Spatial-Temporal Variations in January Precipitation over the Period of 1950-2000 in Pakistan and Possible Links with Global Teleconnections: Geographical Perspective ()
1. Introduction
The Fourth Assessment Report of IPCC [1] projects that climate variability will further aggravate floods and droughts in Asia and will increase vulnerability of poor Asian community. Side by side, the alarming rate of melting glaciers in Himalayas will have negative repercussions on water supplies in coming years [2] . The northern Pakistan accumulates substantial amount of snow during winter precipitation, which is seasonal addition to already existing glaciers and supplement the flow of River Indus, so forecast of summer discharge in the River Indus is also connected to amount of winter precipitation received in upper catchments area [3] . The year of 1997-98 was marked by strong El Nino Southern Oscillation (ENSO); induced five years drought from 1998-2002 in the south west Asia including Pakistan [4] [5] experienced most severe drought conditions in the last 50 years. As consequence, it triggered migration in different parts of southern Pakistan especially in Balo- chistan Province when meteorological drought reached the degree of hydrological drought. The Sulaiman, Kir- thar ranges and most of the areas at their both east and west up to the Makran area in the south are out of reach of summer monsoon rainfall in normal atmospheric condition [6] . Pakistan is located in subtropical region of south Asia with complex topography and has access to Western Disturbances (WDs), and this system of lows contributes to winter precipitation [7] , further it is considered the second largest source of precipitation in Pakistan. The study [8] suggests the mechanism if trough is deeper enough over the northwestern parts of Pakistan and its surrounding in winter the moisture containing winds will rush from Arabian Sea and will contribute to the precipitation of the region. The month of January is significant as the country receives substantial winter precipitation in January. The thermodynamic impact of mountains contributes to capturing precipitation [9] hence; the western and northern parts of Pakistan receive maximum precipitation from WDs as they enter from the west associated with westerlies flow. On experimental basis, through EOF analysis, this paper assesses the January pre- cipitation over the second half of the 20th Century to seek regional temporal and spatial variation in Pakistan and its possible relationships with atmospheric circulation at SLP and 500 hPa level. The EOF tool is capable of iden- tifying the physical mechanisms, which enforce climate variability [10] . The EOFs represent the eigenvectors of the covariance matrix [11] . These vectors elucidate the maximum possible variance; the leading EOF has the po- tential to express maximum variance while the successive EOFs are counted for less variation respectively [12] .
2. Data and Method
In this EOF analysis, two data sets have been utilized. The first set is comprised of ground observed mean monthly January precipitation over the period of 1950-2000, obtained from the Pakistan Meteorological Department (PMD). The 45 stations with less missing data were selected from all over the country (Figure 1(a)).
(a) (b)
Figure 1. (a) Geographical distribution of the stations that provide data for the analysis; (b) Regional detail and landforms in Pakistan, the western and northern parts of Pakistan are dominated by rugged mountains while eastern parts of Pakistan are dominated by plains laid down by River Indus and its tributaries.
The month of January was operated as continues time series from 1950-2000. Interpolation was done with grid resolution of 0.5˚ × 0.5˚. The interpolation with good spatial resolution can overcome the discrepancy exists in data due to either sparsely distributed observatories or missing data. The fine spatial resolution is instrumental to point out the environmental variability in the mountainous and other diversified areas where sharp climate gradient does exist [13] . The study area covers about 796,095 km2 with distinct physiography shown in Figure 1(b) prepared from DEM input into ArcGIS.
The second set of data contains gridded reanalysis data of sea level pressure (SLP) and 500 hPa geopotentail height (GPF) field with spatial resolution of 2.5˚ × 2.5˚ was obtained from National Centre for Environmental Pre- diction/National Center for Atmospheric Research (NCEP/NCAR) at global scale over the period of 1950-2000.
The EOF provides us with statistical expressions and preferred spatial-temporal patterns of variability. Three EOFs have been performed; each set of analysis provides spatial pattern of ground variations, time series of precipitation anomalies, SLP and 500 hPa loading anomalous patterns acknowledged by correlation coefficient for January over the period of 1950-2000 that reflect statistical significant and less significant areas.
3. Results and Discussion
EOF1: The leading EOF mode captured 37.51% of the total variance. The observed spatial distribution of percentage departure of January precipitation from reference value in the time period of 1950-2000 has been shown in Figure 2(a). The anomalous spatial patterns were located as such that, a pattern was centered over Parachinar and Safed Koh about southwest of Peshawar Valley where thunderstorm frequency remains almost high in winter, another pattern was centered over the Muree Hills and contiguous Azad Jammu and Kashmir (AJK). A third pattern was centered over the Hindukush and Karakoram with parts of western Himalayas in the extreme north of the country. In addition, the pattern with less variation prevailed over southern Punjab, Sind and Balochistan provinces. The spatial variation was consistent and more obvious in northern parts of the country. The Khyberpahktoonkhwa (KPK), Federally Administered Tribal Areas (FATA)
Peshawar
Valley
and Hindukush Karakurram Himalayas (HKH) have comparatively steep gradient of precipitation anomaly in the study period. The internal variability is evident that the years including 1950, 1953-1954, 1957, 1959, 1961, 1964-1965, 1970, 1972-1973, 1977, 1981, 1990-1993 and 1999 had precipitation above average in Pakistan while the rest of the years of the study period have precipitation below average in January but with few years close to normal precipitation like in early 1980s. The Khyberpahktoonkhwa (KPK), Federally Administered Tribal Areas (FATA) Peshawar Valley and Hindukush Karakurram Himalayas (HKH) had comparatively steep gradient of precipitation anomalies, in this context Balochistan and Indus plains were found less significant. Overall situation derived from EOF1 reflects that the negative precipitation anomalies dominated in January over the study period. The comparison (Figure 2(b)) of average and temporal trend has been validated significantly with r = 0.92.
The SLP and Φ500 hPa have been mapped with contour interval of 0.1, the blue color patches in the figures indicate the areas where correlation coefficient exceeds 95% significance level with respect to spatial-temporal variability of January precipitation. Reference to Figure 2(d) the Central Asia, eastern Asia, central Europe and northern Atlantic indicate significant correlation with the precipitation variability, in this connection the western tropical Pacific basin is another area of confidence level. High confidence level was achieved around the
Antarctica
.
The correlation pattern at 500 hPa level (Figure 2(e)) demonstrates obvious relation especially in the middle latitudes over the Middle East extending to Central Asia and surroundings, over the eastern Asia and North America, the relation configures high confidence level. The achieved significance is high around
Antarctica
but not that much strong as in case of SLP.
EOF2: The EOF second mode captured 15.79% of the total variance. The time series correlation coefficient (Figure 3(b)) exhibits interannual variability quite consistently and no obvious decadal changes except in the 1950s where the precipitation was mostly found above the reference point except in northernmost lofty parts in the country. Sindh and Indus plains were characterized by less significance. The 27 years of the study period have precipitation above normal except in HKH region while 20 years faced precipitation deficit in most of the country except the HKH region, the rest of the years were found in the range of normal or very close to the normal precipitation.
The coefficient patterns that exhibit the relation with precipitation variability at SLP (Figure 3(c)) shows where few high significant areas were observed, area of obvious correlation exists over northern Atlantic Ocean
that extends from tropics to the Arctic region, simultaneously the high confidence area prevailed over the tropi- cal and subtropical western southern Atlantic basin. The considerable patches of teleconnections have been traced in the
Antarctica
region also. The Mediterranean, Middle East pattern centered over the
Arabian Sea
remained significant at 500 hPa level. Side by side, the atmospheric state over North America and adjacent oceans configures considerable relation with observed precipitation variability. The Antarctic region in the proximity of Antarctic Circle in the southern Atlantic shows area of significance, the rest of the region around
Antarctica
was found less significant in this case.
EOF3: The third EOF mode captured 10.32% of the total variance. The spatial variation over Pakistan shows (+), (−) and then (+) patterns from south to north and reflects changes in phase structure (Figure 4(a)). The tem- poral correlation coefficient shows interannual variability and also some reasonable decadal changes (Figure 4(b)).
In the decade of 1950s, mostly Pakistan had precipitation above average, in 1960s, most areas were found with deficit in precipitation and the same was true for 1970s and 1980s, based on results the Peshawar Valley and surrounding got precipitation above normal in these decades. The 1990s have shown high internal variability and less decadal signature. Twenty years of the study period were found with above normal precipitation in most parts of the country excluding Peshawar Valley, Potwar region, Muree Area and Azad Kashmir where these months reflect precipitation below average. Twenty nine years were observed with rainfall below normal in most of Pakistan except Peshawar Valley, Potwar region, Muree Area and Azad Kashmir. The above said spatial-temporal variability in January precipitation has shown link with the atmospheric state at SLP (Figure 4(c)) in Atlantic Ocean including Mediterranean area, other regions of high significance were eastern Asia and Antarctic areas as well. The precipitation variability also has shown relation with anomalous condition of atmosphere at 500 hPa (Figure 4(d)), the relation over Mediterranean, Middle East, North America, northern basin of Atlantic Ocean and Antarctic and surrounding areas was quite strong.
The climate variability in Pakistan and surroundings has been linked with North Atlantic Oscillations (NAO) as documented by various researchers e.g. [14] - [17] . The positive signature of winter precipitation in northern rugged parts of Pakistan has association with positive (NAO) index [18] . According the findings the Mediterranean region and North Atlantic Ocean are the two most prominent areas at both SLP and 500 hPa, which show their influence on the study area through teleconnection. Based on results, teleconnection support that the January precipitation and its variation in
Pakistan
have deep link with NAO and pressure system over the
Mediterranean
. The 500 hPa field is generally used to determine the prevailing atmospheric condition from middle to upper troposphere, the planetary waves and their transient behavior have been traced, to be associated with westerlies flow [19] and has been recognized as East Atlantic and West Atlantic patterns pertaining to NAO [20] . Results and the above discussion lead us to the conclusion that the variability of January precipitation in Pakistan has been originated from the atmospheric state over the north Atlantic, Mediterranean and surrounding regions.
4. Conclusions
Based on results the rugged northern and western parts of the country show significant sptial-tempotral precipi-
tation variability in Pakistan. These areas include Kalat region, Quetta Valley, western Bordering Ranges, KPK and across Peshawar Valley to the northwestern lofty mountains up to the Karakoram Ranges in the extreme north of the country. The observed spatial-temporal variability in relation to anomalous atmospheric states at SLP and 500 hPa fields supports that precipitation variability in January can be connected to highly variable nature of westerlies. The interannual variability was salient feature in all modes and found consistently throughout time series of precipitation anomalies. The leading EOF mode 1 depicts correlation pattern at SLP and 500 hPa height field could be the acknowledgment of deep trough over the region, which encourages precipitation in winter. The interdecadal changes were not clear in the first two EOF modes but reasonable interdecadal changes were observed associated with EOF mode 3.
The NAO pressure system is known for its high variability, the WDs are mostly nurtured by this system, thus in this way have indispensable influence on the variability of precipitation in north and northwestern parts of the country. The results also lead us to the assumption that the precipitation variability under discussion had link with remote atmospheric condition round Antarctic region that needs further scientific investigation especially at 700 hPa field. We have put forward the January precipitation variability with regional detail in Pakistan; this geographical approach could be the potential base line study for further scientific investigation.
Acknowledgements
We are grateful to the PMD for provision of ground observed data. We are thankful to the anonymous reviewers
as their comments and suggestions improved the paper substantially. We are highly grateful to the NCEP/ ANCAR for making the data available.
NOTES
*Corresponding author.