Comparison of temperature lapse rates from the northern to the southern slopes of the Himalayas

Kattel, Dambaru Ballab; Yao, Tandong; Yang, Wei; Gao, Yang; Tian, Lide

doi:10.1002/joc.4297

Cited by 89 publications

(106 citation statements)

References 61 publications

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“…Fundamentally, with increase in elevation, the near-surface air temperature decreases commonly known as temperature lapse rate (Kattel et al, 2015). Fundamentally, with increase in elevation, the near-surface air temperature decreases commonly known as temperature lapse rate (Kattel et al, 2015).…”

Section: 1029/2018jd029811mentioning

confidence: 99%

Distributed Hydrological Modeling Framework for Quantitative and Spatial Bias Correction for Rainfall, Snowfall, and Mixed‐Phase Precipitation Using Vertical Profile of Temperature

et al. 2019

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Mountain snowpack and its distribution both have intimate connections to regional hydrology by preserving winter precipitation to sustain streamflows during the summer months. One of the key knowledge gaps in mountainous region is the interplay of precipitation and temperature with changing altitudes. Three‐dimensional temperature distribution is pivotal for the realistic temporal and spatial distribution of precipitation with pattern (rain/snow). The environmental/linear lapse rates are inadequate to address snow processes, resulting in significant uncertainties. An effort is made in this study to develop a vertical profile of temperature (VPT) and apply it as a dynamic temperature lapse rate to curtail uncertainties. The VPT was used for the spatiotemporal bias correction of precipitation by targeting accessible data sources based on the quantitative and spatial analysis in a distributed hydrologic modeling framework with a logical calibration and validation. The water and energy budget‐based distributed hydrological model with snow was utilized to simulate the streamflows and spatial distribution of snow cover based on VPT and corrected precipitation. During calibration and validation phase, the simulated discharge resulted with Nash‐Sutcliffe Efficiency over 0.76 and 0.71, respectively. Moreover, the output for the spatial distribution of snow cover evaluated against Moderate Resolution Imaging Spectroradiometer‐derived 8‐day maximum snow cover extents by employing pixel‐by‐pixel analysis with average model accuracy over 88.28% and 85.89%. To the authors' knowledge, it is the first study to integrate VPT in hydrologic modeling with robust potential for optimal water resource management in the data scarce region.

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Section: 1029/2018jd029811mentioning

confidence: 99%

Distributed Hydrological Modeling Framework for Quantitative and Spatial Bias Correction for Rainfall, Snowfall, and Mixed‐Phase Precipitation Using Vertical Profile of Temperature

et al. 2019

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“…We also calculated the mean July temperature for each plot of the Tibetan Plateau data set. July temperatures were obtained based on the altitude differences between the plots and weather station and monthly temperature lapse rates were defined for the SCTP by Kattel et al (2013) and for the SETP by Kattel et al (2015). In contrast to temperatures, the altitudinal changes in precipitation on the Tibetan Plateau strongly varied between different parts of the region.…”

Section: Climate Data Setsmentioning

confidence: 99%

Tree growth and its climate signal along latitudinal and altitudinal gradients: comparison of tree rings between Finland and the Tibetan Plateau

et al. 2017

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Abstract. Latitudinal and altitudinal gradients can be utilized to forecast the impact of climate change on forests. To improve the understanding of how these gradients impact forest dynamics, we tested two hypotheses: (1) the change of the tree growth-climate relationship is similar along both latitudinal and altitudinal gradients, and (2) the time periods during which climate affects growth the most occur later towards higher latitudes and altitudes. To address this, we utilized tree-ring data from a latitudinal gradient in Finland and from two altitudinal gradients on the Tibetan Plateau. We analysed the latitudinal and altitudinal growth patterns in tree rings and investigated the growth-climate relationship of trees by correlating ring-width index chronologies with climate variables, calculating with flexible time windows, and using daily-resolution climate data. High latitude and altitude plots showed higher correlations between tree-ring chronologies and growing season temperature. However, the effects of winter temperature showed contrasting patterns for the gradients. The timing of the highest correlation with temperatures during the growing season at southern sites was approximately 1 month ahead of that at northern sites in the latitudinal gradient. In one out of two altitudinal gradients, the timing for the strongest negative correlation with temperature at low-altitude sites was ahead of treeline sites during the growing season, possibly due to differences in moisture limitation. Mean values and the standard deviation of treering width increased with increasing mean July temperatures on both types of gradients. Our results showed similarities of tree growth responses to increasing seasonal temperature between latitudinal and altitudinal gradients. However, differences in climate-growth relationships were also found between gradients due to differences in other factors such as moisture conditions. Changes in the timing of the most critical climate variables demonstrated the necessity for the use of daily-resolution climate data in environmental gradient studies.

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“…This study indicated that the SAT decreased with a temperature lapse rate of -5.2 (October) to -8.2°C km -1 (February). Recent studies showed that the temperature lapse rates had a seasonal cycle which was due to the elevation-induced air-flow and inversion effect (Kattel et al 2015). The surface solar radiation should be determined by the geographical location if the land surface is absolutely flat.…”

Section: Discussion Topographic Effects and Spatial Scalesmentioning

confidence: 99%

“…The mountain climate simulator (MTCLIM) was used to predict the SAT according to the base temperatures and a temperature lapse rate in mountain areas (Li et al 2001;Lo et al 2011;Running et al 1987). Recent studies have made progresses pertaining to the multivariate colinearity effect of different factors in large-scale areas (Kattel and Yao 2013;Kattel et al 2015). In most studies, latitude, longitude, and elevation were preferred factors when topography was correlated with the SAT (Brown and Comrie 2002;Goodale et al 1998;Lookingbill and Urban 2003;Ollinger et al 1995).…”

Section: Introductionmentioning

confidence: 99%

Topographic effects on spatial pattern of surface air temperature in complex mountain environment

Sun

Zhang

2016

Environ Earth Sci

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Understanding topographic effects on surface air temperature (SAT) is essential in developing an accurate prediction model in complex mountain environment. A nonlinear topographic regression model is developed to predict the spatial SAT pattern using latitude, elevation, slope, and aspect. Monthly SAT data have been collected from 14 meteorological stations between 1960 and 2010 in the Daqing Mountains of China. Topographic data are acquired from a 30 m resolution digital elevation model of the study region. Results show that: (1) the SAT models are able to explain 89-95.8 % of the spatial variation in different months. Elevation has the strongest effect on the SAT variation in all months (average 84.78 %). (2) The combined contribution of slope and aspect to SAT variations is larger (average 9.14 %) than that of latitude (average 6.07 %). (3) The combined effect of slope and aspect on SAT variations is higher in winter than in summer. The introduction of slope and aspect optimizes the SAT modeling in different months. In further studies, the accuracy of SAT model might be improved by introducing alternative topographic factors to capture the vegetation and weather condition.

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Comparison of temperature lapse rates from the northern to the southern slopes of the Himalayas

Cited by 89 publications

References 61 publications

Distributed Hydrological Modeling Framework for Quantitative and Spatial Bias Correction for Rainfall, Snowfall, and Mixed‐Phase Precipitation Using Vertical Profile of Temperature

Distributed Hydrological Modeling Framework for Quantitative and Spatial Bias Correction for Rainfall, Snowfall, and Mixed‐Phase Precipitation Using Vertical Profile of Temperature

Tree growth and its climate signal along latitudinal and altitudinal gradients: comparison of tree rings between Finland and the Tibetan Plateau

Topographic effects on spatial pattern of surface air temperature in complex mountain environment

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