainfall: a review. Research Report no. RR-025. Indian Institute of Tropical Meteorology Pune; 31.

[Pascual et al., 2008] M. Pascual; B. Cazelles; M.J. Bouma; L.F. Chaves; K. Koelle Shifting patterns: malaria dynamics and rainfall variability in an African highland, Proc. R. Soc. B, Volume 275 (2008), pp. 123-132 | DOI

[Raj and Azeez, 2010] P.P.N. Raj; P.A. Azeez Changing rainfall in the Palakkad plains of South India, Atmosfera, Volume 23 (2010), pp. 75-82

[Raj and Azeez, 2011] P.P.N. Raj; P.A. Azeez Trend analysis of rainfall in Bharathapuzha River basin, Kerala, India, Int. J. Climatol. (2011) | DOI

[Rakhecha and Soman, 1994] P.R. Rakhecha; M.K. Soman Trends in the annual extreme rainfall events of 1 to 3 days duration over India, Theor. Appl. Climatol., Volume 48 (1994), pp. 227-237

[Ramakrishnan, 1994] P.S. Ramakrishnan Participatory development in managing population pressure on natural resources (R. Krishnan, ed.), Growing numbers and dwindling resources, Tata Energy Research Inst., New Delhi, 1994, pp. 86-96

[Ramakrishnan, 2001] P.S. Ramakrishnan Increasing population and declining biological resources in the context of global change and globalization, J. Biosci., Volume 26 (2001) no. 4, pp. 465-479

[Rao, 1981] Y.P. Rao The climate of the Indian subcontinent (K. Takahashi; H. Arakawa, eds.), Climates of southern and western Asia. World Survey of Climatology, 9, Elsevier Scientific Publishing Company, Amsterdam, 1981, pp. 67-118

[Reddy and Salvekar, 2003] P.R.C. Reddy; P.S. Salvekar Equatorial East Indian Ocean sea surface temperature: a new predictor for seasonal and annual rainfall, Curr. Sci., Volume 85 (2003), pp. 1600-1604

[Rupa et al., 1992] K. Rupa; G.B. Pant; B. Parthasarathy; N.A. Sontakke Spatial and sub-seasonal patterns of the long-term trends of Indian summer monsoon rainfall, Int. J. Climatol., Volume 12 (1992), pp. 257-268

[Sarkar et al., 2004] S. Sarkar; R.P. Singh; M. Kafatos Further evidences for the weakening relationship of Indian rainfall and ENSO over India, Geophys. Res. Lett., Volume 31 (2004), p. L13209 | DOI

[Sen Roy and Balling, 2004] S. Sen Roy; R.C. Balling Trends in extreme daily precipitation indices in India, Int. J. Climatol., Volume 24 (2004), pp. 457-466

[Silva, 2004] V.P.R. Silva On climate Variability in northeast of Brazil, J. Arid Environ., Volume 58 (2004), pp. 575-596

[Singh and Sharma, 2002] N. Singh; V.P. Sharma Patterns of rainfall and malaria in Madhya Pradesh, central India, Ann. Trop. Med. Parasitol., Volume 96 (2002), pp. 349-359

[Singh et al., 2004] N. Singh; A.C. Nagpal; A. Saxena; M.P. Singh Changing scenario of malaria in central India, the replacement of Plasmodium vivax by Plasmodium falciparum (1986–2000), Trop. Med. Int. Health, Volume 9 (2004), pp. 364-371

[Singh et al., 2008] P. Singh; V. Kumar; T. Thomas; M. Arora Changes in rainfall and relative humidity in river basins in northwest and central India, Hydrol. Process, Volume 22 (2008), pp. 2982-2992

[Suppiah and Hennessy, 1998] R. Suppiah; K.J. Hennessy Trends in total rainfall, heavy rain events and number of dry days in Australia, 1910–1990, Int. J. Climatol., Volume 10 (1998), pp. 1141-1164

[Tebakari et al., 2005] T. Tebakari; J. Yoshitani; C. Suvanpimol Time-space trend analysis in pan evaporation over Kingdom of Thailand, J. Hydrol. Eng., Volume 10 (2005) no. 3, pp. 205-215

[Trenberth, 1998] K.E. Trenberth Atmospheric moisture residence times and cycling: Implications for rainfall rates and climate change, Climate Change, Volume 39 (1998), pp. 667-694

[Yu et al., 1993] Y.S. Yu; S. Zou; D. Whittemore Non-parametric trend analysis of water quality data of rivers in Kansas, J. Hydrol., Volume 150 (1993), pp. 61-80

[Zhou et al., 2004] Zhou; Guofa; Minakawa; Noboru; Githeko; K. Andrew; Yan; Guiyun Association between climate variability and malaria epidemics in the East African highlands, Proc. Natl. Acad. Sci., Volume 101 (2004) no. 8, pp. 2375-2380 | DOI


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