Analysis of Changes in Vegetation Carbon Storage and Net Primary Productivity as Influenced by Land-Cover Change in Inner Mongolia, China

Zhu, Lin; Shi, Mingming; Fan, Deng-Ping; Tu, Kun; Sun, Wanning

doi:10.3390/su15064735

Cited by 8 publications

(8 citation statements)

References 60 publications

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“…Overall, 10.6% of China's shrubland has increased in stability since 2001, which is mainly concentrated in the Inner Mongolia Plateau and the Loess Plateau region, and the possible reasons for this are twofold. One is that the implementation of ecological restoration projects and measures such as returning farmland to forests in the region in the past 20 years has improved the stability of local shrubland [64,65]. The second is the influence of changes in climate; in recent years, the climate of the Inner Mongolia Plateau and Loess Plateau has undergone certain changes, such as rising temperatures and increased precipitation, which has had a positive impact on the growth and stability of vegetation [66,67].…”

Section: Stability Patterns and Trendsmentioning

confidence: 99%

Temporal Variation and Factors Influencing the Stability of NPP in Chinese Shrubland Ecosystems

Li,

Hu,

et al. 2024

Forests

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Given the importance of net primary productivity (NPP) as an indicator of ecosystem productivity and its role in the global carbon cycle, understanding the factors that influence its stability can greatly improve our understanding of shrubland ecosystems and their response to global change. Between 2015 and 2022, we visited most of the primary shrubland in China and surveyed 751 shrubland patches. We collected data on community structure (canopy cover), shrub and herb species diversity, and soil physicochemical properties (soil nitrogen content and soil phosphorus content). We also used remote sensing data to obtain NPP from 2001 to 2022. We quantified temporal trends in shrubland stability in China and used structural equation modeling to disentangle the direct and indirect effects of climate, soil, and shrub community structural properties. We found that 85.3% of China’s shrublands remained stable in terms of productivity from 2001 to 2022, 10.6% of the shrublands increased in stability, and 4.1% of the shrublands need to be alerted to a significant decrease in stability. These changes in stability were mainly related to precipitation changes. We found that changes in precipitation directly affected the stability of net productivity and also indirectly through changes in shrub cover and species richness. Some aspects of community structure moderated these effects. We further found that the portion of shrubland with an upward trend in stability did not have a significant correlation between the stability of net primary productivity and community structure and soil N. Instead, soil phosphorus was the largest direct influence.

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Section: Stability Patterns and Trendsmentioning

confidence: 99%

Temporal Variation and Factors Influencing the Stability of NPP in Chinese Shrubland Ecosystems

Li,

Hu,

et al. 2024

Forests

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“…These factors gradually reduce water conservation at higher altitudes [17,44]. Previous studies have shown that forests provide more carbon storage than shrubs and grasses [45]. In ecologically sensitive high-altitude areas, it is important to protect natural grasslands.…”

Section: Impact Of the Altitude Gradient On Ecological Functionsmentioning

confidence: 99%

Trends in the Altitudinal Gradient Evolution of Vegetation Ecological Functions in Mountainous Areas

Niu,

Huang,

Zhang

et al. 2024

Forests

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Natural vegetation protects, maintains, and improves the environment through its ecological functions and is, thus, an important component of Earth’s ecosystems. The distribution of natural vegetation and its corresponding ecological roles vary with the topographic gradient. Understanding this role is essential for effective ecosystem management and conservation efforts. This study analyzes vegetation composition across altitude gradients and the spatiotemporal evolution of water conservation, soil conservation, and carbon storage in the southern hill and mountain belt of China. We then explored the drivers of the ecological functions of vegetation at different altitude gradients. The results showed that water conservation increased by 108.56%, soil conservation increased by 97.04%, and carbon storage increased only slightly. The ecological functions of vegetation varied across altitude gradients, with the 500–800 m gradient exhibiting markedly higher ecological functions than the other gradients. The effect of precipitation on soil conservation increases with altitude. In addition, at higher altitudes, evergreen coniferous forests had a greater effect on carbon storage. Based on the results, we propose vegetation management measures for different altitudes. This study provides a reference for decision-makers to develop and adjust ecological restoration programs in mountainous areas for the improvement of the local ecological environment.

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“…Currently, climate issues are becoming increasingly severe, and the impacts of global warming-induced extreme weather are already affecting people's lives [1][2][3][4]. Moreover, with the rapid pace of urbanization, phenomena such as population growth, anthropogenic heat emissions, and changes in land cover will lead to more pronounced urban heat island effects [5][6][7][8]. In summary, the current pressing climate and energy issues demand more environmentally friendly and efficient cooling methods [9,10].…”

Section: Introductionmentioning

confidence: 99%

A Study on the Radiation Cooling Characteristics of Cerambycini Latreille

Xu,

Liu

2024

Biomimetics

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The severe climate and energy issues require more environmentally friendly and efficient cooling methods. Radiative cooling offers a cooling solution with significant advantages. However, current radiative cooling technologies focus primarily on seeking perfect materials to achieve complete wavelength absorption. However, numerous research studies have shown that achieving such a perfect scenario is not feasible. Here, inspired by the surface of the Cerambycini Latreille, the inherent mechanism of radiative cooling functionality in the unique structure of these hairs is revealed using effective medium theory and Finite Difference Time Domain (FDTD) optical simulation analysis. Through alkaline etching and template methods, a biomimetic radiative cooling film (BRCF) was successfully fabricated. The BRCF not only efficiently reflects solar radiation but also enhances absorption in the atmospheric window wavelength range. The radiative cooling mechanism proposed in this study and the BRCF presented here may inspire researchers to further explore the field of structural radiative cooling.

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Analysis of Changes in Vegetation Carbon Storage and Net Primary Productivity as Influenced by Land-Cover Change in Inner Mongolia, China

Cited by 8 publications

References 60 publications

Temporal Variation and Factors Influencing the Stability of NPP in Chinese Shrubland Ecosystems

Temporal Variation and Factors Influencing the Stability of NPP in Chinese Shrubland Ecosystems

Trends in the Altitudinal Gradient Evolution of Vegetation Ecological Functions in Mountainous Areas

A Study on the Radiation Cooling Characteristics of Cerambycini Latreille

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