It is increasingly recognized that the land-use change, especially urbanization has influenced hydrological attributes intensely. Flood characteristics variation could likewise increase flood risks and pose higher demand on water management. The paper aims to evaluate temporal and spatial processes of urbanization affecting flood events at catchment level. The study sites were Xiaoqinhe catchment and its sub-catchments, a part of lower Yellow river basin in northern China. Historic cities Jinan and Zibo in the area have experienced dramatic urban expansion in recent decades, about 5 % growth of urban build-up area annually from 1990s to 2010s, and also pressed alarm for increasing flood disasters. In the paper, a HEC-HMS model was set up to simulate flood processes for different land-use scenarios. The possible effects of urbanization on flood characteristics were checked in study catchment and its sub-catchments.
Urbanization levels reflect the degree of economic development of a region, but it also changes water cycle in many aspects. Urbanizing is a major land use/cover (LUCC) change trend for most regions of China in recent decades. It modifies hydrological process by affecting runoff generation and concentration which has been research focus currently (Amini et al., 2011; Delgado et al., 2009; O'Donnell et al., 2011; Wu et al., 2007).
Hydrological model supported by remote sensing technology and GIS has been widely applied in LUCC related studies. Under urban land enlargement scenario and identical precipitation, simulation of runoff variation can be analysed. Parameters in the model can be flexibly adjusted to reveal the mechanism of LUCC on runoff processes. Bronstert et al. (2007) stated that urban and farming changes decided the runoff responses based on simulation test of varied land cover conditions. Many researches (Arnold and Gibbons, 1996; White and Greer, 2006) concluded that storm runoff and peak flow increase with urban development as the proportion of impervious land increase. According to Warburtan et al. (2012) and Sanyal et al. (2014), spatial inhomogeneity of land use change makes local runoff responses present a more complex pattern. Fox et al. (2012) suggested channel management in urban areas has a counterbalance to reduce the runoff. Naef et al. (2002) studied the potential to reduce storm runoff by adjusting land uses in a mesoscale watershed.
China is in the process of rapid urbanization (Xu et al., 2010). A better understanding of land use change on hydrological responses is important for panning, management and sustainable development of the watershed. The objective of this study was to analyse the impacts of urbanization on flood characteristics in Xiaoqing catchment where undergoing intensive urban expansion during 1995–2008.
Location and DEM of the study catchment.
The sub-humid Xiaoqing catchment is located at the eastern end of the Yellow
River basin in the province of Shandong, China, draining an area of
5451 km
The study area contains two megapolis of Jinan and Zibo, along with their satellite cities of Zhangqiu, Zouping and Huantai. These cities experienced rapid development and population expansion during 1990–2010. The mainstream in the area, Xiaoqing River, plays an important role in flood routing during storm events as it accepting flood flows from parallel upstream branches. It is also a key channel in South-North Water Transfer Project. After two severe floods in 1996 and 2007, the government has increased capital investment in flood control projects. The Xiaoqing catchment implemented a series of measures as channel regulation, reservoir maintenance and flood detention preserving. Along the south side of Xiaoqing River, many lakes and ponds were reconstructed as detention basins. In November 1996, the upper reaches of the Xiaoqing River were widened from 35 to 60 m in rectangular section, and the river reaches near Chahe station were widened from 50 to 80 m in trapezoid section. The river section was expanded to 70–100 m in general after 2007.
Sub-basins and rain gauge stations in the Xiaoqing catchment.
The Hydrologic Engineering Center's Hydrologic Modelling System (HEC-HMS) was chosen for simulating the rainfall-runoff process. It is a semi-distributed, event based model, which dividing the catchment into sub-basins, computing runoff response in each sub-basin, and routing the river flow to the outlet.
SCS curve number (CN) method was adopted to calculate rainfall-runoff process. Empirical parameter CN can be easily accessed with land use data and soil classes, and amended by antecedent moisture conditions of soil. CN value could reflect the impact of land cover change on the runoff yield. Evapotranspiration losses were considered to be negligible in the storm event. The overland flow was simulated with Snyder Unit Hydrograph method. Channel flow was calculated with Muskingum routing method, and baseflow was determined by the exponential recession method. Detailed description of algorithms and parameters of the HEC-HMS model can be found in the HEC-HMS Technical Manual (USACE, 2000).
Summary of model calibration and validation results for rainstorm events in Xiaoqing catchment.
DEM of 30 m resolution was processed and used to generate stream network and define sub-basins. Because of human activities, extracted channels had a slight deviation with real ones which has been corrected artificially. The study catchment was divided into 49 sub-basins based on the spatial distribution of terrain, land cover, soil and rainfall gauge stations (Fig. 2). Hydrologic and terrain parameters were derived and calculated as model input. Soil types were converted into the hydrologic soil groups for the catchment. There are 45 rain gauge stations throughout the catchment, while the precipitation in each sub-basin was estimated by inverse distance interpolation method. Precipitation data of rainfall events were recorded in 1 h time interval, the model simulations were also operated on 1 h step accordingly.
Analysing the urbanization development rates of the study area in different years, urban and residential areas gradually accelerated in the 1990s but appeared dramatically spreading over after year 2000. Besides, taking the integrity of aerial photographs and impact of cloud into account, two series of land cover data, i.e. 1995 and 2008, were selected and digitalized into 30 m resolution (Fig. 3). Since the study area is covered by two images, the colour difference of remote sensing images in different time phase may induce errors during interpreting process. So we interpreted images separately, and then mosaicking two vector graphs to generate land use maps for the study area. Based on the Chinese land resource classification system and regional land cover characteristics, the land use types in the Xiaoqing catchment was divided into build-up land, forest, farmland, grassland and waterbody.
Land cover maps of the study catchment in
The HEC-HMS model was calibrated by two rain events and validated by one
rain event for each given land use scenario. Because the hydrologic data set
between 1985 and 2000 is not open and inaccessible, the dataset in early
1980s was used to verify the model under 1995 land use scenario. Examining
images from 1980 to 1995, the land use changed slightly, so it is considered
to be reasonable. Three evaluation indexes were calculated to assess the
model performance (Table 1) including the Nash–Sutcliffe coefficient of
efficiency (
Results of calibration and validation showed that the simulated flow compared well with observed values. The calibrated models were validated for flow prediction in the Xiaoqing catchment.
Percentage cover of different Land use for 1995 and 2008.
In Fig. 3, the land use change was remarkable in Xiaoqing catchment during the period 1995–2008 (Fig. 3), especially in the central catchment, urban and residential area having a leap mainly due to burgeoning expansion of Zibo, Zhangqiu and Zouping. Land use change pattern reflects social and economic structure transform in the study catchment, and this changing pattern is typical in other regions of China from 1990s to 2010s. Table 2 listed land use coverage percent for 1995 and 2008 land cover scenarios. Build-up area increased substantially from 19.1 % in 1995 to 40.5 % in 2008. Meanwhile forest and waterbody areas enhanced by 7.0 and 0.4 percentage points respectively. That said, urbanization not only increases impervious area also makes decision makers pay more attention on flood control measures in the catchment which is beneficial to improve water storage capacity and flow drainage capacity. Correspondingly, farmland and grassland areas declined a lot, their coverages falling from 43.3 and 28.0 % in 1995 to 27.8 and 14.6 % in 2008.
Rainfall event in 3 August 2006 was selected to analyse the effect of
LUCC on runoff response in the Xiaoqing catchment. The average precipitation
of the event is 55 mm. Rainstorm centre located in the northern and western
part of the basin, and the maximum rainfall is up to 103 mm. Runoff
responses to the storm event were simulated under 1995 and 2008 land covers
(Fig. 4). The peak discharge was 130 m
Simulated discharge hydrographs under 1995 and 2008 land cover for storm event No. 060803.
Development of urbanization is heterogeneous over the whole catchment. Other
factors or land use changes could counterbalance the consequences of
impervious area increasing. Scale effect is another critical factor because
impact of LUCC on flow may decrease with size of study area (Blöschl et
al., 2007). Therefore, it is necessary to examine influences of land cover
change on streamflow at sub-basin scale. Figure 5 showed spatial distribution
of urbanization developing degree and simulated runoff depth change rate in
each sub-basin. Equations and variable meanings in Fig. 5 are as follows.
Percentage change of
As illustrated by Fig. 5, 72 % of the watershed area experiencing more
than 5 % of build-up area percentage increase. There are 38 and 8 %
area mainly located in central and southeast watershed which have more than
15 and 25 % of build-up area percentage increase. Distribution of
runoff depth change rate showed higher spatial variability. In Fig. 5b,
negative values indicate that the
This study adopted an event-based hydrological model (HEC-HMS) to investigate the impacts of land use change on runoff responses in Xiaoqing catchment. The study area went through rapid urbanizing expansion between 1995 and 2008. Meanwhile, city expansion also promoted flood proof activities as channel widening, detention basin construction and reservoir maintenance. The overall results of these changes on runoff were increased peak discharge and flood volume but lagged peak time at the catchment outlet. The relationship between urban development and hydrologic responses are complex at sub-basin scale. In general, more runoff was generated in the area with higher increase rate of build-up area, but increase magnitude of runoff did not present as simple linear relationship with the urban area expansion rate. Some sub-basins also showed opposite effect of urbanization on runoff. The findings in the paper provide useful information on effect of urbanization on flood characteristics and be helpful for decision makers to scientifically develop land use planning in the study catchment.
This study has been supported in part by the Natural Science Foundation of China (Grant No. 51209071, 51109137 and 51309078). Authors would like to thank S. Lin and K. Long for hydrologic data checking. Constructive comments by reviewer helped to improve the manuscript.