Grassland Variation and Its Driving Factors from 2000 to 2016: A Comparative Assessment between Qinghai-Tibet Plateau and Inner Mongolia Plateau

Abstract

The grassland of Qinghai-Tibet Plateau (QTP) and Inner Mongolia Plateau (IMP), accounting for 73.9% of the total grassland area in China, is significant to food and ecological safety. Due to climate change and irrational human activities, grasslands on the two plateaus have severely degraded over recent decades. Understanding the dynamic changes of grassland and its driving forces is necessary to make effective measurements to prevent grassland degradation. Here, we selected the net primary productivity (NPP) as an indicator to quantitatively assess the dynamic variation of grassland and the relative roles of climate change and human activities on QTP and IMP from 2000 to 2016. The results found significant spatial variability of grassland on QTP. 28.3% of the grassland experienced degradation and was mainly distributed in the southern QTP, versus 71.7% of the grassland was restored and mainly distributed in the central and northern QTP. In contrast, grassland on IMP didn’t show significant spatial variability. Most of the grassland on IMP was restored during the study period. Climate change (i.e. increased precipitation) was the dominant factor and could explain 72.8% and 84.4% of the restored grassland in QTP and IMP. Irrational human activities (i.e. overgrazing) were the main driving factors and could explain 72.9% and 100.0% of the degraded grassland on the two plateaus during the study period. Ecological restoration projects were favorable for grassland restoration on the two plateaus, and they contributed to 27.2% and 15.6% of the restored grassland in QTP and IMP, respectively. Therefore, climate changes on IMP were more favorable for grassland restoration, and human activities have a greater impact on the grassland variation on QTP.

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Li, X. , Zhang, L. , Zhang, G. , Cui, H. and Liu, L. (2022) Grassland Variation and Its Driving Factors from 2000 to 2016: A Comparative Assessment between Qinghai-Tibet Plateau and Inner Mongolia Plateau. Journal of Environmental Protection, 13, 411-426. doi: 10.4236/jep.2022.136026.

1. Introduction

Qinghai-Tibet Plateau and Inner Mongolia Plateau are the main distributive regions of grassland in China (accounting for 73.9% of the total grassland area in China) and distributed the largest proportion of alpine and temperate grasslands, respectively. Meanwhile, the two plateaus are sensitive areas to global climate changes [1] (Sha et al., 2015). In recent decades, the two plateaus have been experiencing similarly higher rates of warming than the rest of the world [2] [3] [4], but precipitation in QTP and IMP shows a mixed trend and a decreasing trend, respectively. Also, there is an increasing intensity of human activities in QTP and IMP (China Statistical Yearbook). Due to climate change and human activities, 38.8% and 28.8% of the grassland experienced severe degradation on QTP and IMP, respectively [5] [6]. Grassland degradation could cause serious environmental problems [7] [8] and threaten food and ecological safety [9] [10] [11] [12]. To prevent grassland degradation, the government has been implementing a series of ecological restoration projects on QTP and IMP since 2000. These changes in climate and human activities could profoundly induce the dynamic change of grassland. Therefore, it’s necessary to understand the dynamic change of grassland in recent years and its driving factors to help prevent grassland degradation and ensure grassland ecological security.

Many studies discussed grassland degradation and its association with climate change and human activities on QTP and IMP [13]. It is found that the grassland of QTP showed an overall degraded trend before 2000 and a recovery trend after 2000, and climate change is the main driving factor for grassland dynamic change and the role of human activities gradually increases [6] [14] [15] [16]. A similar dynamic change of grassland and its key driving factors are found in IMP [17]. It is emphasized that irrational human activities induced the grassland degradation but ecological projects are favorable to grassland restoration [18] [19] [20] [21] [22]. However, several gaps remain in previous research: 1) most studies focused on several selected fields and hotspots, and large-scale study is few; 2) most of the studies are qualitative but lack quantitative data; 3) there are few studies considering the relative role of human activities as most studies have focused on climatic factors.

Vegetation indexes are effective indicators to monitor grassland degradation and reveal the impacts of human activities and climate change on grassland degradation [14] [23] [24] [25] [26]. Net primary productivity (NPP), the net amount of solar radiation converted to plant organic matter by plants through photosynthesis, can reflect the growth status of vegetation [27] and also is sensitive to both climate variation and human activities [28]. Therefore, many researchers have adopted NPP as an indicator of grassland degradation and to distinguish the impact of climate from that of human activities [29] [30] [31] [32] [33]. Haberl [34] first proposed the human appropriation of NPP as a measure of the environmental impacts of human activities. Zika and Erb introduced this approach for the quantitative assessment of the effect of human activities on degradation [35]. Latest studies improved this approach which introduced actual NPP (ANPP) to monitor the grassland degradation status, the potential NPP (PNPP) and the human-influenced NPP (HNPP, and the difference between PNPP and ANPP) to assess the effect of climate change and human activities on grassland degradation, respectively. These studies confirmed that the NPP is a reliable indicator to monitor grassland degradation and distinguish the impact of climate from that of human activities [6] [14] [23] [24] [25] [26].

The grassland in the two plateaus may respond differently to climate changes and human activities. Regional-scale comparative studies are important in providing an understanding of different regional responses to climate changes and human activities and making progress together to protect grassland [24] [26] [36]. In view of grassland on QTP and IMP playing an important role in the grassland ecosystem of China, this study aims to monitor and evaluate the impact of climate change and human activities on grassland change dynamics on QTP and IMP by using ANPP as the indicator to monitoring the grassland degradation status on QTP and IMP from 2000 to 2016 and combining ANPP with PNPP and HNPP. We hope the results will provide useful information to improve our understanding of the relative contributions of climate changes and human activities to grassland degradation, and therefore contribute to developing reasonable policies to combat grassland degradation in China.

2. Materials and Methods

2.1. Data

In this study, the normalized-difference vegetation index (NDVI), vegetation type data, and meteorological data were necessary to calculate the ANPP in the study area. We downloaded the 16-day synthesized, atmospherically corrected maximum NDVI data (MOD13A1) with the spatial resolution of 1000 m from NASA’s archive and distribution System (https://ladsweb.modaps.eosdis.nasa.gov/search/). We used the 16-day NDVI data to synthesize monthly NDVI values using the maximum-value compositing method. Vegetation distribution data was derived from a national vegetation distribution map downloaded from the China’s WestDC site (http://westdc.westgis.ac.cn/). The grassland data was obtained from the vegetation distribution map. The vegetation distribution map was created mainly based on field investigation, remote sensing images and other materials in vector format and has the best accuracy in China. The data was resampled to a spatial resolution of 1000 m. The meteorological data was downloaded from China’s National Meteorological Information Data (http://data.cma.cn/), which includes monthly average temperature and total precipitation recorded at 204 meteorological stations, and the total solar radiation recorded at 43 meteorological stations in and around the study area. The meteorological data was interpolated using ANUSPLINE version 4.3 software to generate monthly raster images with spatial resolutions of 1000 m. We applied the Albers equal-area conical projection and WGS-84 datum to all spatial data.

Field investigations were conducted to collect the aboveground biomass in 2014, 2015 and 2016 on QTP and 2015 on IMP. There were 80 sites to collect grassland aboveground biomass. At each site, three quadrats of 100 cm multiply by 100 cm were set up, and then the measured NPP was calculated by the aboveground biomass [37].

2.2. Methods

The CASA model, accounting for the light-use efficiency of vegetation, was developed and modified by many researchers [27] [38] [39], and was the most widely used model in recent years [40]. So we used the CASA model to calculate ANPP (g.cm−2.yr−1). ANPP is determined by two variables: the absorbed photosynthetically active radiation (APAR) and light-use efficiency (ε):

ANPP = APAR × ε = FPAR × SOL × 0.5 × ε max × T ε × W ε (1)

where FPAR is the fraction of the total solar radiation (SOL) accounted for by PAR and can be calculated from NDVI, SOL is the total solar radiation, 0.5 is the proportion of SOL intercepted by the vegetation, ε max is the maximum light-use efficiency under ideal conditions, and T ε and W ε is the temperature and moisture stress coefficient, respectively. The detail information of CASA model was discussed by [27].

The validation can be made by comparing the simulation results with observed data [41]. In practice, NPP data converted from biomass is often used as a substitute for observed NPP data as it is usually difficult to obtain the latter [41]. In the present study, the observed NPP data was calculated based on the field-measured biomass data on QTP and IMP. The observed data was used to verify the CASA modeling results on spatial location. Our comparison between the observed ANPP and the CASA simulation results showed good agreement with actual data from field sampling points (R2 = 0.829, p < 0.01; Figure 1), so the simulation accuracy of the model was satisfactory for the needs of the study.

In this study, we used the Synthetic model to estimate PNPP (g.cm−2.yr−1), which can provided better simulation of PNPP in semiarid and arid areas of China [42]. The model estimated NPP by relating the water-balance and heat-balance equations [42], and was expressed as follows:

PNPP = RDI 2 × r × ( 1 + RDI + RDI 2 ) ( 1 + RDI ) ( 1 + RDI 2 ) × exp [ 9.87 + 6.25 RDI ] × 100 (2)

RDI = ( 0.629 + 0.237 PER 0.00313 PER 2 ) 2 (3)

PER = 58.93 × BT / r (4)

Figure 1. Validation of the CASA model for the grasslands in study area.

where r is the annual total precipitation (mm), BT is annual average biological temperature (˚C), which is defined as the average biological temperature for temperatures ranging between 0˚C and 30˚C, PER is the potential evaporation (mm), RDI is the radiative index of dryness.

HNPP (g.cm−2.yr−1) is the difference between PNPP and ANPP, and represents the loss or increment of NPP induced by human activities:

HNPP ( x , t ) = PNPP ( x , t ) ANPP ( x , t ) (5)

Thus, a positive HNPP represents an NPP loss induced by human activities and a negative value represents an NPP increment produced by human activities.

Vegetation dynamics measured by NPP are the most intuitive manifestation of grassland degradation [25]. In this study, the Formula (6) was used to calculate the trends in ANPP, PNPP, and HNPP from 2000 to 2016 in the study area:

Slope = [ 17 × i = 1 17 i × NPP i ( i = 1 17 i i = 1 17 NPP i ) ] / ( 17 × i = 1 17 i 2 ( i = 1 17 i ) 2 ) (6)

where i = 1, 2, …17 are the years 2000, 2001, … 2016, respectively, and NPP i is the NPP value in yeari. A positive slope of ANPP (SANPP) represents grassland reversion, whereas a negative SANPP represents grassland degradation. The slopes of PNPP (SPNPP) and HNPP (SHNPP) from 2000 to 2016 reveal the impacts of climate change and human activities on grassland degradation, respectively. To determine the change in NPPs during the study period, we calculate the total change of NPP for each pixel using the following formula:

Δ NPP = ( n 1 ) × Slope (7)

where n = 17 years, represents the study period from 2000 to 2016. With reference to previous studies of the relative impacts of human activities and climate change on desertification [43] [44], we defined eight scenarios. Table 1 shows the eight scenarios that induced the grassland dynamics.

Table 1. Methods for assessing the driving factors of grassland restoration or degradation in eight scenarios.

Note: ∆PNPP is the total increase or decrease of PNPP during 2000-2016. ∆HNPP is the total increase or decrease of HNPP. The two indicators were calculated using Equation (7).

3. Results

3.1. Trends in ANPP, PNPP, and HNPP

The simulated results showed the average annual changing rate of grassland ANPP on QTP was 0.9 g.cm2·a1 during the study period, and the rate in most of grassland on QTP was between 0.0 - 2.0 g.cm2·a1. Grassland ANPP on QTP showed obvious spatial variability (Figure 2(a)). Grassland that exhibited increasing ANPP (SANPP > 0) was 992,760 km2, accounted for 71.7% of the total area of grassland. Grassland that exhibited decreasing ANPP (SANPP < 0) was 392 248 km2, mainly distributed in the south of the QTP, accounted for 28.3% of the total area of grassland (Figure 2(a)). Contrary to the grassland on QTP, most of grassland on IMP experienced increasing ANPP, and the annual changing rate in most grassland was above 2.0 g.cm2·a1. The total area with SANPP > 0 was 489 333 km2, far more than the area with SANPP < 0 (29 901 km2) on IMP. The grassland withSANPP < 0 only count for 5.8% of the total area of grassland on IMP, which was sporadically distributed (Figure 2(a)).

The trend of grassland PNPP on QTP also showed obvious spatial variability. Grassland that exhibited increasing PNPP (SPNPP > 0) was 1,084,441 km2, accounting for 78.3% of the total area of grassland. The remaining 21.7% of this area (300,567 km2) had SPNPP < 0, primarily in the south (Figure 2(b)). However, the grassland PNPP exhibited an increasing trend on the whole IMP, and the increasing rate was above 2.0 g.cm2·a1 for most grassland (Figure 2(b)). That means climate changes on IMP were more favorable for grassland restoration than that on QTP.

Figure 2. Spatial distributions of trends for (a) ANPP (SANPP), (b) PNPP (SPNPP) and (c) HNPP (SHNPP) of the QTP and IMP grasslands in the periods 2000-2016.

Compared with PNPP and ANPP, the trend in HNPP from 2000 to 2016 showed a different spatial distribution pattern (Figure 2(c)). On QTP, grassland that showed increasing HNPP (SHNPP > 0), accounts for 62.6% of the total area and primarily distributes in the west and south. The remaining 37.4% of the total area (518,447 km2) was in the east and middle region, where human activities had a positive effect on grassland (Figure 2(c)). On IMP, the grassland with SHNPP > 0, accounts for 57.5% of the total area of grassland (298,605 km2) and mainly distributed in the west and middle region. The grassland with SHNPP < 0 (positive effect of human activities on grassland) accounted for 42.5% of the total area (220,629 km2), primarily distributed in the north and south region, where the climate was relative warmer and wetter (Figure 2(c)).

3.2. Contributions of Climate Change and Human Activities to Grassland Dynamics

By superimposing the data for the trends in PNPP and HNPP in the areas of grassland restoration (SANPP > 0), we obtained the dominant factors responsible for grassland restoration from 2000 to 2016 based on the scenario definitions. The result showed that climate change dominated 72.8% of the grassland restoration on QTP, which mainly distributed in the central and northern region (Figure 3 & Table 2). The remaining 27.2% of grassland restoration was due to human activities. Similarly, climate change was also the main driving factor for grassland restoration on IMP. Climate-dominated restoration accounted for 84.4% of the total grassland restoration area, the remaining 15.6% of grassland restoration was due to human activities (Figure 2).

Figure 3. Spatial distribution of the (a) climate-dominated restoration, (b) human-dominated restoration, (c) climate-dominated degradation and (d) human-dominated degradation of the QTP and IMP grasslands.

Table 2. The relative role of climate change and human activities in the dynamic change of grassland.

The driving factors of grassland degradation were also analyzed. Spatial variation in the dominant factors responsible for grassland degradation existed on QTP. Climate-dominated degradation accounted for 27.1% of the total degradation area, which mainly distributed in the south region (Figure 3 & Table 2). And 72.9% of the degraded grassland was induced by human activities, which mainly distributed in the southwestern and eastern region. Contrary to QTP, 100% of the degraded grassland on IMP was caused by human activities (Table 2).

Spatial distribution of the trends for the average annual temperature and the annual total precipitation of QTP and IMP from 2000 to 2016 were shown in Figure 4, while the Time series of grassland PNPP, annual temperature, precipitation, grassland HNPP and livestock number of the two plateaus from 2000 to 2016 were in Figure 4.

Figure 4. Spatial distribution of the trends for (a) the average annual temperature and (b) the annual total precipitation from 2000 to 2016.

4. Discussion

Climate change is one of the key factors that affect the grassland degradation [45] [46]. In this study, we found that grassland on QTP and IMP showed an overall restoration from 2000 to 2016, and climate changes dominated the grassland restoration. This result was consistent with previous studies of grassland NPP on QTP and IMP [15] [21]. On the QTP and IMP (the most sensitive areas of global climate change), grassland is mainly located in arid, semi-arid and semi-humid zones. The grassland in these regions is particularly susceptible to fluctuations in precipitation [47] [48] [49]. Besides, low temperature was the limiting factor for grassland growth on QTP [50]. On the QTP, there is a consensus that temperature increased in most region in recent 30 to 50 years. But the trend in precipitation varied spatially, with a decrease in southern of QTP, and an increase in central and western of QTP [4] [14] [51]. The trend in precipitation (Figure 4(b)) showed a similar spatial distribution to the trends in PNPP and ANPP (Figure 2). This suggests that increasing precipitation promoted vegetation growth, and decreasing precipitation restrained vegetation growth. The rising temperature exerts complex effects on vegetation growth [14] [40] [49]. Low temperature was the limiting factor for grassland growth on QTP and rising temperature was favor for the grassland growth. Meanwhile, increased evaporation caused by rising temperature will sharpened the dry condition and limit grassland growth. There was no obvious correspondence between the trend in PNPP and temperature on QTP from 2000 to 2016 (Figure 5(a)). Therefore, the variation in precipitation was the dominant climatic driving factor responsible for grassland degradation and restoration on the QTP from 2000 to 2016.

Over the past 30 years, there are an increasing trend in temperature on IMP, and a decreasing trend in precipitation [3] [52]. However, the variation in temperature showed a decreasing trend from 2000 to 2016, the precipitation was in a significantly increasing trend (Figure 5(b)). Water is the limiting factor for vegetation growth on the IMP [50]. Increasing precipitation was favor for vegetation

Figure 5. Time series of (a) grassland PNPP, annual temperature, and precipitation of QTP, (b) grassland PNPP, annual temperature, and precipitation of IMP, (c) grassland HNPP, and livestock number of QTP and (d) grassland HNPP, and livestock number of IMP from 2000 to 2016.

growth and grassland restoration. The variation in PNPP has a good agreement with the variation in the integrated precipitation data (Figure 5(b)), but there is no obvious correspondence relationship between the trend in PNPP and temperature (Figure 5(b)). That means increasing precipitation was the dominant climatic driving factor responsible for grassland restoration on the IMP from 2000 to 2016.

Grazing is one of the important human activities that affected the grassland ecosystem on QTP [7] [14] [53] and IMP [18] [54] [55] [56]. Overgrazing was one of the factors that induced the grassland degradation on QTP [14] [55]. From 2000 to 2016, the total number of livestock in Tibet Autonomous Region and Qinghai Province was in the range of 8.4 × 107 - 9.7 × 107 (standardized sheep units) (Figure 5(c)), most of grassland was overloading. However, as the total number of livestock decreased in general versus the trend in HNPP increased (Figure 5(c)), it implies that there are other irrational human activities that constraint the grassland growth. For example, in recent decades, the tourism in QTP has been developing and the population also increased rapidly (Qinghai Statistical Yearbook and Tibet Statistical Yearbook), all of such activities have brought tremendous pressure to the vulnerable grassland ecosystem.

The total number of livestock in Inner Mongolia Autonomous Region was in the range of 7.0 × 107 - 10.8 × 107 (standardized sheep units) during this study period, grassland was also overloading. Meanwhile, the total number of livestock significantly increased (p < 0.001). And the trend in HNPP also increased from 2000 to 2016 (Figure 5(d)). Thus, the overgrazing, increasing livestock number in accordance with the increased HNPP suggest that overgrazing was one of the main factors induced the degradation of grassland. However, the changing trends of the total number of livestock and HNPP on IMP were different. That means besides grazing, there existed other human activities slowed down the increasing trend of HNPP and promoted the grassland reversion in IMP. Compared the impacts of irrational human activities on the grasslands between the two plateaus, the trend in HNPP on QTP grassland was larger than that on IMP grassland, the areas withSANPP > 0 and human-dominated degradation on QTP grassland were also greater than that on IMP grassland. That means the impact of irrational human activities on the grassland on QTP was greater than that on IMP.

Since 2000, a series of ecological restoration projects have implemented on the QTP and IMP, such as the Grazing Withdrawal Program, the Natural Grassland Protection Program and so on. These programs include enclose the degraded grasslands, ecological compensation, blocks rotational grazing, pest control and so on. These measures have been proved to be effective in controlling the grassland degradation [57] [58] [59]. Our results also showed that human activities were an important factor that promoted the grassland reversion (Figure 3(b)). However, the contributions of human activities to grassland reversion on the two plateaus were different. 27.2% and 15.6% of restored grassland were induced by human activities on QTP and IMP, respectively. The trends in the total number of livestock from 2000 to 2016 were different for the two plateaus, decreasing on QTP, significantly increasing on IMP (Figure 5). Thus, the effect of ecological projects for grassland restoration on QTP was better than those on IMP, which may be related to the differences in ecological protection investment among QTP and IMP.

5. Conclusion

In this study, we analyzed the dynamic variation of grassland and its driving factors on QTP and IMP from 2000 to 2016 by selecting NPP as an indicator. The results showed that the changing trend of grassland on QTP showed obvious spatial variation, 28.3% of grassland area experienced degradation, which was mainly distributed in the southern of QTP. However, grassland NPP exhibited an overall increasing trend on IMP, and 94.2% of grassland experienced restoration. Climate change dominated the grassland restoration on the two plateaus, 84.4% and 72.8% of restored grassland was dominated by climate changes on IMP and QTP, respectively. Precipitation increase was the main climatic factor that induced grassland restoration. Irrational human activities were the dominant factor that leads to grassland degradation on the two plateaus. All of the grassland degradations on IMP were caused by irrational human activities; however, 72.9% and 27.1% of degraded grassland on QTP were due to irrational human activities and drying climate, respectively. The ecological restoration projects implementing promoted the grassland restoration on QTP and IMP, and 15.6% and 27.2% of restored grassland were dominated by human activities on IMP and QTP, respectively. The impact of climate changes on IMP was more favorable for grassland restoration than that on QTP, and the impact of human activities on the QTP grassland was greater than that on the IMP grassland. Thus, the government should continue to implement the ecological programs on the two plateaus and the grassland on QTP deserved more attention.

Acknowledgements

This study was supported by the Doctoral Fund of Shandong Agriculture and engineering University (NO. sgybsjj2020-05).

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

References

[1] Sha, Y., Shi, Z., Liu, X. and An, Z. (2015) Distinct Impacts of the Mongolian and Tibetan Plateaus on the Evolution of the East Asian Monsoon. Journal of Geophysical Research Atmospheres, 120, 4764-4782.
https://doi.org/10.1002/2014JD022880
[2] Duan, A. and Xiao, Z. (2015) Does the Climate Warming Hiatus Exist over the Tibetan Plateau? Scientific Reports, 5, Article No. 13711.
https://doi.org/10.1038/srep13711
[3] Tao, S., Fang, J., Zhao, X., Zhao, S., Shen, H., Hu, H., et al. (2015) Rapid Loss of Lakes on the Mongolian Plateau. Proceedings of the National Academy of Sciences of the United States of America, 112, 2281.
https://doi.org/10.1073/pnas.1411748112
[4] Zou, H., Li, H. and Hu, Q. (2020) Responses of Vegetation Greening and Land Surface Temperature Variations to Global Warming on the Qinghai-Tibetan Plateau 2001-2016. Ecological Indicators, 19, Article ID: 106867.
https://doi.org/10.1016/j.ecolind.2020.106867
[5] Zhang, Q., Wu, S., Zhao, D. and Dai, E. (2013) Temporal-Spatial Changes in Inner Mongolian Grassland Degradation during Past Three Decades. Agricultural Science & Technology, 14, 676-683.
[6] Wang, Z., Zhang, Y., Yang, Y., Zhou, W., Gang, C., Zhang, Y., et al. (2016) Quantitative Assess the Driving Forces on the Grassland Degradation in the Qinghai-Tibet Plateau, in China. Ecological Informatics, 33, 32-44.
https://doi.org/10.1016/j.ecoinf.2016.03.006
[7] Harris, R.B. (2010) Rangeland Degradation on the Qinghai-Tibetan Plateau: A Review of the Evidence of Its Magnitude and Causes. Journal of Arid Environments, 74, 1-12.
https://doi.org/10.1016/j.jaridenv.2009.06.014
[8] Cui, H., Wagg, C., Wang, X., Liu, Z., et al. (2022) The Loss of Above- and Belowground Biodiversity in Degraded Grasslands Drives the Decline of ecosystem multifunctionality. Applied Soil Ecology, 172, Article ID: s104370.
https://doi.org/10.1016/j.apsoil.2021.104370
[9] O’Mara, F.P. (2012) The Role of Grasslands in Food Security and Climate Change. Annals of Botany, 110, 1263-1270.
https://doi.org/10.1093/aob/mcs209
[10] Gieselman, T.M., Hodges, K.E. and Vellend, M. (2013) Human-Induced Edges Alter Grassland Community Composition. Biological Conservation, 158, 384-392.
https://doi.org/10.1016/j.biocon.2012.08.019
[11] Guidi, C., Magid, J., Rodeghiero, M., Gianelle, D. and Vesterdal, L. (2014) Effects of Forest Expansion on Mountain Grassland: Changes within Soil Organic Carbon Fractions. Plant and Soil, 385, 373-387.
https://doi.org/10.1007/s11104-014-2315-2
[12] Han, P., Zhao, X., Dong, Z., et al. (2022) A New Approach for the Classification of Grassland Utilization in Inner Mongolia—Based on Ecological Sites and State-and-Transition Models. Ecological Indicators, 137, Article ID: 108733.
https://doi.org/10.1016/j.ecolind.2022.108733
[13] Li, M., Li, X., Liu, S., Li, X., et al. (2021) Ecosystem Services under Different Grazing Intensities in Typical Grasslands in Inner Mongolia and Their Relationships. Global Ecology and Conservation, 26, e01526.
https://doi.org/10.1016/j.gecco.2021.e01526
[14] Chen, B., Zhang, X., Tao, J., Wu, J., Wang, J., Shi, P., et al. (2014) The Impact of Climate Change and Anthropogenic Activities on Alpine Grassland over the Qinghai-Tibet Plateau. Agricultural & Forest Meteorology, s189-s190, 11-18.
https://doi.org/10.1016/j.agrformet.2014.01.002
[15] Xu, H.J., Wang, X.P. and Zhang, X.X. (2016) Alpine Grasslands Response to Climatic Factors and Anthropogenic Activities on the Tibetan Plateau from 2000 to 2012. Ecological Engineering, 92, 251-259.
https://doi.org/10.1016/j.ecoleng.2016.04.005
[16] Pan, T., Zou, X., Liu, Y., Wu, S. and He, G. (2017) Contributions of Climatic and Non-Climatic Drivers to Grassland Variations on the Tibetan Plateau. Ecological Engineering, 108, 307-317.
https://doi.org/10.1016/j.ecoleng.2017.07.039
[17] Yan, H., Xue, Z. and Niu, Z. (2021) Ecological Restoration Policy Should Pay More Attention to the High Productivity Grasslands. Ecological Indicators, 129, Article ID: 107938.
https://doi.org/10.1016/j.ecolind.2021.107938
[18] Li, S., Verburg, P.H., Lv, S., Wu, J. and Li, X. (2012) Spatial Analysis of the Driving Factors of Grassland Degradation under Conditions of Climate Change and Intensive Use in Inner Mongolia, China. Regional Environmental Change, 12, 461-474.
https://doi.org/10.1007/s10113-011-0264-3
[19] Huang, L., Xiao, T., Zhao, Z., Sun, C., Liu, J., Shao, Q., et al. (2013) Effects of Grassland Restoration Programs on Ecosystems in Arid and Semiarid China. Journal of Environmental Management, 117, 268-275.
https://doi.org/10.1016/j.jenvman.2012.12.040
[20] Cai, H., Yang, X. and Xu, X. (2015) Human-Induced Grassland Degradation/Restoration in the Central Tibetan Plateau: The Effects of Ecological Protection and Restoration Projects. Ecological Engineering, 83, 112-119.
https://doi.org/10.1016/j.ecoleng.2015.06.031
[21] Han, F., Kang, S., Buyantuev, A., Zhang, Q., Niu, J., Yu, D., et al. (2016) Effects of Climate Change on Primary Production in the Inner Mongolia Plateau, China. International Journal of Remote Sensing, 37, 5551-5564.
https://doi.org/10.1080/01431161.2016.1230286
[22] Wang, Z., Deng, X., Song, W., Li, Z. and Chen, J. (2017) What Is the Main Cause of Grassland Degradation? A Case Study of Grassland Ecosystem Service in the Middle-South Inner Mongolia. Catena, 150, 100-107.
https://doi.org/10.1016/j.catena.2016.11.014
[23] Gang, C., Zhou, W., Chen, Y., Wang, Z., Sun, Z., Li, J., et al. (2014) Quantitative Assessment of the Contributions of Climate Change and Human Activities on Global Grassland Degradation. Environmental Earth Sciences, 72, 4273-4282.
https://doi.org/10.1007/s12665-014-3322-6
[24] Gang, C., Zhou, W., Wang, Z., Chen, Y., Li, J., Chen, J., et al. (2015) Comparative Assessment of Grassland NPP Dynamics in Response to Climate Change in China, North America, Europe and Australia from 1981 to 2010. Journal of Agronomy & Crop Science, 201, 57-68.
https://doi.org/10.1111/jac.12088
[25] Zhou, W., Gang, C., Zhou, F., Li, J., Dong, X. and Zhao, C. (2015) Quantitative Assessment of the Individual Contribution of Climate and Human Factors to Desertification in Northwest China Using Net Primary Productivity as an Indicator. Ecological Indicators, 48, 560-569.
https://doi.org/10.1016/j.ecolind.2014.08.043
[26] Yang, Y., Wang, Z., Li, J., Gang, C., Zhang, Y., Zhang, Y., et al. (2016) Comparative Assessment of Grassland Degradation Dynamics in Response to Climate Variation and Human Activities in China, Mongolia, Pakistan and Uzbekistan from 2000 to 2013. Journal of Arid Environments, 135, 164-172.
https://doi.org/10.1016/j.jaridenv.2016.09.004
[27] Piao, S. and Guo, Q. (2001) Application of CASA Model to the Estimation of Chinese Terrestrial Net primary Productivity. Acta Phytoecologica Sinica, 25, 603-608.
[28] Schimel, D.S. (1995) Terrestrial Biogeochemical Cycles: Global Estimates with Remote Sensing. Remote Sensing of Environment, 51, 49-56.
https://doi.org/10.1016/0034-4257(94)00064-T
[29] Prince, S.D. (1998) Evidence from Rain-Use Efficiencies Does Not Indicate Extensive Sahelian Desertification. Global Change Biology, 4, 359-374.
https://doi.org/10.1046/j.1365-2486.1998.00158.x
[30] Prince, S.D., Becker-Reshef, I. and Rishmawi, K. (2009) Detection and Mapping of Long-Term Land Degradation Using Local Net Production Scaling: Application to Zimbabwe. Remote Sensing of Environment, 113, 1046-1057.
https://doi.org/10.1016/j.rse.2009.01.016
[31] Zheng, Y.R., Xie, Z.X., Robert, C., Jiang, L.H. and Shimizu, H. (2006) Did Climate Drive Ecosystem Change and Induce Desertification in Otindag Sandy Land, China over the Past 40 Years? Journal of Arid Environments, 64, 523-541.
https://doi.org/10.1016/j.jaridenv.2005.06.007
[32] Wessels, K.J., Prince, S.D. and Reshef, I. (2008) Mapping Land Degradation by Comparison of Vegetation Production to Spatially Derived Estimates of Potential Production. Journal of Arid Environments, 72, 1940-1949.
https://doi.org/10.1016/j.jaridenv.2008.05.011
[33] Zare, A., Chemura, A., Gleixner, S., et al. (2021) Evaluating the Grassland NPP Dynamics in Response to Climate Change in Tanzania. Ecological Indicators, 125, Article ID: 107600.
https://doi.org/10.1016/j.ecolind.2021.107600
[34] Haberl, H. (1997) Human Appropriation of Net Primary Production as an Environmental Indicator: Implications for Sustainable Development. Ambio, 26, 143-146.
[35] Zika, M. and Erb, K.H. (2009) The Global Loss of Net Primary Production Resulting from Human-Induced Soil Degradation in Drylands. Ecological Economics, 69, 310-318.
https://doi.org/10.1016/j.ecolecon.2009.06.014
[36] Du, J., Wang, Y., et al. (2022) Climatic Resources Mediate the Shape and Strength of Grassland Productivity-Richness Relationships from Local to Regional Scales. Agriculture, Ecosystems & Environment, 330, Article ID: 107888.
https://doi.org/10.1016/j.agee.2022.107888
[37] Piao, S. and Xiao, Y. (2004) Spatial Distribution of Grassland Biomass in China. Acta Phytoecologica Sinica, 28, 491-498.
https://doi.org/10.17521/cjpe.2004.0067
[38] Potter, C.S., Randerson, J.T., Field, C.B., Matson, P.A., Vitousek, P.M., Mooney, H.A., et al. (1993) Terrestrial Ecosystem Production: A Process Model Based on Global Satellite and Surface Data. Global Biogeochemical Cycles, 7, 811-841.
https://doi.org/10.1029/93GB02725
[39] Field, C.B., Randerson, J.T. and Malmstroem, C.M. (1995) Global Net Primary Production: Combining Ecology and Remote Sensing. Remote Sensing of Environment, 51, 74-88.
https://doi.org/10.1016/0034-4257(94)00066-V
[40] Gao, Q., Yue, L., Wan, Y., Qin, X., Wangzha, J. and Liu, Y. (2009) Dynamics of Alpine Grassland NPP and Its Response to Climate Change in Northern Tibet. Climatic Change, 97, 515.
https://doi.org/10.1007/s10584-009-9617-z
[41] Zhu, W. (2005) Remote Sensing Estimation of Net Primary Productivity of Vegetation and Its Relationship with Climate Change in China’s Terrestrial Ecosystem. Beijing Normal University, Beijing.
[42] Zhou, G., Zheng, Y., Chen, S. and Luo, T. (1998) NPP Model of Natural Vegetation and Its Application in China. Scientia Silvae Sinicae, 34, 2-11.
[43] Xu, D.Y., Kang, X.W., Zhuang, D.F. and Pan, J.J. (2010) Multi-Scale Quantitative Assessment of the Relative Roles of Climate Change and Human Activities in Desertification—A Case Study of the Ordos Plateau, China. Journal of Arid Environments, 74, 498-507.
https://doi.org/10.1016/j.jaridenv.2009.09.030
[44] Zhou, W., Yang, H., Huang, L., Chen, C., Lin, X., Hu, Z., et al. (2017) Grassland Degradation Remote Sensing Monitoring and Driving Factors Quantitative Assessment in China from 1982 to 2010. Ecological Indicators, 83, 303-313.
https://doi.org/10.1016/j.ecolind.2017.08.019
[45] Parton, W.J., Scurlock, J.M.O., Ojima, D.S., Schimel, D.S., Hall, D.O. and Members, S.G. (1995) Impact of Climate Change on Grassland Production and Soil Carbon Worldwide. Global Change Biology, 1, 13-22.
https://doi.org/10.1111/j.1365-2486.1995.tb00002.x
[46] An, R., Zhang, C., Sun, M., et al. (2021) Monitoring Grassland Degradation and Restoration Using a Novel Climate Use Efficiency (NCUE) Index in the Tibetan Plateau, China. Ecological Indicators, 131, Article ID: 108208.
https://doi.org/10.1016/j.ecolind.2021.108208
[47] Qin, Y., Yi, S., Ren, S., Li, N. and Chen, J. (2014) Responses of Typical Grasslands in a Semi-Arid Basin on the Qinghai-Tibetan Plateau to Climate Change and Disturbances. Environmental Earth Sciences, 71, 1421-1431.
https://doi.org/10.1007/s12665-013-2547-0
[48] Fensholt, R., Horion, S., Tagesson, T., Ehammer, A., Grogan, K., Tian, F., et al. (2015) Assessing Drivers of Vegetation Changes in Drylands from Time Series of Earth Observation Data. Springer International Publishing, Berlin.
https://doi.org/10.1007/978-3-319-15967-6_9
[49] Piao, S., Tan, K., Nan, H., Ciais, P., Fang, J., Wang, T., et al. (2012) Impacts of Climate and CO2 Changes on the Vegetation Growth and Carbon Balance of Qinghai-Tibetan Grasslands over the Past Five Decades. Global & Planetary Change, 98-99, 73-80.
https://doi.org/10.1016/j.gloplacha.2012.08.009
[50] Ma, J., Ji, C., Han, M., Zhang, T., Yan, X., Hu, D., et al. (2012) Comparative Analyses of Leaf Anatomy of Dicotyledonous Species in Tibetan and Inner Mongolian Grasslands. Science China Life Sciences, 55, 68-79.
https://doi.org/10.1007/s11427-012-4268-0
[51] Han, G., Wang, Y. and Fang, S. (2011) Climate Change over the Qinghai-Tibet Plateau and Its Impacts on Local Agriculture and Animal Husbandry in the Last 50 Years. Resources Science, 33, 1969-1975.
[52] Wang, S., Li, R., Wu, Y. and Zhao, S. (2022) Effects of Multi-Temporal Scale Drought on Vegetation Dynamics in Inner Mongolia from 1982 to 2015, China. Ecological Indicators, 136, Article ID: 108666.
https://doi.org/10.1016/j.ecolind.2022.108666
[53] Liu, X., Ma, Z., Huang, X. and Li, L. (2020) How Does Grazing Exclusion Influence Plant Productivity and Community Structure in Alpine Grasslands of the Qinghai-Tibetan Plateau? Global Ecology and Conservation, 23, e01066.
https://doi.org/10.1016/j.gecco.2020.e01066
[54] Tong, C., Wu, J., Yong, S., Yang, J. and Yong, W. (2004) A Landscape-Scale Assessment of Steppe Degradation in the Xilin River Basin, Inner Mongolia, China. Journal of Arid Environments, 59, 133-149.
https://doi.org/10.1016/j.jaridenv.2004.01.004
[55] Li, W., Ali, S.H. and Zhang, Q. (2007) Property Rights and Grassland Degradation: A Study of the Xilingol Pasture, Inner Mongolia, China. Journal of Environmental Management, 85, 461-470.
https://doi.org/10.1016/j.jenvman.2006.10.010
[56] Li, M., Zhang, X., Wu, J., et al. (2021) Declining Human Activity Intensity on Alpine Grasslands of the Tibetan Plateau. Journal of Environmental Management, 296, Article ID: 113198.
https://doi.org/10.1016/j.jenvman.2021.113198
[57] Liu, L., Zhang, Y., Bai, W., Yan, J., Ding, M., Shen, Z., et al. (2006) Characteristics of Grassland Degradation and Driving Forces in the Source Region of the Yellow River from 1985 to 2000. Journal of Geographical Sciences, 16, 131-142.
https://doi.org/10.1007/s11442-006-0201-4
[58] Li, W. and Huntsinger, L. (2011) China’s Grassland Contract Policy and Its Impacts on Herder Ability to Benefit in Inner Mongolia: Tragic Feedbacks. Ecology & Society, 16, 1.
https://doi.org/10.5751/ES-03969-160201
[59] Liu, M., Dries, L., Heijman, W., Huang, J., Zhu, X., Hu, Y., et al. (2017) The Impact of Ecological Construction Programs on Grassland Conservation in Inner Mongolia, China. Land Degradation & Development, 29, 326-336.
https://doi.org/10.1002/ldr.2692

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