Environ Earth Sci (2017)76:635 DOI 10.1007/s12665-017-6976-z
ORIGINAL ARTICLE
Assessment of land use land cover change impact on hydrological regime of a basin Vaibhav Garg1 • S. P. Aggarwal1 • Prasun K. Gupta2 • Bhaskar R. Nikam1 Praveen K. Thakur1 • S. K. Srivastav3 • A. Senthil Kumar3
•
Received: 24 May 2016 / Accepted: 8 September 2017 Springer-Verlag GmbH Germany 2017
Abstract The sustainability of water resources mainly depends on planning and management of land use; a small change in it may affect water yield largely, as both are linked through relevant hydrological processes, explicitly. However, human activities, especially a significant increase in population, in-migration and accelerated socioeconomic activities, are constantly modifying the land use and land cover (LULC) pattern. The impact of such changes in LULC on the hydrological regime of a basin is of widespread concern and a great challenge to the water resource engineers. While studying these impacts, the issue that prevails is the selection of a hydrological model that may be able to accommodate spatial and temporal dynamics of the basin with higher accuracy. Therefore, in the present study, the capabilities of variable infiltration capacity hydrological model to hydrologically simulate the basin under varying LULC scenarios have been investigated. For the present analysis, the Pennar River Basin, Andhra Pradesh, which falls under a water scarce region in India, has been chosen. The water balance components such as runoff potential, evapotranspiration (ET) and & Vaibhav Garg
[email protected] 1
Water Resources Department, Indian Institute of Remote Sensing, Indian Space Research Organisation, Department of Space, Government of India, 4, Kalidas Road, Dehradun, Uttarakhand 248 001, India
2
Geo-informatics Department, Indian Institute of Remote Sensing, Indian Space Research Organisation, Department of Space, Government of India, 4, Kalidas Road, Dehradun, Uttarakhand 248 001, India
3
Indian Institute of Remote Sensing, Indian Space Research Organisation, Department of Space, Government of India, 4, Kalidas Road, Dehradun, Uttarakhand 248 001, India
baseflow of Pennar Basin have been simulated under different LULC scenarios to study the impact of change on hydrological regime of a basin. Majorly, increase in builtup (13.94% approx.) and decrease in deciduous forest cover (2.44%) are the significant changes observed in the basin during the last three decades. It was found that the impact of LULC change on hydrology is balancing out at basin scale (considering the entire basin, while routing the runoff at the basin outlet). Therefore, an analysis on spatial variation in each of the water balance components considered in the study was done at grid scale. It was observed that the impact of LULC is considerable spatially at grid level, and the maximum increase of 265 mm (1985–2005) and the decrease of 48 mm (1985–1995) in runoff generation at grid were estimated. On the contrary, ET component showed the maximum increase of 400 and decrease of 570 mm under different LULC change scenario. Similarly, in the base flow parameter, an increase of 70 mm and the decrease of 100 mm were observed. It was noticed that the upper basin is showing an increasing trend in almost all hydrological components as compared to the lower basin. Based on this basin scale study, it was concluded that change in the land cover alters the hydrology; however, it needs to be studied at finer spatial scale rather than the entire basin as a whole. The information like the spatial variation in hydrological components may be very useful for local authority and decision-makers to plan mitigation strategies accordingly. Keywords Hydrology and water resource Land use land cover change Runoff potential Hydrological modelling Models (physical) Variable infiltration capacity model Impact assessment
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Introduction The present analysis focuses on the impact of LULC change on hydrology of a water scarce river basin. A complex relationship exists between LULC and hydrology involving a large variety of surface–vegetation–atmosphere interactions at varying spatial and temporal scales (DeFries and Eshleman 2004; Dwarakish and Ganasri 2015). LULC has been considered as a driver to almost all hydrological processes such as evapotranspiration (ET), groundwater recharge and overland flow (Wilk and Hughes 2002; Mustard and Fisher 2004; Zhao et al. 2013). According to Chase et al. (2000), the LULC change affects the precipitation and temperature pattern, the fundamental driving forces of the hydrological cycle. Consequently, it alters the entire water balance that exists between evaporation, groundwater recharge and stream discharge of a region or basin (Sahin and Hall 1996; DeFries and Eshleman 2004). It is reported that the LULC change is the main driver in the increase of river discharge worldwide, since 1900 (Piao et al. 2007; Obahoundje et al. 2017). Among different categories of LULC change, it is observed that deforestation alone is the major cause of changes in various hydrological processes, such as ET, stream flow, accumulation and snowmelt processes (Bosch and Hewlett 1982; Gao et al. 2009; Dwarakish and Ganasri 2015; Obahoundje et al. 2017). It is also reported that developing countries, such as India, are likely to witness drastic change in the present century due to inadvertent urbanization (Gosain et al. 2006; Wagner et al. 2013). The consequent change in climate as a result of such changes is thus likely to be more severe in such countries due to poor adaptability (Gosain et al. 2006). Moreover, in the recent times, many of the river basins in the country are facing adverse hydrometeorological conditions, such as floods, droughts and cyclones repetitively (Gosain et al. 2006; Mall et al. 2007; Singh et al. 2010; Gosain et al. 2011). The frequent reoccurrence of such events indicates the shift in the hydrological response of the river basins (Aggarwal et al. 2012). The drivers responsible for changes in land use fall essentially in two categories: biophysical drivers and socioeconomic drivers (Lo and Yang 2002; Kindu et al. 2015). The biophysical drivers include characteristics and processes of the natural environment, such as elevation, slope, soil types and climatic variables, whereas socio-economic drivers mainly include demographic, social, economic, political and technological factors. Many studies have indicated that human actions, mediated by socio-economic drivers, are mainly responsible for land use change in the recent past which in turn has altered the distribution of water resources (Bosch and Hewlett 1982; Stednick 1996; Matheussen et al. 2000; Foley et al. 2004; Gao et al. 2009;
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Petchprayoon et al. 2010; Schilling et al. 2010). To understand the cause-and-effect relation between LULC change and hydrology, the following key questions need to be answered: (1) where LULC changes have taken place in the past; (2) what are the drivers or determinants of land use change, (3) how information on these drivers can be used to project future LULC patterns and (4) what will be the consequences of change in LULC (Lambin et al. 2003). However, the availability of reliable information about the past and present status of these changes in a spatially distributed form and at appropriate scale is one of the major issues in global change studies. In this regard, the capabilities of remote sensing can be utilized which provides synoptic coverage of earth at regular interval. Another problem confronted by water resources engineer is the selection of an appropriate hydrological model which can simulate impact of LULC change on hydrological components. The impact of such changes on hydrology can be best evaluated through a physically based, distributed hydrological model capable of simulating complex hydrological processes, governed by a large number of biophysical variables of the land surface and climatic forcing. Dwarakish and Ganasri (2015) have carried out comprehensive review of hydrological models suitable for the LULC change impact studies. The gridbased, Water Flow and Balance Simulation Model (WaSiM), which is a deterministic spatially distributed hydrological catchment model, has been applied for the purpose at meso-scale catchments (Niehoff et al. 2002; Verbunt et al. 2005; Shrestha et al. 2007; Krause et al. 2007; Merta et al. 2008; Cornelissen et al. 2013; Liu et al. 2013). The most favoured model for such analysis is Soil and Water Assessment Tool (SWAT) hydrological modelling (Schilling et al. 2008; Githui et al. 2009; Nie et al. 2011; Wang and Kalin 2011; Deng et al. 2014; Woldesenbet et al. 2017). SWAT works on hydrological response units (based on LULC, soil and slope) and runs at daily time step. However, the snowmelt runoff calculation of SWAT is temperature based. Hydrologic Engineering Center–Hydrological Modeling System (HEC-HMS) is another hydrological model widely used (Olang and Fu¨rst 2011). However, it has been developed for storm events and works on sub-basin scale. The MIKE-SHE modelling approach has also been attempted in this regard which works on subcatchment scale (Im et al. 2009). The high cost and the computational intensive nature of MIKE-SHE are its limitations. Except MIKE-SHE, none of the abovementioned models are compatible with gridded climatic parameter outputs of general circulation model (GCM). Therefore, one has to simulate two different models to study the impact of climate change and LULC change on hydrology. Moreover, the GCM outputs cannot be handled by micro-scale models, easily. In such a case,
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efficient downscaling technique has to be performed to produce future climatic parameters at desired scale. In recent past, soil–vegetation–atmosphere transfer schemes (SVATS) have been explicitly developed to represent the land surface partitioning of net radiation into latent, sensible and ground heat fluxes in climate and weather forecast models. ‘‘These models consider the role of vegetation in estimation of evapotranspiration. Furthermore, these models do surface energy balance by reiterating on effective temperatures’’ (Lettenmaier 2001). Moreover, these models generally emphasize on vertical/column processes also, such as extraction of soil moisture by vegetation and transpiration, those involve interaction of vegetation, soil moisture and surface atmosphere and their feedback.
Overview of variable infiltration capacity hydrological model The VIC model, which has also been developed as a SVATS by Liang et al. (1994), has been used for Indian Basin in the present study. It is a physically based, semidistributed hydrological model which quantifies the dominant hydrometeorological process taking place at the land surface atmosphere interface over large river basins to the entire globe (Aggarwal et al. 2013). The distinguishing features of VIC over other land surface models are as follows: •
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it considers subgrid variability in land surface vegetation classes and explicitly represents its effects on water and energy budgets; the representation of soil moisture storage capacity as a spatial probability distribution at subgrid level, to estimate surface runoff (Zhao et al. 1980); its parameterization of drainage from the lower soil moisture zone (base flow) as a nonlinear recession (Dumenil and Todini 1992); incorporation of the topography which in turn considers orographic precipitation and temperature lapse rate, resulting in more realistic results for mountainous regions (Gao et al. 2009); the inclusion of both the saturation and infiltration excess runoff processes with a consideration of the subgrid-scale soil heterogeneity at model grid cell (Lohmann et al. 1998a, b; Liang and Xie 2003); the frozen soil processes consideration for cold climate conditions (Cherkauer and Lettenmaier 1999); it solves full surface energy and water balances (Gao et al. 2009); it has separate routing module based on a linear transfer function to simulate the stream flow;
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it also incorporates water management effects including reservoir operation, irrigation diversions and return flows (Haddeland et al. 2006a, b; Haddeland et al. 2007); it can be coupled with GCM and other climate models.
VIC model has been validated and adopted at a range of spatial scales, from large river basins to continental and global scales. Within North America, it has been applied at 1˚ spatial resolution to the Missouri (Wood et al. 1997), Arkansas-Red River (Abdulla et al. 1996), Columbia River Basins (Nijssen et al. 1997) and at 0.5 resolution to the Delaware River (Nijssen et al. 1997), Weser River Basin in Germany (Lohmann et al. 1998a, b). The grid network version of the two-layer VIC (VIC-2L) model together with a linear routing scheme was able to estimate daily, monthly and annual stream flow with reasonable accuracy. As a part of the Land Data Assimilation System project, Maurer et al. (2001a) carried out a detailed diagnosis of VIC model results of 50-year simulations over the central USA for model validation and parameterizations. Liang et al. (2004) adopted three-layer VIC (VIC-3L) model to investigate the impacts of spatially distributed precipitation and soil heterogeneity on modelling water fluxes of Blue River Watershed (1233 km2 area), Oklahoma, at different spatial resolutions. Yuan et al. (2004) applied VIC-3L land surface model to simulate stream flow for the Hanjiang River Basin in China. In this case study, the simulated runoff was routed and compared at six different outlets for the daily and monthly observed stream flow at these stations. It was reported that the model can simulate the observations with reasonable accuracy. Aggarwal et al. (2013) implemented the model for entire Indian landmass at 0.25 9 0.25 grid and studied the water balance of major river basins with very high accuracy. In a similar study, Garg et al. (2016) studied the water balance components of Godavari Basin, one of the major river basins in India at 5 9 5 km grid using VIC-3L model. The application of VIC model to simulate impact of LULC change on hydrology is in nascent stage. Matheussen et al. (2000) analysed two land cover scenarios (historical and a current) and its impact on hydrology of the Columbia River Basin at 0.25 spatial grid for the period of 1979–1990. An annual average increase in runoff in the sub-basins ranged from 4.2 to 10.7%, and decreases in ET ranged from 3.1 to 12.1%. The declination in forest cover found to increase stream flow as a result of reduced ET. This study provided a broad-scale framework for assessing the vulnerability of watersheds to altered hydrological regimes attributed to changes in LULC that occur over large geographical areas on long time frames. In a similar study, Dadhwal et al. (2010) carried out hydrological simulation of Mahanadi River Basin to study impact of
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LULC change on surface runoff using VIC model. An increase by 24.44 mm in the annual stream flow was observed at Mundali outlet of the basin from 1972 to 2003. It was concluded that a decrease in forest cover by 5.71% has caused the river flow to increase by 4.53%. Hurkmans et al. (2009) investigated the VIC model to study the effects of land use changes on average stream flow for various locations in the Rhine Basin for projected year 2030 under different scenarios. However, the model was forced with meteorological data of the period 1993–2003. Under each land use change scenario, an increase in stream flow was observed with magnitude varying from about 2% in different sub-basins in the upstream part of the Rhine to about 30% in the Lahn Basin. Due to diverse climatic and topographical features, the availability of water is highly erratic both spatially and temporally across India. The estimated annual precipitation including snowfall which the country receives is 4000 km3. However, the surface runoff potential in the rivers is about 1869 km3 as per the basinwise estimates of Central Water Commission (CWC), India (Garg and Hassan 2007; Mall et al. 2007; Mujumdar 2008). According to the distribution of water resources potential in the country, the national per capita annual availability of water was 1731 m3 as on 2004 (Mujumdar 2008). Per capita annual availability for rest of the country excluding Brahmaputra and Barak Basin works out to about 1345 m3. The Cauvery, Sabarmati, eastflowing rivers and west-flowing river basins fall into waterstressed category, where the availability of water is less than 1000 m3 per capita, which is considered as scarcity condition by international agencies (Gosain et al. 2006; Mujumdar 2008; CWC 2015). Moreover, the developmental activities going on in the country again put stress on future water availability. Considering all these aspects, there is a need to assess LULC change and its impact on hydrological regime of major basins in the country. However, each river basin is characterized by its typical topography, hydrology, climate and anthropogenic influence. In the present study, a detailed analysis of impact of LULC change on hydrological regime of the Pennar Basin has been carried out. Pennar River is one of the major eastflowing rivers and is considered as ‘‘water scarce’’ basin as per UN indicators (CWC 2015; Jain et al. 2009). The basin requires appropriate water management strategy, and the adapted methodology of the present study is described in the subsequent section.
Study area The Pennar River is one of the major east-flowing rivers in India, and it rises in the Thenanahesava hill of the Nandidurg range in Karnataka, drains into the Bay of Bengal
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near Nellore, Andhra Pradesh, and covers a total length of 597 km. The basin encompasses an area of 54,970 km2, and its location is shown in Fig. 1. The fan-shaped Pennar Basin is lying within 13150 –15500 N latitude and 77100 – 80100 E longitude. The major tributaries of the river are Jayamangali, Kunderu, Sagileru, Chitravathi, Papagani and Cheyyeru. The Somashila is the major hydro project in this river basin. There are 07 hydrological observation sites lying in the basin, namely Nagalamadike, Singavaram, Tadipattri, Kamalapuram, Alladupalli, Nandipalli and Nellore (CWC 2015). The elevation in basin varies from \5 to 1250 m. The basin receives rainfall in both the (southwest and northeast) monsoon. However, as the basin lies in a semiarid region, it experiences low rainfall. The rainfall in the basin varies from region to region, and the coastal areas of the basins experience heavier rainfall than western parts. The average annual rainfall of the basin is around 825 mm (CWC 2015). High humidity has been observed during monsoon period, whereas moderate during nonmonsoon. The annual mean temperature of the basin is around 27.17 C, whereas the annual average maximum and minimum temperature of the basin is around 32.71 and 21.63 C, respectively (CWC and NRSC 2014). The major part of the basin is used for agriculture (*53%) and secondly is covered by forest (*20%). Mostly, the basin is composed of fine- to medium-textured clayey soils.
Methodology Assessment of LULC change In order to assess LULC change, initially, the decadal LULC data developed under Indian Space Research Organisation Geosphere Biosphere Programme (ISROGBP): Land Use Land Cover dynamics and impact of Human Dimension in Indian river basins project for the years 1985, 1995 and 2005 at a 1:250,000 scale, were used (as shown in Fig. 3). The existing LULC database of the year 2005 at 1:50,000 scale, prepared under the Natural Resources Census Project of the Natural Resources Repository Programme of the Department of Space, Government of India, is harmonized at 1:250,000 scale following the International Geosphere Biosphere Programme (IGBP) classification scheme adopted by ISROGBP. This harmonized LULC map of 2005 at 1:250,000 scale forms the reference data, based on which changes in LULC units during 1995 and 1985 are mapped using spatially referenced satellite images of the corresponding periods. Firstly, the area of each LULC class for all the years has been identified in ArcGIS 10.1. Then, the area weighted percentage change in each LULC class has been
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Fig. 1 Location of Pennar Basin in India (Source: India-WRIS), Location of gauging station on drainage map and generated 5 9 5 km grid map laid over DEM (DEM Source: USGS)
studied considering 1985 as a base year. Then, the simple subtraction of area has been taken as change of particular LULC class in a particular time period. Later, the decadal change between LULC has been analysed, considering LULC of year 1985 as base year. The details of the LULC change analysis can be found as LULC change matrices and figures in result section. Finally, the daily hydrological simulation of Pennar Basin has been carried out using the three soil-layered VIC (VIC-3L) hydrological models to study the impact of LULC change on its hydrological regime. The Pennar Basin has been transformed to 5 9 5 km scale grid as shown in Fig. 1. Masking of Pennar Basin and grid map was done to identify the active grids to be used as an input for the model. It was found that around 1865 grids are lying within the Pennar Basin boundary and are considered for hydrological simulations. The details of the model requirements and data used are presented in the subsequent section. Hydrological model parameterization As VIC requires land surface characteristics such as soil data, topography and vegetation parameters, the four major input files: soil parameter, vegetation parameter, vegetation library and forcing files were prepared for each grid. The soil parameter file used by VIC describes the unique soil properties for each grid cell in the model domain. In the present analysis, soil texture information and bulk densities
were derived from the National Bureau of Soil Survey and Land Use Planning (NBSS&LUP) digitized soil map as shown in Fig. 2. The soil texture class with highest reoccurrence (on area basis) within a grid has been designated as soil texture class for that particular grid. In this region, generally sand, loam, clay, clay skeletal and loamy skeletal textured soils are present. The file also identifies the grid cells to be simulated based on their latitudes and longitudes and to find the forcing files for the particular grid. The parameters such as porosity, saturated soil potential, saturated hydraulic conductivity and the exponent for each texture class under unsaturated flow condition were calculated for each grid using pedo-transfer functions suggested by Cosby et al. (1984). The parameters used to calibrate the model were: thickness of each soil layer, di; the exponent of the infiltration capacity curve, bi; and the three parameters in the baseflow scheme: Dsmax is the maximum baseflow velocity in mm/day, Ds is the fraction of maximum baseflow velocity, and Ws is the fraction of maximum soil moisture content of the third soil layer at which nonlinear baseflow occurs. The specific soil characteristics (e.g. field capacity, wilting point and saturated hydraulic conductivity) for each grid were obtained from algorithms developed by Cosby et al. (1984), Rawls et al. (1998) and Reynolds et al. (2000). The topographic parameters, namely elevation and slope, were derived from GTOPO30 (90-m resolution) digital elevation model (http://edc.usgs.gov/products/elevation/gtopo30/gtopo30. html) as shown in Fig. 1.
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Fig. 2 Soil texture map of Pennar Basin (Data Source: NBSS & LUP)
The vegetation parameter and vegetation library files were prepared for the years 1985, 1995 and 2005 from LULC maps developed under ISRO-GBP Project at a 1:250,000 scale, as discussed earlier. From these data, the land cover types and their fraction of the grid cell occupied by each are identified, as described by Maurer et al. (2001a, b) in the model domain for generation of vegetation parameter file, which uses the same grid cell numbering as the soil file. Rooting depth for each land use class is also specified, which enables shorter crops and grasses draw moisture from the upper soil layers and tree roots from the deeper soil layer. This file cross-indexes each vegetation tile to the classes listed in the vegetation library (http://www.hydro.washington.edu/Lettenmaier/Models/ VIC/). Leaf area index (LAI) is the important characteristic of the land cover that affects the VIC model hydrological simulation. The monthly mean LAI corresponding to each vegetation class has been picked from the Moderate Resolution Imaging Spectroradiometer (MODIS) data product on LAI (http://ladsweb.nascom.nasa.gov/data/search.html) and stored in vegetation library file. The LAI values for a
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particular LULC class will change seasonally; hence, intraannual variations in vegetation characteristics have been incorporated at monthly timescale using monthly LAI for respective classes. The additional parameters of vegetation library file, namely roughness length and displacement height (in m), architectural resistance (in s/m) and minimum stomatal resistance (in s/m) for each vegetation tile, were assembled based on Global Land Data Assimilation System database (http://ldas.gsfc.nasa.gov/gldas/GLDAS mapveg.php). Initially, the VIC-3L model was forced with daily observed surface meteorological data which include precipitation, minimum temperature, maximum temperature and wind speed for 34 years (1951–1984) at daily time step for calibration against long-term observed average discharge available at Global Runoff Data Centre (http:// www.bafg.de/GRDC/EN/01_GRDC/13_dtbse/database_ node.html). The forcing file of each grid for each year has been prepared using Indian Meteorological Department (IMD) gridded data (Pai 2014) on rainfall (0.25 9 0.25) and temperature (1 9 1).
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Model calibration As seen in the above section, alike other physically based hydrological models, the VIC model also has many parameters that must be specified. Most of these parameters can be derived from in situ measurement and remote sensing observation. Six of them are considered as calibration parameters, namely bi, d2, d3, Dsmax, Ds and Ws. bi describes the amount of available infiltration capacity as a function of relative saturated grid cell area and hence controls the partitioning of precipitation into infiltration and direct runoff as it. The high value of bi gives low infiltration and yields more surface runoff. The d2 and d3 are the soil layer thicknesses for second and third layers that control the availability of water for transpiration and baseflow, respectively. The thicker soil depths will dominate evapotranspiration, baseflow and lower down runoff response. On the other hand, it will retain soil moisture for long and results in higher baseflow in wet seasons. As in Pennar Basin, mostly deep soils are present, the d2 and d3 were kept constant as 6 and 0.5 m. However, the baseflow parameters, namely Dsmax, Ds and Ws, govern the water stored in the lowest soil layer and its release as baseflow (Liang et al. 1994). The higher the value of Ds, the higher the baseflow at lower water content in the lowest soil layer. A higher value of Ws will raise the water content required for baseflow and delay runoff peaks. Later, the calibrated model was forced with the same meteorological parameters for period (1980–2010) with vegetation parameter files of each year, i.e. 1985, 1995 and 2005, under consideration, separately. The meteorological forcing for period (1980–2010) was kept constant for entire simulations; however, only vegetation parameter file of years under consideration (i.e. 1985, 1995 and 2005) was changed in each simulation to study impact of LULC change on the water balance components.
Results and discussion Assessment of LULC change To study the LULC change, the LULC database developed under ISRO-GBP LULC Project for all the years 1985, 1995 and 2005 has been procured as shown in Fig. 3. Then, the decadal change in LULC has been analysed, considering LULC of year 1985 as base year as shown in LULC change matrices for the period 1985–1995 and 1985–2005 which are reported in Table 1 There is very less change observed in LULC between 1985 and 1995. However, a considerable change has been noticed between 1985 and 2005 (refer Fig. 4), and this may be attributed to developmental activities in the basin area in
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the last twenty-year time span. It was observed that there is a maximum increase in built-up class (13.94% approx.) and corresponding maximum decline in deciduous forest by 2.44% between years 1985 and 2005. Certainly, this change in LULC pattern will have an effect on hydrology of the basin. Impact of LULC change on hydrology To study the influence of LULC on hydrological regime of Pennar Basin, VIC-3L hydrological model has been utilized. Initially, the model was forced with daily meteorological parameters, namely rainfall, maximum temperature, minimum temperature and wind speed for period 1951–1984 (34 years). The NBSS&LUP soil texture data and LULC of year 1985 were used to derive soil parameter file and vegetation parameter files, respectively, as described in the previous section. The runoff estimated was routed at the basin outlet near Nellore, Andhra Pradesh, India (shown in Fig. 1) using VIC’s routing model as described in detail by Lohmann et al. (1996, 1998a). The calibration parameters as discussed in methodology section were adjusted through a trial-and-error procedure until acceptable match between estimated and observed discharge was found. The usual range and calibrated values of these parameters are provided in Table 2. As the long-term (1965–79) monthly average discharge data were available at GRDC, the estimated discharge between these periods was averaged in order to validate the model. The comparison of mean monthly estimated and observed discharge data is shown in Fig. 5. Later, the calibrated VIC-3L hydrological model has been investigated to study the impact of LULC change on hydrological regime of Pennar Basin. In this analysis, in order to study impact of LULC change, the meteorological forcing which was comprised of daily precipitation, daily minimum temperature, daily maximum temperature and daily wind speed (for period 1980–2010) has to be kept uniform for the years under consideration, i.e. 1985, 1995 and 2005. Only the vegetation parameter file corresponding to the particular year, i.e. 1985/1995/2005 was changed for hydrological simulation using VIC-3L. The simulation has been carried out for period 1980–2010, so that the model gets stabilized with good amount of warming period. The model generates separate flux files for each grid as an output which is comprised of precipitation, surface runoff, evaporation from canopy, evaporation from bare soil, transpiration from canopy, baseflow and soil moisture for each soil layer. The gridwise results of each simulation year, i.e. 1985, 1995 and 2005, were averaged to find out basin average hydrological components for the basin. The study indicates that all the water balance components are varying in accordance with general change in LULC; the
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Fig. 3 LULC map of the basin for years 1985, 1995 and 2005 (Data Source: ISRO-GBP) Table 1 LULC change (km2) matrix for the period 1985–1995 and 1985–2005 1995 BU 1985
Total CL
FL
PL
DBF
MF
SL
WB
BL
WL
BU
322.50
0.88
0.00
0.00
0.00
0.00
0.00
0.00
0.00
0.00
323.38
CL
12.06
28791.50
614.69
3.31
0.00
8.38
69.88
64.56
2.88
0.63
29567.88
FL
10.88
615.25
3337.19
0.31
0.00
2.13
2.94
77.88
27.25
0.31
4074.13
PL
0.00
8.31
1.88
338.13
0.00
0.00
5.69
0.25
0.00
0.00
354.25 6982.81
DBF
0.00
0.81
0.00
0.00
6550.63
419.56
8.88
0.00
2.94
0.00
MF
3.38
7.56
1.69
0.00
51.38
4864.50
32.75
0.00
24.75
0.06
4986.06
SL
0.31
66.81
38.13
0.00
25.69
25.50
5404.38
12.69
19.00
0.00
5592.50
WB
1.38
16.38
5.38
0.06
0.00
1.38
1.19
2121.94
0.00
0.00
2147.69
BL
0.00
4.50
0.00
0.00
0.00
0.44
123.38
0.00
679.75
1.44
809.50 139.69
WL Total
0.00
0.06
0.00
0.00
0.00
0.00
0.00
0.00
0.00
139.63
350.50
29512.06
3998.94
341.81
6627.69
5321.88
5649.06
2277.31
756.56
142.06
2005 BU 1985
Total CL
FL
PL
DBF
MF
SL
WB
BL
WL
BU
322.44
0.38
0.19
0.00
0.00
0.13
0.19
0.06
0.00
0.00
323.38
CL
25.38
28328.44
610.19
15.75
33.50
66.50
161.38
279.75
41.94
5.06
29567.88 4074.13
FL
11.31
293.00
3609.19
8.00
8.31
4.13
26.19
83.06
29.38
1.56
PL
0.00
3.00
7.75
340.88
0.00
0.44
0.25
0.88
0.50
0.56
354.25
DBF
0.00
25.69
15.31
13.88
6575.06
290.31
33.94
26.44
2.19
0.00
6982.81
MF SL
3.38 1.19
49.63 118.69
27.06 41.81
5.31 3.81
165.63 16.50
4622.94 39.06
88.31 5309.25
2.38 35.19
21.38 26.50
0.06 0.50
4986.06 5592.50 2147.69
WB
3.44
202.94
40.88
5.00
13.50
21.75
35.81
1814.75
5.25
4.38
BL
1.31
6.63
23.25
0.00
0.00
1.88
16.13
1.00
757.88
1.44
809.50
WL
0.00
3.94
0.94
0.00
0.00
1.00
1.06
0.00
0.06
132.69
139.69
368.44
29032.31
4376.56
392.63
6812.50
5048.13
5672.50
2243.50
885.06
146.25
Total
The diagonal values are shown in bold, indicating the area which has remained unchanged between two time periods for respective LULC class BU built-up, CL crop land, FL fallow land, PL plantation, DBF deciduous broad leaf forest, MF mixed forest, SL shrub land, WB water body, BL barren land, WL waste land
value of estimated runoff potential is 210.21 mm in year 1985, 209.87 mm in 1995 and 201.42 mm in 2005. Similarly, the components, i.e. ET and baseflow, were also analysed as given in Fig. 6.
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A very little variation in each of the water balance component estimates was observed. This null effect of considerable LULC change on hydrology of the basin was further analysed. The reason can be attributed to the fact
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Fig. 4 LULC change map of the basin, location of major changes in LULC highlighted in red boxes
Table 2 VIC calibration parameters, their range and calibrated value Parameter
Value range
Calibrated value
bi
0–0.4
0.2
Ds
0–1
0.1
Dsmax
0–30
It has been assigned to each grid based on the soil texture class, saturated hydraulic conductivity and slope
Ws
0–1
0.9
that a very large basin has been simulated to study impact of LULC change. The spatial LULC change map, as shown in Fig. 4, was further analysed with respect to impact of particular change on hydrology, in general. The spatial area calculation has been done with regard to LULC change which might induce reduction or increase in runoff, as shown in Fig. 7. It was noticed that the area under LULC change that induces increase in runoff is around 1150 km2, whereas the area under LULC changes that induce reduction in runoff is about 1087 km2. It is evident from this
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Fig. 5 Comparison of long-term mean observed and estimated discharge at basin outlet near Nellore, Andhra Pradesh Fig. 6 Plot of estimated basin average water balance components: runoff potential, baseflow and ET against rainfall
analysis that the area forcing increase and decrease in runoff generation is more or less similar. Therefore, the changes in LULC, which might result in generation of more runoff and changes which further may reduce the runoff production, get nullified over this large basin. It is to be noted that the same will be the case for other hydrological components, as the hydrological components depend on each other. For example, if built-up increases, runoff increases, whereas ET and baseflow decreases. On the contrary, if vegetation (forest/crop land) increases, ET and baseflow may increase with the decrease in runoff. However, the model used in the present study solves water
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balance for each grid; the change in any hydrological parameter will have effect on the other. This study provided an impetus to study spatial variation in these water balance components with regard to LULC change. In this part of analysis, initially, a climatic normal of each water balance component, i.e. runoff, ET and baseflow, was derived by taking long-term (1951–1984) 34-year spatial mean of these components. The climatic normal of each water balance component is provided in Fig. 8. It was observed that the variation of runoff is from 0 to 364.3 mm, ET varies from 0 to 945 mm, and baseflow varies from 0 to 186 mm.
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Fig. 7 Impact of LULC change on runoff generation
Later, each of these parameters under each LULC change scenario (1985/1995/2005) was analysed for meteorological forcing of year 1995, as the annual basin average rainfall in year 1995 is very close to long-term basin average rainfall of 825 mm. The difference or anomaly maps between long-term annual average and the annual sum of the particular year (with regard to forcing of year 1995) of each parameter were analysed. The difference maps of each parameter for each year under consideration are shown in Fig. 9. These maps depict that large spatial region is subjected to hydrological changes due to LULC change. The changes (increase or decrease) in each component have been observed for all the years under consideration
with regard to climatic normal. However, it was noticed that there is a very nominal change in hydrology of the basin between years 1985 and 1995 as there is very less variation in the LULC during this period. The runoff potential in some parts of the basin has increased maximum by around 48 mm and decreased by maximum around 173 mm during 1985 and 1995 with respect to climatic normal runoff. The effect of LULC change on runoff is predominant in the year 2005, where runoff potential has increased by 88 mm and decreased by 265 mm. However, the ET component has increased maximum by around 400 mm and decreased by 570 mm under each LULC scenario. Similarly, the baseflow is showing variation of 70-mm increase and 100-mm decrease throughout the
Fig. 8 Long-term climatic normal of basin runoff, ET and baseflow
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Fig. 9 Spatial variation of basin average water balance components and their anomaly for respective years a basin annual runoff and runoff anomaly for each year under consideration, b basin annual ET
and ET anomaly for each year under consideration, c basin annual baseflow and baseflow anomaly for each year under consideration
analysis. The upper Pennar Basin is showing increasing trend in all the water balance components; however, the lower basin is showing decrease in these components. The grids with maximum increase and decrease in water balance components were analysed further for better
understanding. The location of these selected grids was marked on LULC change map (refer Fig. 4), and the corresponding change in LULC of these grids was analysed as presented in Table 3.
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Fig. 9 continued
In the grids 2164, 469 and 1477; where, the increase in built-up and subsequent decrease in cropland/forest was observed, the general trend of runoff increase was noticed. This may be attributed due to slight increase in impervious area and reduction in vegetative surface. The baseflow showed an increasing trend as with the increase in built-up and subsequent decrease in vegetative surface, the transpiration through plants’ root reduced. However, the grid 1477 in year 1995 showed a slight decrease in runoff. It might be due to the reason that more area covered under water body in this particular grid, which may be retaining water to flow out. The decrease in runoff and increase in ET was observed, in the grids (Grid No. 1678, the year 2005), where, cropland/forest has decreased and water body area has increased. However, in such cases, generally, ET must reduce, but in the present analysis, slight increase in ET was observed. The reason could be the prevalence of large number of shallow fish ponds and storage tanks constructed in this coastal region of India, contributing more to evaporation. Similarly, baseflow was also showing slight increase, as the increase in water body would keep its surrounding saturated, so the lowest soil layer would remain saturated and contribute more to baseflow. In the grid 723, a large increase in cropland has been observed, which forced to reduce runoff generation, whereas the grid 1428 was showing shifting of deciduous forest to mixed forest, which showed general trend of increase in runoff. Similarly, the grid 1292 was also showing increase in runoff with the change of cropland to
fallow land. This might have attributed due to decrease in LAI and reduced transpiration from less vegetated surface. Based on these observations, it can be concluded that slight change in LULC can change hydrological regime of a basin entirely.
Summary and conclusions In the present study, the Pennar Basin has been simulated using VIC hydrological model for assessing the impact of LULC change on its hydrological regime successfully. Initially, the change in LULC between years 1985, 1995 and 2005 has been assessed. It was observed that almost all LULC classes show significant changes during these periods. Maximum increase in built-up LULC class has been observed, and maximum decline in deciduous forest class was observed. Later, the impact of these changes in LULC on water balance components of Pennar Basin was studied. In the present analysis, the VIC soil–vegetation–atmosphere transfer scheme has been investigated for Indian condition. Firstly, the model was simulated for meteorological forcing of period 1951–1984. The simulated model was then calibrated against the available average monthly discharge data for period 1965–1979 at GRDC site of Nellore outlet. The well-calibrated model was later utilized to study impact of LULC on hydrology of Pennar Basin. In order to study LULC change impact, the meteorological forcing (period 1980–2010) was kept constant for all three
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Table 3 Change in LULC and corresponding change in water balance components Location
Fraction LULC Class Area
Runoff (mm)
1985
1995
2005
Grid no: 1678
CL: 0.53
CL: 0.53
CL: 0.0975
Lat: 14.525
SL: 0.355
SL: 0.355
SL: 0.355
Long: 79.075
WB: 0.115
WB: 0.115
WB: 0.5475
Grid no: 723
CL: 0.3575
CL: 0.975
CL: 0.975
Lat: 15.275
FL: 0.635
WB: 0.025
WB: 0.025
Long: 78.575
WB: 0.0075
Grid no: 1428 Lat: 79.175
CL: 0.0275 DBF: 0.955
CL: 0.0275 DBF: 0.545
CL: 0.0275 DBF: 0.545
Long: 14.725
SL: 0.0125
MF: 0.41
MF: 0.4075
WB: 0.005
SL: 0.0125
SL: 0.015
WB: 0.005
WB: 0.005
Grid no: 2164
CL: 0.805
BU: 0.0525
BU: 0.0925
Lat: 14.125
DBF: 0.0175
CL: 0.7525
CL: 0.7125
Long: 78.175
BL: 0.1775
MF: 0.0175
MF: 0.0175
SL: 0.075
BL: 0.1775
1995
ET (mm)
2005
1995
Baseflow (mm) 2005
1995
2005
0
-56.72
0
205.15
0
28.41
-1.26
-1.26
-5.54
-5.54
-0.04
0.38
1.91
1.67
22.47
23.09
0
0.59
0.21
10.31
-0.43
-30.16
0.22
0.25
-1.47
-1.64
0.5
2.02
-0.59
0.079
0
-0.212
31.58
27.12
BL: 0.1025 Grid no: 469
BU: 0.29
BU: 0.405
BU: 0.4175
Lat: 15.475
CL: 0.6875
CL: 0.5725
CL: 0.56
Long: 78.475
WB: 0.0225
WB: 0.0225
WB: 0.0225
Grid no: 1477
BU: 0.05
BU: 0.1525
BU: 0.17
Lat: 14.675
CL: 0.8375
CL: 0.7
CL: 0.505
Long: 78.475
FL: 0.0325 MF: 0.015
FL: 0.0525 MF: 0.0075
FL: 0.26 MF: 0.0075
WB: 0.065
WB: 0.0875
WB: 0.0575
Grid no: 1292
CL: 0.875
CL: 0.875
CL: 0.2125
Lat: 14.825
PL: 0.0225
PL: 0.225
FL: 0.67
Long: 78.675
SL: 0.0425
SL: 0.0425
PL: 0.0225
WB: 0.0375
WB: 0.0375
SL: 0.0425
BL: 0.0225
BL: 0.0225
WB: 0.03
-1.82
0
0
-0.038
0
1.103
-1.478
0.09
BL: 0.0225
simulations with vegetation parameters correspond to LULC of years 1985, 1995 and 2005. It was noticed that when water balance components were lumped over this large basin, a marginal change in hydrology of the basin was observed. Further, to verify the same, the LULC change map was analysed for changes that would induce runoff increase and changes those would reduce the same. It was observed that the area under each of these categories was almost the same, which would have hugely minimized the effect of LULC change on this large basin water balance components at basin scale to a negligible stage. Further attempts were made to analyse results with respect to impact of LULC change on spatial scale. The model was run for meteorological forcing of period 1951–1984 (34 yrs), and the climatic normal of each
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parameter, i.e. runoff potential, ET and baseflow, was generated by averaging all the grids for this period. Later, the annual total of basin average of each of these parameters from the analysis of meteorological forcing (period 1980–2010) for year 1995 only was generated for each year under consideration, i.e. 1985, 1995 and 2005. Then, difference or anomaly maps were generated by subtracting average annual of each parameter from respective longterm climatic normal. It was observed that large area of the basin was unchanged with regard to hydrology. However, wherever, the changes in LULC over the period 1985–2005 were significant and the considerable change in basin’s water balance was observed. The grids where forest cover or crop land has declined, and the runoff has increased significantly. However, the regions of urban sprawl were
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showing general trend of increase in runoff potential and subsequent decrease in ET. The runoff has increased because impervious area has increased with the decrease in vegetative surface. The decline in vegetated surface further reduces transpiration, which has been depicted by decrease in overall ET. In this coastal region of India, large fish ponds and tanks were constructed; those are retaining water and contributing more to evaporation. The retention of water made soil to remain saturated; hence, increase in baseflow was observed in such cases. Therefore, it may be concluded that slight change in LULC influences the hydrological regime of river basin in larger way, but needs to be studied at finer spatial scale. Such studies may prove to be very important for decision-makers who require such information to evaluate mitigation and adaptation strategies under changing LULC scenarios. Further, it can support policy makers to allocate water judiciously among each sector: agriculture, ecosystems, domestic and industry. In the present study, the sensitivity of the Pennar hydrological system with respect to change in land cover has been studied over long time (decadal) frames. Moreover, climatic factors were kept constant to study the impact of LULC change over a large analysis period, this does not reflect reality, as simultaneously, climate might have also changed during the period of consideration. The nonconsideration of dynamics (in both land surface and climate) between such a long time duration may be one of the limitations of the present analysis. It is also to be noted that each region will behave differently with respect to LULC and climate change. Therefore, each of the regions needs to be studied separately, taking into account plausible LULC within a climate change context projecting the behaviour of the region in the future research. Acknowledgements The authors would like to thank the authorities of Indian Space Research Organisation for providing financial grant for this research work. The work has been done under the ISRO-GBP Project on ‘‘Land Use Land Cover dynamics and impact of Human Dimension in Indian river basins’’. The authors thank IMD for providing daily gridded data on rainfall and temperature and the VIC hydrological model team for their help during the course of the study. Thanks are due to LULC team for their efforts in generating LULC map for entire India and for providing the data for this particular basin. Authors would like to extend their gratitude to Ms. Asfa Siddiqui for reviewing the manuscript and correcting it for the language.
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