Abstract
Regional specific study of the most important climatic variables is essential to reduce the adverse effects of climate change in developing countries. In the present study, an attempt has been made to detect the trends in rainfall and temperature (past and future) time series and the possibility of any rational relationship between the trends and elevation over study region. The study was mainly focused on a part of Brahmaputra river basin in Northeast India, i.e., the Dikhow catchment (area = 3100 km2). The Dikhow catchment is a set of unique composite catchment topography comprising fairly higher altitude hills as well as alluvial plains at much lower elevation. Historically (from the year 1901 to 2002), annual precipitation and monsoon precipitation are decreasing significantly (5 % level of significance), whereas significant rise was observed on annual and seasonal basis for both maximum and minimum temperature time series. Further, during the entire time series (1901–2002), significant negative correlation was obtained between precipitation (annual and monsoon) trend magnitude and elevation of the study region. Significant rise for future precipitation was identified over the region for both A2 and B2 SRES scenarios, and winter precipitation is likely to increase more (59.18–69.44 % under A2 and 47.71–54.90 % under B2 over the catchment) than summer and monsoon precipitation. The maximum temperature has higher rate of rise than the minimum temperature for annual, summer, and monsoon temperature time series, while winter season shows higher rate of rise rather than the maximum temperature (1.02 °C over 102 years). For diurnal temperature range (DTR), monsoon season shows the significant rising which varies from 0.0016 to 0.0021 °C/year. Extreme temperature indices (TXx, TXn, TNx, and TNn) also show the significant warming picture over the catchment. Trend magnitude of extreme temperature indices and elevation shows significant relationship, while trend magnitude of the average maximum and minimum temperature and DTR does not show the noticeable connection between warming rate and elevation of the study area. Future Tmax and Tmin are increasing sharply for both A2 and B2 scenarios. A2 scenario shows higher rate than the B2 scenario.
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References
Barnett TP, Adam JC, Lettenmaier DP (2005) Potential impacts of a warming climate on water availability in snow-dominated regions. Nature 438(7066):303–309
Basistha A, Arya DS, Goel NK (2009) Analysis of historical changes in rainfall in the Indian Himalayas. Int J Climatol 29(4):555–572
Bhutiyani MR, Kale VS, Pawar NJ (2007) Long-term trends in maximum, minimum and mean annual air temperatures across the Northwestern Himalaya during the twentieth century. Clim Chang 85(1–2):159–177
Chaudhari QZ (1994) Pakistan’s summer monsoon rainfall associated with global and regional circulation features and its seasonal prediction. In: Proceedings of the international conference on monsoon variability and prediction, Trieste
Chen LX, Dong M, Shao YN (1992) The characteristic of international variations on the east Asian Monsoon. J Meteorol Soc Jpn 70:397–421
Chen B, Chao WC, Liu X (2003) Enhanced climatic warming in the Tibetan Plateau due to doubling CO2: a model study. Clim Dyn 20(4):401–413
Chowdary VM, Chandran RV, Neeti N, Bothale RV, Srivastava YK, Ingle P, Singh R (2008) Assessment of surface and sub-surface waterlogged areas in irrigation command areas of Bihar state using remote sensing and GIS. Agric Water Manag 95(7):754–766
Chowdhury A, Jha MK, Chowdary VM, Mal BC (2009) Integrated remote sensing and GIS‐based approach for assessing groundwater potential in West Medinipur district, West Bengal, India. Int J Remote Sens 30(1):231–250
Chung YS, Yoon MB (2000) Interpretation of recent temperature and precipitation trends observed in Korea. Theor Appl Climatol 67(3–4):171–180
Deka RL, Mahanta C, Nath KK (2009) Trends and fluctuations of temperature regime of North East India. Impact Clim Change Agric 376–380
Domroes M, El-Tantawi A (2005) Recent temporal and spatial temperature changes in Egypt. Int J Climatol 25:51–63
Duhan D, Pandey A, Gahalaut KPS, Pandey RP (2013) Spatial and temporal variability in maximum, minimum and mean air temperatures at Madhya Pradesh in central India. Compt Rendus Geosci 345(1):3–21
Easterling DR, Horton B, Jones PD, Peterson TC, Karl TR, Parker DE, Folland CK (1997) Maximum and minimum temperature trends for the globe. Science 277(5324):364–367
ElNesr MM, Abu-Zreig MM, Alazba AA (2010) Temperature trends and distribution in the Arabian Peninsula. Am J Environ Sci 6(2):191–203
Fowler HJ, Archer DR (2006) Conflicting signals of climatic change in the Upper Indus Basin. J Clim 19(17):4276–4293
Frauenfeld OW, Zhang T, Serreze MC (2005) Climate change and variability using European Centre for Medium‐Range Weather Forecasts reanalysis (ERA‐40) temperatures on the Tibetan Plateau. J Geophys Res Atmos 110(D2):1–9
Gadgil A, Dhorde A (2005) Temperature trends in twentieth century at Pune, India. Atmos Environ 39(35):6550–6556
Gain AK, Giupponi C (2015) A dynamic assessment of water scarcity risk in the lower Brahmaputra River Basin: an integrated approach. Ecol Indic 48:120–131
Giupponi C, Rosato P, Rounsevell M (1998) Integrated model to predict European land use: climate change and land use in the Venice Lagoon Watershed. In University of Minnesota, Center for International Food and Agricultural Policy conference papers, no. 14485, August
Goyal MK (2014) Statistical analysis of long term trends of rainfall during 1901–2002 at Assam, India. Water Resour Manag 28(6):1501–1515
Guan Y, Zhang X, Zheng F, Wang B (2015) Trends and variability of daily temperature extremes during 1960–2012 in the Yangtze River Basin, China. Glob Planet Chang 124:79–94
Haskett JD, Pachepsky YA, Acock B (2000) Effect of climate and atmospheric change on soybean water stress: a study of Iowa. Ecol Model 135(2):265–277
Hay LE, Clark MP (2003) Use of statistically and dynamically downscaled atmospheric model output for hydrologic simulations in three mountainous basins in the western United States. J Hydrol 282(1):56–75
Izrael Y, Anokin Y, Eliseev AD (1997) Vulnerability and adaptation assessments. Final report of the Russian country study on climate problem. Russian Federal service for hydrometeorology and environmental monitoring, vol 3, Task 3, Roshydromet, Moscow, Russia, p 105
Jeganathan A, Andimuthu R (2013) Temperature trends of Chennai City, India. Theor Appl Climatol 111(3–4):417–425
Jhajharia D, Singh VP (2011) Trends in temperature, diurnal temperature range and sunshine duration in Northeast India. Int J Climatol 31(9):1353–1367
Kadioglu M (1997) Trends in surface air temperature data over Turkey. Int J Climatol 17:511–520
Kang S, Zhang Y, Qin D, Ren J, Zhang Q, Grigholm B, Mayewski PA (2007) Recent temperature increase recorded in an ice core in the source region of Yangtze River. Chin Sci Bull 52(6):825–831
Kumar KR, Kumar KK, Pant GB (1994) Diurnal asymmetry of surface temperature trends over India. Geophys Res Lett 21(8):677–680
Lu A, He Y, Zhang Z, Pang H, Gu J (2004) Regional structure of global warming across China during twentieth century. Clim Res 27:189–195
Mirza MQ, Dixit A (1997) Climate change and water management in the GBM Basins. Water Nepal 5:71–100
Murphy J (1999) An evaluation of statistical and dynamical techniques for downscaling local climate. J Clim 12(8):2256–2284
Pandey A, Chowdary VM, Mal BC, Billib M (2008) Runoff and sediment yield modeling from a small agricultural watershed in India using the WEPP model. J Hydrol 348(3):305–319
Pepin NC, Lundquist JD (2008) Temperature trends at high elevations: patterns across the globe. Geophys Res Lett 35(14):1–6
Pepin NC, Seidel DJ (2005) A global comparison of surface and free‐air temperatures at high elevations. J Geophys Res: Atmos 110(D3)
Rankova E (1998) Climate change during the 20th century for the Russian Federation. In: Abstract book of the 7th international meeting on statistical climatology, Whistler, British Columbia, Canada, May 25–29, Abstract 102–198
Ren G, Wu H, Chen Z (2000) Spatial pattern of precipitation change trend of the last 46 years over China. J Appl Meteorol 11(3):322–330
Roy SS, Balling RC (2005) Analysis of trends in maximum and minimum temperature, diurnal temperature range, and cloud cover over India. Geophys Res Lett 32(12):1–4
Salinger MJ, Griffiths GM (2001) Trends in New Zealand daily temperature and rainfall extremes. Int J Climatol 21:1437–1452
Schoof JT, Pryor SC (2001) Downscaling temperature and precipitation: a comparison of regression‐based methods and artificial neural networks. Int J Climatol 21(7):773–790
Sharma N, Flügel WA (eds) (2015) Applied geoinformatics for sustainable Integrated Land and Water Resources Management (ILWRM) in the Brahmaputra River Basin: results from the EC-project BRAHMATWINN. Springer, New Delhi, Heidelberg, New York, Dordrecht, London
Singh A, Krause P, Panda SN, Flugel WA (2010) Rising water table: a threat to sustainable agriculture in an irrigated semi-arid region of Haryana, India. Agric Water Manag 97(10):1443–1451
Song ZW, Zhang HL, Snyder RL, Anderson FE, Chen F (2009) Distribution and trends in reference evapotranspiration in the North China Plain. J Irrig Drain Eng 136(4):240–247
Subash N, Sikka AK (2014) Trend analysis of rainfall and temperature and its relationship over India. Theor Appl Climatol 117(3–4):449–462
Tian L, Yao T, MacClune K, White JWC. Schilla A, Vaughn B, Ichiyanagi K (2007) Stable isotopic variations in west China: a consideration of moisture sources. J Geophys Res Atmos 112(D10):1–12
Tomozeiu R, Pavan V, Cacciamani C, Amici M (2006) Observed temperature changes in Emilia-Romagna: mean values and extremes. Clim Res 31:217–225
Vuille M, Bradley RS (2000) Mean annual temperature trends and their vertical structure in the tropical Andes. Geophys Res Lett 27(23):3885–3888
Warwade P, Hardaha MK, Kumar D, Chandniha SK (2014) Estimation of soil erosion and crop suitability for a watershed through remote sensing and GIS approach. Indian J Agric Sci 84(1):18–23
Warwade P, Kumari D, Sharma N (2015) Trends in reference evapotranspiration of Dikhow catchment, North East India. Int J Trop Agric 33(2 (Part IV)):1571–1578
Wibig J, Glowicki B (2002) Trends of minimum and maximum temperature in Poland. Clim Res 20:123–133
You QL, Kang S, Flügel WA, Pepin N, Yan Y, Huang J (2010) Decreasing wind speed and weakening latitudinal surface pressure gradients in the Tibetan Plateau. Clim Res 42(1):57–64
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Warwade, P., Sharma, N., Pandey, A., Ahrens, B. (2017). Analysis of Climate Variability in a Part of Brahmaputra River Basin in India. In: Sharma, N. (eds) River System Analysis and Management . Springer, Singapore. https://doi.org/10.1007/978-981-10-1472-7_7
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DOI: https://doi.org/10.1007/978-981-10-1472-7_7
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