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Attribution identification of terrestrial ecosystem evolution in the Yellow River Basin

  • Jun Hou , Jianwei Wang , Tianling Qin EMAIL logo , Shanshan Liu , Xin Zhang , Sheng Yan , Chenhao Li und Jianming Feng
Veröffentlicht/Copyright: 28. Juni 2022
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Abstract

The aim of this study was to identify the impacts of different driving factors on terrestrial ecosystem evolution. The Yellow River Basin was selected as the study area, of which terrestrial ecosystem was deeply affected by climatic change and human activities. We constructed four scenarios (including without any impacts, affected by climate change, by human activities and by both impacts), and the discrepancies between them reflected the impacts of climate change or human activities. Based on this, the future land use simulation model was used to simulate the land use distribution under the four scenarios, and then, the ecosystem services values (ESV) and landscape patterns index were evaluated. The results indicated that affected by climate change during 1995–2015, the Mean Patch Area of the forestland decreased by 0.19% and the landscape patterns became fragmented. Meanwhile, the total ESV decreased by 0.03 billion dollars and the ecosystem regulation services were weakened. Under the influences of human activities, the Contagion index decreased by 1.71% and the landscape patterns became dispersed. Simultaneously, the total ESV increased by 0.56 billion dollars, but the function tends to be unitary. In addition, these effects showed great spatial heterogeneity. This study provides scientific support for ecological protection in the Yellow River Basin.

Keywords: climate change; human activities; ecosystem services values; landscape patterns; future land use simulation model

1 Introduction

Under the dual effects of climate change and human activities, the composition and structure of ecosystem have been undergone tremendous changes [1,2], which exerted profound impacts on landscape patterns and ecosystem services function [3,4,5]. Observed climatic warming has led to changes in the spatial–temporal of precipitation and frequent occurrence of extreme events [6]. All of these changes have altered the potential evapotranspiration and the soil hydrothermal properties, promoted or restrained the growth of vegetation and affected the vegetation ecosystem further [7,8]. In addition, with the accretion of population and rapid economic development, the impacts of anthropogenic activities on the ecosystem have intensified. The vegetation coverage has been increased by forest planting and hill closing afforestation, and the vegetation ecosystem services have been improved [9,10], but the urbanization expansion and unreasonable farming have been destroyed the ecosystem and weakened the ecosystem services function [11,12]. Under the background of intensified global warming and man-made activities, it has guiding significance to quantify the impacts of distinct driving mechanisms on landscape patterns and ecosystem services function for regional ecological construction and sustainable development.

The development of remote sensing technology made it possible to study the effects of climate change and human activities on terrestrial ecosystem [13,14,15]. Scholars have conducted extensive studies, which mainly focused on the correlation analysis based on historical meteorological data and vegetation coverage data [16], analyzing the effects of human activities on ecosystem services [17], as well as quantifying the contribution of multiple driving factors [18]. Climate change was closely related to vegetation ecosystem; Zheng et al. analyzed the relationship between the net primary production (NPP) and normalized difference vegetation index (NDVI) and found that climate change contributed 57.65% to the grassland NDVI in the Loess Plateau [19], but studies have shown that the impacts of climate change on vegetation ecosystem presented great regional difference, which was related to regional altitude, precipitation and vegetation types [20]. The temperature rising led to increased vegetation cover in the middle and high latitudes of the Northern Hemisphere, which improved the ecological service function [21,22]. While in some arid areas, increased potential evapotranspiration and soil water shortage caused by temperature rising has resulted in the decreasing of vegetation coverage and then impaired the landscape patterns [23,24]. Extreme events, such as severe droughts and heavy rains, may augment the mortality of trees and reduce the forest ecosystem services [25,26]. The impacts of human activities on ecosystems were dramatic. Wang et al. observed that the urbanization expansion in Dongying City led to the ecosystem services values (ESV) was decreased by 16.1% based on the historical land use data in 1995–2015, and this trend was expected to continue for a long time in the future [27]. Similar problems have also arisen in other regions, such as the Pearl River Delta [28] and the Yangtze River Delta [29]. Liu et al. wrote that the vegetation restoration projects in the agro-pastoral ecotone of northern China in the past 20 years significantly improved ecosystem services based on the NPP and scenarios simulation, which resulted in a net increase of ESV by 8.18 billion dollars [30]. However, some scholars proposed that the projects of vegetation restoration in the Loess Plateau have also brought about some ecological problems, such as the singularization of ecological service function and the attenuation of landscape diversity [31,32]. In recent years, the effects of multiple driving factors on the ecosystem were carried out [33,34]. Ling et al. selected remote sensing data, including vegetation cover, human disturbance index and temperature vegetation drought index, and pointed out that the contributions of these three driving factors to the total ESV in Manas River Basin were 38, 31.6 and 30.4%, respectively [35]. Wang et al. noted that the ecosystem services function in Shaanxi province showed an increasing trend from 2000 to 2013 based on different spatial models, and human activities contributed the most to the restoration of vegetation ecosystem (45.8%), followed by climate factors (38.0%) and climate and human factors (16.2%) [36]. However, few studies have considered the following two scientific issues: (1) how to identify the driving mechanism of climate change and human activities on terrestrial ecosystem and (2) how to quantify the contribution of different driving factors.

The Yellow River Basin was a fundamental ecological security barrier in China, as well as a central area of population activities and economic development, which shouldered a pivotal strategic position in the national development and socialist modernization [37]. In recent years, climate change, vegetation restoration projects and urbanization have had huge impacts on watershed ecosystem [31]. The objective of this article is to conduct the attribution identification of terrestrial ecosystem evolution in the Yellow River Basin, which is based on the quantitative analysis of the impacts of climate change and human activities on landscape patterns and ecosystem services function.

2 Data and methods

2.1 Study area

The Yellow River basin (95°53′–119°05′E, 32°10′–41°50′N) is the second largest river in China, occupying approximately 795,000 km2, which accounts for about 8.3% of China’s continent area (Figure 1). The watershed is located between northwest arid zones and southeast humid zones, most of the areas belong to arid and semi-arid continental monsoon climate. The average annual temperature is 6.74°C, with the characteristics of increasing from west to east and decreasing from north to south. The average annual precipitation is 487 mm, mainly concentrated in June to September and exhibited a decreasing trend from southeast to northwest. The Yellow River Basin covers 9 provinces (autonomous regions) of China, including more than 66 cities and 340 counties, with a total population of 116 million and a population density of 147 people/km2. The terrain is high in the west and low in the east, with a highest elevation of 6,212 m and a minimum of −8 m. The basin is divided into three parts, the Plateau Glaciers in the upper reaches, the Loess Plateau in the middle reaches and the Yellow River Delta in the lower reaches.

Figure 1 Location, elevation, main cities, basin boundary and its different sections (upstream, midstream and downstream) of the Yellow River Basin.
Figure 1

Location, elevation, main cities, basin boundary and its different sections (upstream, midstream and downstream) of the Yellow River Basin.

2.2 Data

The data used in this article include the historical land use data, the historical meteorological data, digital elevation model (DEM) data, the socioeconomic data, the roads data and the statistics data of the Yellow River Basin (Table 1).

Table 1

The data category, year, source and description used in this study

Category Data Year Data source Description
Land use Land use 1995/2015 Resources and Environmental Sciences and Data Center (https://www.resdc.cn/) With a resolution of 1 km
Meteorological Temperature 1980–2015 Resources and Environmental Sciences and Data Center (https://www.resdc.cn/) With a resolution of 1 km
Precipitation
Socioeconomic GDP 2015 Resources and Environmental Sciences and Data Center (https://www.resdc.cn/) With a resolution of 1 km
Population
Terrain data DEM 2000 Geospatial Data cloud (http://www.gscloud.cn/) With a resolution of 1 km
Slope Generated from DEM data
Aspect
Roads data Road Open Street Map (https://www.openstreetmap.org/) Convert from the shp file, with a resolution of 1 km
Statistics Grain yield 2000–2015 Statistical yearbook sharing platform (https://www.yearbookchina.com/) Average grain yield and average grain price
Grain price

2.3 Methods

The research workflow includes data preparation, scenarios setting, land use simulation, index calculation and attribution identification (Figure 2). First, based on the historical meteorological data and land use data, the Mann–Kendall test and land use transfer matrix were used to detect the influence of climate change and human activities. Then, the scenarios of without any impacts (Scenarios 1), affected by climate change (Scenarios 2), by human activities (Scenarios 3) and by both impacts (Scenarios 4) were constructed. Second, the future land use simulation (FLUS) model was calibrated and verified, which was used to simulate the land use distribution in 2015 under the four scenarios. Third, the landscape patterns index and the ESV were calculated. Finally, according to the discrepancies of evaluation results between the scenarios, the impacts of climate change and human activities on terrestrial ecosystem were quantitatively evaluated.

  1. Mutation detection

    The Mann–Kendall test is a nonparametric test method, which is widely used to detect the long-term change trend and mutation point of the precipitation and temperature [38,39]. The formulas were as follows:

    S k = i = 0 k r i ,

    r i = + 1 , x i > 0 , 0 , x i x j ,

    UF k = ( S k E ( S k ) ) Var ( S k ) ,

    where k = 1, 2, …, n; E ( S k ) = k ( k + 1 ) / 4 , Var ( S k ) = k ( k + 1 ) ( 2 k + 5 ) / 72 . UF k was the statistical series calculated by the time series, and all the values would form a curve; then, the sequence was arranged in reverse order and repeated the above calculation process to get UB k . The significance level in this article was 0.05, and the critical value UF 0.05 = ± 1.96 . When the curve of UF and UB intersected at a certain point, which called the mutation point.

    According to the annual precipitation and temperature data of the Yellow River Basin from 1981 to 2015, we found that the average annual precipitation showed a decreasing trend with a decreasing rate of −2.1 mm/10a, but the change trend showed no significance (p > 0.05). While the average annual temperature showed a significant increasing trend (p < 0.05) with a rising rate of 0.4°C/10a. Since the temperature change was significant, and which would affect the frequency and intensity of precipitation [40], the temperature numerical data were used to detect the mutation point of climate change, and the mutation year appeared in 1994. Based on this, we divided the baseline period climate (1981–1994) and the variation period climate (1995–2015).

  2. Scenarios setting

    We used the Arcgis 10.2 software to calculate the land use transfer matrix of the Yellow River Basin from 1995 to 2015. The changes in forestland, grassland, water bodies and other areas were mainly related to cultivated land and construction land. If the conversion of cultivated land and construction land to other land use types was prohibited, the changes of forestland, grassland, water area and unutilized land affected by human activities will be very small [41]. Therefore, the impacts of human activities were determined by whether the cultivated land and construction land changed in land use conversion. If the impacts of human activities were absence, the cultivated land and construction land were consistent with that in 1995. On the contrary, the conversion of cultivated land and construction land with other land use types was permitted.

    In the light of whether the land use types were affected by climate change and human activities, four scenarios were constructed, including without any impacts (Scenario 1), affected by climate change (Scenario 2), by human activities (Scenario 3) and by both impacts (Scenario 4). Where the discrepancies between Scenario 1 and Scenario 2 reflected the impacts of climate change, the discrepancies between Scenario 1 and Scenario 3 reflected the impacts of human activities and the discrepancies between Scenario 1 and Scenario 4 reflected the combined impacts of climate change and human activities.

  3. The FLUS model simulation and validation

    In this article, the FLUS model was used to simulate and predict the land use distribution (Figure 3), which was an integrated model for multi-type land use scenario simulation by coupling anthropogenic and nature effects [42,43]. First, the system dynamics model was used to predicted the land use demand under various climatic and socioeconomical driving factors. Then, the artificial neural network was used to calculate the adaptability probability, which aimed to obtain the sinuous relationships between land use types and various human and nonhuman driving factors. In addition, the model adopted an adaptive inertia competition mechanism based on roulette wheel selection method, which dealt with the uncertainty and complexity of land use conversion effectively, and made the FLUS model with a high simulation accuracy [44,45,46].

    Based on the land use data in 1995, we selected natural factors (such as DEM, slope and aspect), social and economic factors (such as population density and GDP), meteorological factors (such as temperature and precipitation) and other driving factors to calculate the adaptability probability of the land use types (Figure 3) and then simulated land use distribution in 2015. The actual data of 2015 were used to verify the simulation results. The Kappa coefficient was 0.85, which indicated that the FLUS model could better simulate the spatial distribution of the land use in the Yellow River Basin. In the next work, we simulated and predicted the land use distribution under the four scenarios by adjusting the input driving force and parameters of the model.

  4. Landscape patterns

    According to the landscape patterns features and the practical principle in the study area, the watershed ecological landscape patterns indices were analyzed from the type level and landscape level. Where the type level includes the number of patches (NP), the edge density (ED), the landscape shape index (LSI) and the mean patch area (AREA_MN), the landscape level comprises the ED, the LSI, the Contagion (CONTAG) and the Shannon’s diversity index (SHDI). The value of each landscape indices was calculated by Fragstats 4.2 software, and the ecological significance and calculation method of each index were detailed in the references [47,48].

  5. ESV

    The equivalent coefficient method was the most representative method to quantitatively evaluate the ecosystem services functions. In this article, the ecosystem services types and the equivalent coefficient were determined based on the research results of Costanza et al. and Xie et al. [49,50]. Combined with the value calculation method of the equivalent coefficients proposed by Xie et al. [51], we obtained the ESV per unit area of different land use types in the Yellow River Basin (Table 2).

Figure 2 The research workflow of the attribution identification of terrestrial ecosystem evolution.
Figure 2

The research workflow of the attribution identification of terrestrial ecosystem evolution.

Figure 3 The framework of FLUS model and the process of land use simulation.
Figure 3

The framework of FLUS model and the process of land use simulation.

Table 2

The provisioning, regulating, supporting and cultural services value per unit area for different land use types (dollars/hm2)

Primary classification Secondary classification Farmland Forestland Grassland Water bodies Unutilized land
Provisioning services Food supply 219.06 79.89 56.70 206.17 0.00
Raw material supply 103.08 182.98 85.05 59.27 0.00
Water 5.15 95.35 46.39 2136.44 0.00
Regulating services Air quality regulation 172.67 605.62 293.79 198.44 5.15
Climate regulation 92.78 1811.72 778.29 590.16 0.00
Waste treatment 25.77 512.85 257.71 1430.30 25.77
Regulation of water flows 69.58 904.57 569.54 26348.52 7.73
Erosion prevention 265.44 737.06 358.22 239.67 5.15
Supporting services Maintenance of soil 30.93 56.70 28.35 18.04 0.00
Fertility habitat services 33.50 530.89 327.29 657.17 5.15
Cultural services Aesthetic landscape provision 15.46 293.79 144.32 487.08 2.58

3 Results

3.1 Land use simulation of different scenarios

The land use distribution and the proportions of different land use categories in the Yellow River Basin by 2015 under the four scenarios are shown in Figure 4. Compared with scenario 1 (Figure 4a), the forestland area in scenario 2 (Figure 4b) was decreased by 0.1%, the grassland area was increased, the water bodies and unutilized land were changed slightly, which indicated that climate change led to a decrement in the forestland and an increment in the grassland. The area of water bodies and construction land in scenario 3 (Figure 4c) and scenario 4 (Figure 4d) were consistent, with an increase of 1.3 and 20.6%, while the other land use types showed diverse trends. In scenario 3, the area of cultivated land and grassland were decreased by 2.0 and 0.3%, and the area of forestland was increased by 1.2%. In scenario 4, the area of cultivated land and grassland were decreased by 1.8 and 0.3% and the area of forestland was increased by 1.1%. These differentially showed that under the dual effects of climate change and human activities, the area of cultivated land was decreased sharply, while the forestland and construction land were increased drastically. Diverse climatic conditions led to different variations in forestland, cultivated land, grassland and unutilized land.

Figure 4 Spatial distribution and the proportions of land use types in the Yellow River Basin by 2015 under different scenarios. Where (a–d) represent the land use distribution under the scenario 1, scenario 2, scenario 3 and scenario 4, respectively.
Figure 4

Spatial distribution and the proportions of land use types in the Yellow River Basin by 2015 under different scenarios. Where (a–d) represent the land use distribution under the scenario 1, scenario 2, scenario 3 and scenario 4, respectively.

3.2 Impacts of climate change and human activities on landscape patterns

  1. The impacts on the type level

    In terms of type level, the landscape pattern indices of each land use types under different scenarios are shown in Figure 5. Compared with scenario 1, the ED and LSI were changed little in scenario 2, the NP of forestland and unutilized land were increased by 0.09 and 0.77%, the AREA_MN were decreased by 0.19 and 0.76%, the NP of grassland was decreased by 0.67% and the AREA_MN was increased by 0.70%. The results showed that the fragmentation of vegetation landscape was increased due to climate change. Scenario 3 and Scenario 4 showed a similar trend, the NP and AREA_MN of cultivated land as well as construction land were changed the most, the LSI of cultivated land, water bodies and construction land were increased significantly and the ED of grassland was decreased the most. These alterations showed that the dominant species of grassland landscape was decreased, the shape of cultivated land, water bodies and construction land became more irregular and the boundary length was decreased due to human activities.

  2. The impacts on the landscape level

    At the landscape level, the landscape pattern indices of different scenarios are shown in Figure 6. Compared with scenario 1, landscape pattern indices of scenario 2 was changed slightly. Scenario 3 and Scenario 4 were displayed homologous change characteristics, in which the LSI was increased by 0.46 and 0.44%, the CONTAG was decreased by 1.71 and 1.70% and the ED and SHDI were changed slightly. The results indicated that the entirety landscape patterns in the Yellow River Basin were less affected by climate change, while the ecological function of the Yellow River Basin was impaired under the action of human activities, and the landscape patterns tended to be complicated, fragmented and dispersed.

Figure 5 The change rate of landscape patterns indices of type-level under different scenarios in the Yellow River Basin. Where FL, WL, GL, WB, CL and UL represent the farmland, woodland, grassland, water bodies, construction land and unutilized land, respectively. ΔS2–S1, ΔS3–S1 and ΔS4–S1 represent the discrepancies of scenario 1 with scenario 2, scenario 3 and scenario 4, respectively. The NP, ED, LSI and AREA_MN represent the number of patches, the edge density, the landscape shape index and the mean patch area, respectively.
Figure 5

The change rate of landscape patterns indices of type-level under different scenarios in the Yellow River Basin. Where FL, WL, GL, WB, CL and UL represent the farmland, woodland, grassland, water bodies, construction land and unutilized land, respectively. ΔS2–S1, ΔS3–S1 and ΔS4–S1 represent the discrepancies of scenario 1 with scenario 2, scenario 3 and scenario 4, respectively. The NP, ED, LSI and AREA_MN represent the number of patches, the edge density, the landscape shape index and the mean patch area, respectively.

Figure 6 The change rate of landscape patterns indices in landscape level under different scenarios in the Yellow River Basin, where ΔS2–S1, ΔS3–S1 and ΔS4–S1 represent the discrepancies of Scenario 1 with Scenario 2, Scenario 3 and Scenario 4, respectively. The ED, LSI, CONTAG and SHDI represent the the number of patches, the landscape shape index, Contagion and Shannon’s diversity index respectively.
Figure 6

The change rate of landscape patterns indices in landscape level under different scenarios in the Yellow River Basin, where ΔS2–S1, ΔS3–S1 and ΔS4–S1 represent the discrepancies of Scenario 1 with Scenario 2, Scenario 3 and Scenario 4, respectively. The ED, LSI, CONTAG and SHDI represent the the number of patches, the landscape shape index, Contagion and Shannon’s diversity index respectively.

3.3 Impacts of climate change and human activities on ESV

  1. Changes of the ESV under different scenarios

    The ESV per unit area as well as the proportions of different ecosystems under four scenarios are shown in Figure 7. The total ESV of scenario 1 (Figure 7a) was expected to be 237.87 billion dollars by 2015. Compared with scenario 1, the ESV of scenario 2 (Figure 7b) was decreased by 0.03 billion dollars, the proportion of ESV in the grassland was increased and forestland was decreased. Scenario 3 (Figure 7c) and Scenario 4 (Figure 7d) were increased by 0.56 and 0.50 billion dollars, respectively. In Scenario 3, the cultivated land and grassland were reduced by 0.43 and 0.28 billion dollars, while the forestland and water bodies were increased by 0.72 and 0.55 billion dollars. In Scenario 4, the cultivated land and grassland were decreased by 0.40 and 0.31 billion dollars, and the forestland and water bodies were increased by 0.67 and 0.55 billion dollars. These discrepancies indicated that the ESV of forestland decreased due to the impacts of climate change. Under the combined influences of climate change and human activities, the ESV of forestland and water area were increased, while the cultivated land and grassland were decreased.

  2. Changes in the values of different ecosystem services

    Figure 8 shows the changes in the values of different ecosystem services in the Yellow River Basin under four scenarios. Compared with Scenario 1, the regulating services such as erosion prevention were reduced in Scenario 2 and the other ecosystem services functions were changed small. The provisioning services in Scenario 3 and Scenario 4 were weakened, which reduced by about 0.3%. While the regulation services were improved significantly, especially the function of the climate regulation and regulation of water flows.

Figure 7 Spatial distribution and the proportions of ESV in the Yellow River Basin by 2015 under different scenarios. Where (a), (b), (c) and (d) represent the ESV under the Scenario 1, Scenario 2, Scenario 3 and Scenario 4, respectively.
Figure 7

Spatial distribution and the proportions of ESV in the Yellow River Basin by 2015 under different scenarios. Where (a), (b), (c) and (d) represent the ESV under the Scenario 1, Scenario 2, Scenario 3 and Scenario 4, respectively.

Figure 8 Changes in the values of different ecosystem services in the Yellow River Basin under different scenarios, where ΔS2–S1, ΔS3–S1 and ΔS4–S1 represent the discrepancies of Scenario 1 with Scenario 2, Scenario 3 and Scenario 4, respectively.
Figure 8

Changes in the values of different ecosystem services in the Yellow River Basin under different scenarios, where ΔS2–S1, ΔS3–S1 and ΔS4–S1 represent the discrepancies of Scenario 1 with Scenario 2, Scenario 3 and Scenario 4, respectively.

4 Discussion

4.1 Effects of climate change on landscape patterns and ecosystem services function

Since 1995, climate change was notable in the Yellow River Basin. The average temperature was increased by 0.4°C/10a, which was significantly higher than the growth rate in China (0.25°C/10a) [52]. The average precipitation was decreased by −2.1 mm/10a but presented the characteristic of large spatial-temporal difference. Concurrently, the frequency of extreme events was increased [4,40], such as the agricultural and ecological droughts. In accordance with the simulation results of scenario 1 and scenario 2, under the impacts of climate change, the forestland area was decreased by 0.1% and the grassland area was increased in the Yellow River Basin from 1995 to 2015, but these changes showed great spatial heterogeneity. In the upper reaches of the Yellow River, the forestland area was decreased by 0.2%, the grassland and unutilized land area were increased. While in the middle and lower reaches, the impacts of climate change were weakened, the forestland was reduced by 0.04%.

There were several reasons for these complex spatial–temporal changes. In the upstream high-altitude regions, the vegetation ecosystems were extremely sensitive and fragile in respond to climate variation. The rising temperature prolonged the growing season of vegetation and strengthened the photosynthesis, which improved the vegetation coverage, and led to the enhancement of ecosystem services function and landscape patterns [53,54]. While in the other arid and semi-arid areas, climate warming induced an increase in evaporation, coupled with the decreased precipitation, all of which aggravated the shortage of soil moisture and resulted in the decrease of vegetation coverage, then impaired the ecosystem services [24,55,56]. In addition, extreme drought events were occurred frequently. Studies have proved that prolonged drought may cause trees to die due to the lack of moisture for a long time and reduce the survival rate of trees [25,57]. According to Bulletin of Flood and Drought Disaster in China [58], there were five large-scale droughts in the Yellow River Basin during 1995–2015. Especially the North China Plain drought in 2009, with the features of long duration and wide range, which had serious impacts on the vegetation ecosystems. In conclusion, the vegetation ecosystem was damaged due to climate change in the Yellow River Basin, the fragmentation of vegetation landscape was intensified, which resulted in the reduction of ESV, and the ecosystem regulation services became weakened, such as the erosion prevention.

4.2 Effects of human activities on landscape patterns and ecosystem services function

During the study period, the population density in the Yellow River Basin increased from 121.11 people/km2 (1995) to 149.62 people/km2 (2015), and the GDP per unit area increased from 467.7 yuan/km2 (1995) to 715.0 yuan/km2 (2015). In line with the simulation results of scenario 1 and scenario 3, under the impacts of human activities, the area of forestland, water bodies and construction land were increased by 1.2, 1.3 and 20.6% while the cultivated land and grassland were decreased by 2.0 and 0.3%. However, these variations exhibited different characteristics in the upper, middle and lower reaches of the Yellow River Basin. In Qinghai, Gansu and other mid-upstream cities, the economic development was relatively backward, and with a low population concentration, while the soil erosion and ecological degradation were serious. The local government had implemented large-scale projects of the Grain for Green Project to protect the ecological environment, which resulted in the forestland area increased rapidly, the arable land and grassland were decreased [30,59]. According to statistics, since the implementation of the Grain for Green Project in 1999, the cumulative afforestation area reached 18.9 million hm2. The ecological services functions such as the soil and water conservation in the mid-upstream area were significantly improved, but resulted in the singularization of ecological function and weakened the landscape diversity [32].

In Henan, Shandong and other mid-downstream cities, many large irrigation districts have been built due to the merits of population concentration, flat terrain and convenient irrigation, such as the Yellow River irrigation district, which resulted in a large number of grassland and water bodies converted into arable land [31]. Simultaneously, to cooperate with the population growth and economic development, a large number of cultivated land and ecological land were occupied by the construction land [27]. In addition, some reservoirs have been built for the purpose of irrigation and flood prevention, such as the Xiaolangdi Hydro Project (total storage capacity 12.65 billion m3), as well as some rubber dams have been built for restoring the aquatic ecosystem, such as the water surface engineering [60]; all of these measures have increased the area of water bodies area, which improved the ecosystem regulation of water flows function significantly. The expansion of arable land and construction land in mid-downstream impaired the ecosystem function, but these losses were offset by the increased water bodies and forestland. In general, the total ESV were increased by 0.56 billion dollars affected by human activities, in which the provisioning services function was weakened, and the regulating services and supporting services were improved, but the ecosystem services function tends to be unitary. In terms of landscape patterns, the ecological landscape patterns became more complex and irregular, landscape diversity became more weakened and the anti-interference ability decreased.

4.3 Relationship between landscape patterns and ESV

Studies have shown that there was a close relationship between landscape patterns and ESV. Landscape patterns changed the material circulation and the energy flow in landscape by affecting the types, area and spatial distribution of various ecosystems and then affected the supply and maintenance of ecosystem services function [61,62]. However, the emphases of the two analysis method were different. The landscape patterns index was an important quantitative indicator reflecting the landscape structure composition, spatial configuration and landscape heterogeneity, such as the landscape fragmentation degree and landscape anti-interference ability, which highly concentrated the landscape patterns information and described the spatially discontinuous data [10,47]. While the ESV was a monetary method to quantify the value of ecosystem services function and evaluate the production and living services provided by the ecosystem, including provisioning services, regulating services, supporting services and cultural services [48,49]. Therefore, our study selected the landscape patterns and ESV as the evaluation indicator, which would have a more comprehensive understanding of the impacts of climate change and human activities on the ecosystem of the Yellow River Basin.

5 Conclusions

Our study selected the Yellow River Basin as study area and quantitatively evaluated the contributions of climate change and human activities on landscape patterns and ecosystem services function from 1995 to 2015 by scenarios simulation. The main conclusions were as follows:

  1. Under the combined action of climate change and human activities, the total ESV in the Yellow River Basin increased by 0.5 billion dollars during 1995–2015, the ecological service function increased, but the overall landscape patterns tended to be complicated, fragmented and decentralized.

  2. Climate change has had great impacts on the composition and pattern of vegetation ecosystems in the Yellow River Basin, but these impacts showed great spatial heterogeneity, which presented greater impacts in the upper reaches, where the forestland area was decreased by 0.2%.

  3. The ESVs were increased by 0.56 billion dollars due to human activities, which means that the ecological situation of the Yellow River Basin has been improved, but the contradiction between ecological environment protection and economic development still existed, especially in the middle and lower reaches of the Yellow River, which has brought considerable pressure to local governments.

  4. In the following work, the dynamic evolution between climate change and vegetation ecosystems will be further studied.

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Acknowledgments

This research was supported by the National Science Fund Project (51725905; 52130907; 51879275) and Five Major Excellent Talent Programs of IWHR (WR0199A012021). We acknowledge the Resources and Environmental Sciences and Data Center and China Energy Modeling Forum. Moreover, we would like to thank the reviewers for their constructive and detailed comments.

  1. Author contributions: All the authors contributed to the completion of this article. JH conducted the model building, data processing and article writing. TQ reviewed and revised the comments of the article. SL and SY designed the structure of the manuscript. XZ and CL polished the English expression of the article. JW and JF provided assistance in model building and data processing. All authors have read and agreed to the published version of the manuscript.

  2. Conflicts of interest: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this article.

References

[1] Naeem S, Zhang Y, Tian J, Mueen F, Latif A, Paul PK. Quantifying the impact of anthropogenic activities and climate variations on vegetation productivity change of china from 1985–2015. Remote Sens-Basel. 2020;12(7):1113. 10.3390/rs12071113.Suche in Google Scholar

[2] Paudel B, Wang Z, Zhang Y, Rai MK, Paul PK. Climate change and its impacts in different physiographic regions of the transboundary Koshi River Basin, Central Himalayas. Int J Env Res Pub He. 2021;18(13):7142. 10.3390/ijerph18137142.Suche in Google Scholar PubMed PubMed Central

[3] Foley JA, Defries R, Asner GP, Barford C, Bonan G, Carpenter SR, et al. Global consequences of land use. Science. 2005;309(5734):570–4. 10.1126/science.1111772.Suche in Google Scholar PubMed

[4] Zhang Y, Lu X, Liu B, Wu D, Fu G, Zhao Y, et al. Spatial relationships between ecosystem services and socioecological drivers across a large-scale region: A case study in the Yellow River Basin. Sci Total Environ. 2021;766:142480. 10.1016/j.scitotenv.2020.142480.Suche in Google Scholar PubMed

[5] Hasan SS, Zhen L, Miah MG, Ahamed T, Samie A. Impact of land use change on ecosystem services: A review. Environ Dev. 2020;34:100527. 10.1016/j.envdev.2020.100527.Suche in Google Scholar

[6] Masson-Delmotte V, Zhai P, Pirani A, Connors S, Péan C, Berger S, et al. IPCC, 2021: Summary for Policymakers. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press. In Press. https://www.ipcc.ch/ar6-syr/.Suche in Google Scholar

[7] Afuye GA, Kalumba AM, Orimoloye IR. Characterisation of vegetation response to climate change: a review. Sustainability-Basel. 2021;13(13):7265. 10.3390/su13137265.Suche in Google Scholar

[8] Souza R, Feng X, Antonino A, Montenegro S, Souza E, Porporato A. Vegetation response to rainfall seasonality and interannual variability in tropical dry forests. Hydrol Process. 2016;30(20):3583–95. 10.1002/hyp.10953.Suche in Google Scholar

[9] Su S, Xiao R, Jiang Z, Zhang Y. Characterizing landscape pattern and ecosystem service value changes for urbanization impacts at an eco-regional scale. Appl Geogr. 2012;34:295–305. 10.1016/j.apgeog.2011.12.001.Suche in Google Scholar

[10] Wang X, Yan F, Zeng Y, Chen M, Su F, Cui Y. Changes in ecosystems and ecosystem services in the guangdong-hong kong-macao greater bay area since the reform and opening up in china. Remote Sens-Basel. 2021;13(9):1611. 10.3390/rs13091611.Suche in Google Scholar

[11] Li W, Zinda JA, Zhang Z. Does the “returning farmland to forest program” drive community-level changes in landscape patterns in China? Forests. 2019;10(10):933. 10.3390/f10100933.Suche in Google Scholar

[12] Zhang J, Qu M, Wang C, Zhao J, Cao Y. Quantifying landscape pattern and ecosystem service value changes: A case study at the county level in the chinese loess plateau. Glob Ecol Conserv. 2020;23:e1110. 10.1016/j.gecco.2020.e01110 Suche in Google Scholar

[13] Baiocchi V, Zottele F, Dominici D. Remote sensing of urban microclimate change in L’Aquila City (Italy) after post-earthquake depopulation in an open source GIS environment. Sensors-Basel. 2017;17:404. 10.3390/s17020404.Suche in Google Scholar PubMed PubMed Central

[14] Mortoja MG, Yigitcanlar T. Local drivers of anthropogenic climate change: quantifying the impact through a remote sensing approach in brisbane. Remote Sens-Basel. 2020;12:2270. 10.3390/rs12142270.Suche in Google Scholar

[15] Yang J, Gong P, Fu R, Zhang M, Chen J, Liang S, et al. The role of satellite remote sensing in climate change studies. Nat Clim Change. 2013;3(10):875–83. 10.1038/nclimate1908.Suche in Google Scholar

[16] Watson L, Straatsma MW, Wanders N, Verstegen JA, de Jong SM, Karssenberg D. Global ecosystem service values in climate class transitions. Environ Res Lett. 2020;15(2):24008. 10.1088/1748-9326/ab5aab.Suche in Google Scholar

[17] Estoque RC, Murayama Y. Quantifying landscape pattern and ecosystem service value changes in four rapidly urbanizing hill stations of Southeast Asia. Landscape Ecol. 2016;31(7):1481–507. 10.1007/s10980-016-0341-6.Suche in Google Scholar

[18] Jiang C, Wang F, Zhang H, Dong X. Quantifying changes in multiple ecosystem services during 2000–2012 on the Loess Plateau, China, as a result of climate variability and ecological restoration. Ecol Eng. 2016;97:258–71. 10.1016/j.ecoleng.2016.10.030.Suche in Google Scholar

[19] Zheng K, Wei JZ, Pei JY, Cheng H, Zhang XL, Huang FQ, et al. Impacts of climate change and human activities on grassland vegetation variation in the Chinese Loess Plateau. Sci Total Environ. 2019;660:236–44. 10.1016/j.scitotenv.2019.01.022.Suche in Google Scholar PubMed

[20] Zhang W, Wang L, Xiang F, Qin W, Jiang W. Vegetation dynamics and the relations with climate change at multiple time scales in the Yangtze River and Yellow River Basin, China. Ecol Indic. 2020;110:105892. 10.1016/j.ecolind.2019.105892.Suche in Google Scholar

[21] Jin XY, Jin HJ, Iwahana G, Marchenko SS, Luo DL, Li XY, et al. Impacts of climate-induced permafrost degradation on vegetation: A review. Adv clim chang res. 2021;12(1):29–47. 10.1016/j.accre.2020.07.002.Suche in Google Scholar

[22] Wang M, Fu JE, Wu Z, Pang Z. Spatiotemporal variation of NDVI in the vegetation growing season in the source region of the yellow river, China. Isprs Int J Geo-Inf. 2020;9(4):282. 10.3390/ijgi9040282.Suche in Google Scholar

[23] Ji Y, Zhou G, Wang S, Wang L. Prominent vegetation greening and its correlation with climatic variables in northern China. Environ Monit Assess. 2020;192(10):636. 10.1007/s10661-020-08593-8.Suche in Google Scholar PubMed

[24] Meng X, Gao X, Li S, Lei J. Spatial and temporal characteristics of vegetation NDVI changes and the driving forces in mongolia during 1982–2015. Remote Sens-Basel. 2020;12(4):603. 10.3390/rs12040603.Suche in Google Scholar

[25] Allen CD, Breshears DD, McDowell NG. On underestimation of global vulnerability to tree mortality and forest die-off from hotter drought in the Anthropocene. Ecosphere. 2015;6(8):129. 10.1890/ES15-00203.1.Suche in Google Scholar

[26] Tei S, Sugimoto A, Yonenobu H, Kotani A, Maximov TC. Effects of extreme drought and wet events for tree mortality: Insights from tree‐ring width and carbon isotope ratio in a Siberian larch forest. Ecohydrology. 2019;12:e2143. 10.1002/eco.2143.Suche in Google Scholar

[27] Wang C, Wang Y, Wang R, Zheng P. Modeling and evaluating land-use/land-cover change for urban planning and sustainability: A case study of Dongying city, China. J Clean Prod. 2018;172:1529–34. 10.1016/j.jclepro.2017.10.294.Suche in Google Scholar

[28] Mao Y, Hou L, Zhang Z. Spatial-temporal evolution and relationship between urbanization level and ecosystem service from a dual-scale perspective: a case study of the pearl river delta urban agglomeration. Sustainability-Basel. 2021;13(15):8537. 10.3390/su13158537.Suche in Google Scholar

[29] Chen S, Li G, Xu Z, Zhuo Y, Wu C, Ye Y. Combined impact of socioeconomic forces and policy implications: spatial-temporal dynamics of the ecosystem services value in yangtze river delta, China. Sustainability-Basel. 2019;11(9):2622. 10.3390/su11092622.Suche in Google Scholar

[30] Liu M, Jia Y, Zhao J, Shen Y, Pei H, Zhang H, et al. Revegetation projects significantly improved ecosystem service values in the agro-pastoral ecotone of northern China in recent 20 years. Sci Total Eviron. 2021;788:147756. 10.1016/j.scitotenv.2021.147756.Suche in Google Scholar PubMed

[31] Yin D, Li X, Li G, Zhang J, Yu H. Spatio-temporal evolution of land use transition and its eco-environmental effects: a case study of the yellow river basin, China. Land. 2020;9(12):514. 10.3390/land9120514.Suche in Google Scholar

[32] Liu Y, Zhang D, He K, Gao Q, Qin F. Research on land use change and ecological environment effect based on remote sensing sensor technology. J Sensors. 2021;2021:1–11. 10.1155/2021/4351733.Suche in Google Scholar

[33] Chen T, Bao A, Jiapaer G, Guo H, Zheng G, Jiang L, et al. Disentangling the relative impacts of climate change and human activities on arid and semiarid grasslands in Central Asia during 1982–2015. Sci Total Environ. 2019;653:1311–25. 10.1016/j.scitotenv.2018.11.058.Suche in Google Scholar PubMed

[34] Liu Z, Wu R, Chen Y, Fang C, Wang S. Factors of ecosystem service values in a fast-developing region in China: Insights from the joint impacts of human activities and natural conditions. J Clean Prod. 2021;297:126588. 10.1016/j.jclepro.2021.126588.Suche in Google Scholar

[35] Ling H, Yan J, Xu H, Guo B, Zhang Q. Estimates of shifts in ecosystem service values due to changes in key factors in the manas river basin, northwest China. Sci Total Environ. 2019;659:177–87. 10.1016/j.scitotenv.2018.12.309.Suche in Google Scholar PubMed

[36] Wang H, Liu G, Li Z, Zhang L, Wang Z. Processes and driving forces for changing vegetation ecosystem services: insights from the shaanxi province of China. Ecol Indic. 2020;112:106105. 10.1016/j.ecolind.2020.106105.Suche in Google Scholar

[37] Jiang C, Zhang H, Zhang Z. Spatially explicit assessment of ecosystem services in China’s Loess Plateau: Patterns, interactions, drivers, and implications. Global Planet Change. 2018;161:41–52. 10.1016/j.gloplacha.2017.11.014.Suche in Google Scholar

[38] Sun J, Wang X, Cao Y, Li H, Jung K. Analysis of spatial and temporal evolution of hydrological and meteorological elements in nenjiang river basin, China. Theor Appl Climatol. 2019;137(1–2):941–61. 10.1007/s00704-018-2641-z.Suche in Google Scholar

[39] Salman SA, Shahid S, Ismail T, Chung E, Al-Abadi AM. Long-term trends in daily temperature extremes in Iraq. Atmos Res. 2017;198:97–107. 10.1016/j.atmosres.2017.08.011.Suche in Google Scholar

[40] Zhao Y, Xu X, Huang W, Wang Y, Xu Y, Chen H, et al. Trends in observed mean and extreme precipitation within the yellow river basin, China. Theor Appl Climatol. 2018;136(3–4):1387–96. 10.1007/s00704-018-2568-4.Suche in Google Scholar

[41] Yang Y, Weng B, Man Z, Yu Z, Zhao J. Analyzing the contributions of climate change and human activities on runoff in the northeast tibet plateau. J Hydrol-Res Stud. 2020;27:100639. 10.1016/j.ejrh.2019.100639.Suche in Google Scholar

[42] Liu X, Liang X, Li X, Xu X, Ou J, Chen Y, et al. A future land use simulation model (FLUS) for simulating multiple land use scenarios by coupling human and natural effects. Landscape Urban Plan. 2017;168:94–116. 10.1016/j.landurbplan.2017.09.019.Suche in Google Scholar

[43] Liang X, Liu X, Li X, Chen Y, Tian H, Yao Y. Delineating multi-scenario urban growth boundaries with a CA-based FLUS model and morphological method. Landscape Urban Plan. 2018;177:47–63. 10.1016/j.landurbplan.2018.04.016.Suche in Google Scholar

[44] Liang X, Liu X, Li D, Zhao H, Chen G. Urban growth simulation by incorporating planning policies into a CA-based future land-use simulation model. Int J Geogr Inf Sci. 2018;32(11):2294–316. 10.1080/13658816.2018.1502441.Suche in Google Scholar

[45] Wang J, Wang K, Qin T, Nie H, Lv Z, Liu F, et al. Analysis and prediction of LUCC change in Huang-Huai-Hai river basin. Open Geosci. 2020;12(1):1406–20. 10.1515/geo-2020-0112.Suche in Google Scholar

[46] Liu Y, Hou X, Li X, Song B, Wang C. Assessing and predicting changes in ecosystem service values based on land use/cover change in the Bohai Rim coastal zone. Ecol Indic. 2020;111:106004. 10.1016/j.ecolind.2019.106004.Suche in Google Scholar

[47] Zhao Q, Wen Z, Chen S, Ding S, Zhang M. Quantifying land use/land cover and landscape pattern changes and impacts on ecosystem services. Int J Env Res Pub He. 2020;17(1):126. 10.3390/ijerph17010126.Suche in Google Scholar PubMed PubMed Central

[48] Liu L, Chen X, Chen W, Ye X. Identifying the impact of landscape pattern on ecosystem services in the middle reaches of the yangtze river urban agglomerations, China. Int J Env Res Pub He. 2020;17(14):5063. 10.3390/ijerph17145063.Suche in Google Scholar PubMed PubMed Central

[49] Costanza R, d'Arge R, De Groot R, Farber S, Grasso M, Hannon B, et al. The value of the world’s ecosystem services and natural capital. Nature. 1997;387:253–60.10.1038/387253a0Suche in Google Scholar

[50] Xie G, Zhen L, Lu C, Xiao Y, Chen C. Expert knowledge based valuation method of ecosystem services in China. J Nat Resour. 2008;23:911–9 (in Chinese with English summary).Suche in Google Scholar

[51] Xie G, Zhang C, Zhen L, Zhang L. Dynamic changes in the value of China’s ecosystem services. Ecosyst Serv. 2017;26:146–54. 10.1016/j.ecoser.2017.06.010.Suche in Google Scholar

[52] Ren G, Ding Y, Tang G. An overview of mainland china temperature change research. J Meteor Res. 2017;31(1):3–16. 10.1007/s13351-017-6195-2.Suche in Google Scholar

[53] Xu S, Yu Z, Yang C, Ji X, Zhang K. Trends in evapotranspiration and their responses to climate change and vegetation greening over the upper reaches of the yellow river basin. Agr Forest Meteorol. 2018;263:118–29. 10.1016/j.agrformet.2018.08.010.Suche in Google Scholar

[54] Lu C, Hou M, Liu Z, Li H, Lu C. Variation characteristic of NDVI and its response to climate change in the middle and upper reaches of yellow river basin, China. Ieee J-Stars. 2021;14:8484–96. 10.1109/JSTARS.2021.3105897.Suche in Google Scholar

[55] Zhao Q, Ma X, Liang L, Yao W. Spatial-temporal variation characteristics of multiple meteorological variables and vegetation over the loess plateau region. Appl Sci. 2020;10(3):1000. 10.3390/app10031000.Suche in Google Scholar

[56] Liu S, Huang S, Xie Y, Wang H, Huang Q, Leng G, et al. Spatial-temporal changes in vegetation cover in a typical semi-humid and semi-arid region in China: Changing patterns, causes and implications. Ecol Indic. 2019;98:462–75. 10.1016/j.ecolind.2018.11.037.Suche in Google Scholar

[57] Omer A, Zhuguo M, Yuan X, Zheng Z, Saleem F. A hydrological perspective on drought risk-assessment in the yellow river basin under future anthropogenic activities. J Environ Manage. 2021;289:112429. 10.1016/j.jenvman.2021.112429.Suche in Google Scholar PubMed

[58] Ministry of Water Resources of the People’s Republic of China: Bulletin of Flood and Drought Disaster in China. http://www.mwr.gov.cn/sj/tjgb/zgshzhgb/.Suche in Google Scholar

[59] Han X, Yu J, Shi L, Zhao X, Wang J. Spatiotemporal evolution of ecosystem service values in an area dominated by vegetation restoration: Quantification and mechanisms. Ecol Indic. 2021;131:108191. 10.1016/j.ecolind.2021.108191.Suche in Google Scholar

[60] Hou J, Qin T, Liu S, Wang J, Dong B, Yan S, et al. Analysis and prediction of ecosystem service values based on land use/cover change in the yiluo river basin. Sustainability-Basel. 2021;13(11):6432. 10.3390/su13116432.Suche in Google Scholar

[61] Hu Z, Yang X, Yang J, Yuan J, Zhang Z. Linking landscape pattern, ecosystem service value, and human well-being in Xishuangbanna, southwest China: Insights from a coupling coordination model. Glob Ecol Conserv. 2021;27:e1583. 10.1016/j.gecco.2021.e01583.Suche in Google Scholar

[62] Tang J, Li Y, Cui S, Xu L, Ding S, Nie W. Linking land-use change, landscape patterns, and ecosystem services in a coastal watershed of southeastern China. Glob Ecol Conserv. 2020;23:e1177. 10.1016/j.gecco.2020.e01177.Suche in Google Scholar
Received: 2021-11-19
Revised: 2022-05-23
Accepted: 2022-05-24
Published Online: 2022-06-28

© 2022 Jun Hou et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/geo-2022-0385
Schlagwörter für diesen Artikel
climate change; human activities; ecosystem services values; landscape patterns; future land use simulation model
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Artikel in diesem Heft

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  13. Research on comprehensive benefits and reasonable selection of marine resources development types
  14. Embedded deformation of the rubble-mound foundation of gravity-type quay walls and influence factors
  15. Activation of Ad Damm shear zone, western Saudi Arabian margin, and its relation to the Red Sea rift system
  16. A mathematical conjecture associates Martian TARs with sand ripples
  17. Study on spatio-temporal characteristics of earthquakes in southwest China based on z-value
  18. Sedimentary facies characterization of forced regression in the Pearl River Mouth basin
  19. High-precision remote sensing mapping of aeolian sand landforms based on deep learning algorithms
  20. Experimental study on reservoir characteristics and oil-bearing properties of Chang 7 lacustrine oil shale in Yan’an area, China
  21. Estimating the volume of the 1978 Rissa quick clay landslide in Central Norway using historical aerial imagery
  22. Spatial accessibility between commercial and ecological spaces: A case study in Beijing, China
  23. Curve number estimation using rainfall and runoff data from five catchments in Sudan
  24. Urban green service equity in Xiamen based on network analysis and concentration degree of resources
  25. Spatio-temporal analysis of East Asian seismic zones based on multifractal theory
  26. Delineation of structural lineaments of Southeast Nigeria using high resolution aeromagnetic data
  27. 3D marine controlled-source electromagnetic modeling using an edge-based finite element method with a block Krylov iterative solver
  28. A comprehensive evaluation method for topographic correction model of remote sensing image based on entropy weight method
  29. Quantitative discrimination of the influences of climate change and human activity on rocky desertification based on a novel feature space model
  30. Assessment of climatic conditions for tourism in Xinjiang, China
  31. Attractiveness index of national marine parks: A study on national marine parks in coastal areas of East China Sea
  32. Effect of brackish water irrigation on the movement of water and salt in salinized soil
  33. Mapping paddy rice and rice phenology with Sentinel-1 SAR time series using a unified dynamic programming framework
  34. Analyzing the characteristics of land use distribution in typical village transects at Chinese Loess Plateau based on topographical factors
  35. Management status and policy direction of submerged marine debris for improvement of port environment in Korea
  36. Influence of Three Gorges Dam on earthquakes based on GRACE gravity field
  37. Comparative study of estimating the Curie point depth and heat flow using potential magnetic data
  38. The spatial prediction and optimization of production-living-ecological space based on Markov–PLUS model: A case study of Yunnan Province
  39. Major, trace and platinum-group element geochemistry of harzburgites and chromitites from Fuchuan, China, and its geological significance
  40. Vertical distribution of STN and STP in watershed of loess hilly region
  41. Hyperspectral denoising based on the principal component low-rank tensor decomposition
  42. Evaluation of fractures using conventional and FMI logs, and 3D seismic interpretation in continental tight sandstone reservoir
  43. U–Pb zircon dating of the Paleoproterozoic khondalite series in the northeastern Helanshan region and its geological significance
  44. Quantitatively determine the dominant driving factors of the spatial-temporal changes of vegetation-impacts of global change and human activity
  45. Can cultural tourism resources become a development feature helping rural areas to revitalize the local economy under the epidemic? An exploration of the perspective of attractiveness, satisfaction, and willingness by the revisit of Hakka cultural tourism
  46. A 3D empirical model of standard compaction curve for Thailand shales: Porosity in function of burial depth and geological time
  47. Attribution identification of terrestrial ecosystem evolution in the Yellow River Basin
  48. An intelligent approach for reservoir quality evaluation in tight sandstone reservoir using gradient boosting decision tree algorithm
  49. Detection of sub-surface fractures based on filtering, modeling, and interpreting aeromagnetic data in the Deng Deng – Garga Sarali area, Eastern Cameroon
  50. Influence of heterogeneity on fluid property variations in carbonate reservoirs with multistage hydrocarbon accumulation: A case study of the Khasib formation, Cretaceous, AB oilfield, southern Iraq
  51. Designing teaching materials with disaster maps and evaluating its effectiveness for primary students
  52. Assessment of the bender element sensors to measure seismic wave velocity of soils in the physical model
  53. Appropriated protection time and region for Qinghai–Tibet Plateau grassland
  54. Identification of high-temperature targets in remote sensing based on correspondence analysis
  55. Influence of differential diagenesis on pore evolution of the sandy conglomerate reservoir in different structural units: A case study of the Upper Permian Wutonggou Formation in eastern Junggar Basin, NW China
  56. Planting in ecologically solidified soil and its use
  57. National and regional-scale landslide indicators and indexes: Applications in Italy
  58. Occurrence of yttrium in the Zhijin phosphorus deposit in Guizhou Province, China
  59. The response of Chudao’s beach to typhoon “Lekima” (No. 1909)
  60. Soil wind erosion resistance analysis for soft rock and sand compound soil: A case study for the Mu Us Sandy Land, China
  61. Investigation into the pore structures and CH4 adsorption capacities of clay minerals in coal reservoirs in the Yangquan Mining District, North China
  62. Overview of eco-environmental impact of Xiaolangdi Water Conservancy Hub on the Yellow River
  63. Response of extreme precipitation to climatic warming in the Weihe river basin, China and its mechanism
  64. Analysis of land use change on urban landscape patterns in Northwest China: A case study of Xi’an city
  65. Optimization of interpolation parameters based on statistical experiment
  66. Late Cretaceous adakitic intrusive rocks in the Laimailang area, Gangdese batholith: Implications for the Neo-Tethyan Ocean subduction
  67. Tectonic evolution of the Eocene–Oligocene Lushi Basin in the eastern Qinling belt, Central China: Insights from paleomagnetic constraints
  68. Geographic and cartographic inconsistency factors among different cropland classification datasets: A field validation case in Cambodia
  69. Distribution of large- and medium-scale loess landslides induced by the Haiyuan Earthquake in 1920 based on field investigation and interpretation of satellite images
  70. Numerical simulation of impact and entrainment behaviors of debris flow by using SPH–DEM–FEM coupling method
  71. Study on the evaluation method and application of logging irreducible water saturation in tight sandstone reservoirs
  72. Geochemical characteristics and genesis of natural gas in the Upper Triassic Xujiahe Formation in the Sichuan Basin
  73. Wehrlite xenoliths and petrogenetic implications, Hosséré Do Guessa volcano, Adamawa plateau, Cameroon
  74. Changes in landscape pattern and ecological service value as land use evolves in the Manas River Basin
  75. Spatial structure-preserving and conflict-avoiding methods for point settlement selection
  76. Fission characteristics of heavy metal intrusion into rocks based on hydrolysis
  77. Sequence stratigraphic filling model of the Cretaceous in the western Tabei Uplift, Tarim Basin, NW China
  78. Fractal analysis of structural characteristics and prospecting of the Luanchuan polymetallic mining district, China
  79. Spatial and temporal variations of vegetation coverage and their driving factors following gully control and land consolidation in Loess Plateau, China
  80. Assessing the tourist potential of cultural–historical spatial units of Serbia using comparative application of AHP and mathematical method
  81. Urban black and odorous water body mapping from Gaofen-2 images
  82. Geochronology and geochemistry of Early Cretaceous granitic plutons in northern Great Xing’an Range, NE China, and implications for geodynamic setting
  83. Spatial planning concept for flood prevention in the Kedurus River watershed
  84. Geophysical exploration and geological appraisal of the Siah Diq porphyry Cu–Au prospect: A recent discovery in the Chagai volcano magmatic arc, SW Pakistan
  85. Possibility of using the DInSAR method in the development of vertical crustal movements with Sentinel-1 data
  86. Using modified inverse distance weight and principal component analysis for spatial interpolation of foundation settlement based on geodetic observations
  87. Geochemical properties and heavy metal contents of carbonaceous rocks in the Pliocene siliciclastic rock sequence from southeastern Denizli-Turkey
  88. Study on water regime assessment and prediction of stream flow based on an improved RVA
  89. A new method to explore the abnormal space of urban hidden dangers under epidemic outbreak and its prevention and control: A case study of Jinan City
  90. Milankovitch cycles and the astronomical time scale of the Zhujiang Formation in the Baiyun Sag, Pearl River Mouth Basin, China
  91. Shear strength and meso-pore characteristic of saturated compacted loess
  92. Key point extraction method for spatial objects in high-resolution remote sensing images based on multi-hot cross-entropy loss
  93. Identifying driving factors of the runoff coefficient based on the geographic detector model in the upper reaches of Huaihe River Basin
  94. Study on rainfall early warning model for Xiangmi Lake slope based on unsaturated soil mechanics
  95. Extraction of mineralized indicator minerals using ensemble learning model optimized by SSA based on hyperspectral image
  96. Lithofacies discrimination using seismic anisotropic attributes from logging data in Muglad Basin, South Sudan
  97. Three-dimensional modeling of loose layers based on stratum development law
  98. Occurrence, sources, and potential risk of polycyclic aromatic hydrocarbons in southern Xinjiang, China
  99. Attribution analysis of different driving forces on vegetation and streamflow variation in the Jialing River Basin, China
  100. Slope characteristics of urban construction land and its correlation with ground slope in China
  101. Limitations of the Yang’s breaking wave force formula and its improvement under a wider range of breaker conditions
  102. The spatial-temporal pattern evolution and influencing factors of county-scale tourism efficiency in Xinjiang, China
  103. Evaluation and analysis of observed soil temperature data over Northwest China
  104. Agriculture and aquaculture land-use change prediction in five central coastal provinces of Vietnam using ANN, SVR, and SARIMA models
  105. Leaf color attributes of urban colored-leaf plants
  106. Application of statistical and machine learning techniques for landslide susceptibility mapping in the Himalayan road corridors
  107. Sediment provenance in the Northern South China Sea since the Late Miocene
  108. Drones applications for smart cities: Monitoring palm trees and street lights
  109. Double rupture event in the Tianshan Mountains: A case study of the 2021 Mw 5.3 Baicheng earthquake, NW China
  110. Review Article
  111. Mobile phone indoor scene features recognition localization method based on semantic constraint of building map location anchor
  112. Technical Note
  113. Experimental analysis on creep mechanics of unsaturated soil based on empirical model
  114. Rapid Communications
  115. A protocol for canopy cover monitoring on forest restoration projects using low-cost drones
  116. Landscape tree species recognition using RedEdge-MX: Suitability analysis of two different texture extraction forms under MLC and RF supervision
  117. Special Issue: Geoethics 2022 - Part I
  118. Geomorphological and hydrological heritage of Mt. Stara Planina in SE Serbia: From river protection initiative to potential geotouristic destination
  119. Geotourism and geoethics as support for rural development in the Knjaževac municipality, Serbia
  120. Modeling spa destination choice for leveraging hydrogeothermal potentials in Serbia
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Heruntergeladen am 9.9.2025 von https://www.degruyterbrill.com/document/doi/10.1515/geo-2022-0385/html
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