Table of Content

18 March 2025, Volume 36 Issue 3

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Special Features of Urban Climate and Urban Design (Special Feature Organizer: HE Baojie)

Review on research methods of the surface urban heat island effect based on CNKI bibliometrics

CHEN Cen, LIANG Dezhuang, YANG Jun, HAN Dongrui, QIAO Zhi

2025, 36(3):  647-658.  doi:10.13287/j.1001-9332.202503.029

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The urban heat island (UHI) effect is an increasingly prominent local climate issue in the process of global urbanization, significantly impacting human settlement health and energy consumption. Based on the China National Knowledge Infrastructure (CNKI) database, we searched and analyzed Chinese journal articles on the surface urban heat island (SUHI) effect published during 1980 and 2024. Using CiteSpace software, we conducted a visual analysis of publication trends and keywords to systematically summarize the research advances. We reviewed and discussed the research hotspots, including data sources, identification methods, and evaluation indicators related to the surface urban heat island effect. We also proposed the shortages and challenges in current research, such as identification accuracy, mechanism analysis, and impact assessment. More works should be strengthened in future research, including optimizing multi-source data integration with cross-validation, innovating multi-scale dynamic evaluation methods, and enriching multi-dimension impact assessment systems. By reviewing the development process of surface urban heat island effect research in China, we hoped to provide theoretical support and technical guidance for future research, contributing to the deepening and practical application of the research.

Relationship between urban form and surface temperature based on XGBoost SHAP interpretable machine learning model

TAN Jie, WEI Qianjun, LIAO Zhaoyang, KUANG Wenjun, DENG Huiting, YU De

2025, 36(3):  659-670.  doi:10.13287/j.1001-9332.202503.025

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With the increase of high-rise buildings in major cities worldwide, exploring the effects of urban two-dimensional (2D) and three-dimensional (3D) morphology on land surface temperature (LST) has become the key to mitigating the urban thermal environment and optimizing urban planning. Using the area within the Third Ring Road of Changsha as a case, we extracted 13 urban 2D/3D morphological factors based on 2020 multi-source remote sensing data. We used Pearson correlation analysis to examine the relationship between LST and each factor, and used the XGBoost model and SHAP method to reveal their nonlinear impacts and contributions. The results showed that in 2020, high-temperature regions mainly concentrated in the building-dense central area of Changsha, while low-temperature areas predominantly located in the forest parks in the western and northeastern parts of the city, as well as along the Xiangjiang River. The normalized difference building index (NDBI), nighttime lighting (NTL) and proportion of construction land (PCL) exhibited significant positive correlations with LST, with correlation coefficients of 0.592, 0.537 and 0.446, respectively, indicating that urbanization exacerbated surface warming. In contrast, the normalized difference vegetation index (NDVI) and the sky view coefficient (SVF) showed significant negative correlation with LST, with correlation coefficients of -0.316 and -0.200, respectively, reflecting the important role of green space and open space in mitigating the urban heat island effect. NDBI, NTL, NDVI, and elevation (DEM) had the greatest influence on LST, contributing 60.9% of the total variance. These 2D/3D morphological factors exhibited complex nonlinear effects on LST. NDBI had the most significant warming effect in the range from 0 to 0.2. The warming effect of NTL tended to saturate when its intensity exceeded 40. The cooling effect of NDVI became more pronounced as it surpassed 0.5. DEM values between 50 and 150 m produced the most signifi-cant cooling effect. This study validated the effectiveness of the XGBoost-SHAP model in uncovering the nonlinear mechanisms through which urban 2D/3D morphological factors influenced LST, offering scientific insights for urban heat management and the development of green, low-carbon, and livable urbanization.

Numerical modeling of the effects of motor vehicle lanes layout on the transport and dispersion of exhaust pollutants in urban street canyons

LIU Wen, HUANG Zhengdong, ZHAN Qingming, ZHANG Hong-liang, ZHAO Fuyun, GUO Renzhong

2025, 36(3):  671-681.  doi:10.13287/j.1001-9332.202503.023

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To reveal the impacts of motor vehicle lane layout on street-canyon air quality, we used computational fluid dynamics (CFD) numerical simulations to construct models for the transport and diffusion of traffic exhaust pollutants in urban street canyons under different lane layouts, and investigated the effects of the lane number and location on the distribution and diffusion of traffic exhaust pollutants in urban street canyons. The results showed that the number and location of motor vehicle lanes significantly affected the distribution and dispersion of pollutants in urban street canyons, but such impacts depended on the in-canyon airflow structure. Air quality within shallow street canyons was generally better than that of deep street canyons. Furthermore, air quality on the leeward side of shallow canyons was poorer than that on the windward side, whereas the spatial heterogeneity of air pollutant distribution in deep canyons differed due to the location of motor vehicle lanes. The configuration of motor vehicle lanes could change the spatial homogeneity of pollutant distribution within urban street canyons and promote the diffusion and removal of traffic exhaust pollutants, and consequently improve the in-canyon air quality. Controlling the number of lanes and placing them closer to the upstream building facilitated the improvement of air quality at the pedestrian level and on the windward side in shallow street canyons. Increasing the number of lanes and locating them nearer to the downstream building could reduce pedestrian-level air pollution risks at the leeward side in deep street canyons. Our findings could provide a scientific reference for numerical modeling of pollutant dispersion in street canyons and help develop urban design strategies for enhancing in-canyon air quality.

Comparison of carbon sequestration and cooling benefits of plants in different landscaped green sites based on GGE biplot

SI Mingqian, MU Yan

2025, 36(3):  682-692.  doi:10.13287/j.1001-9332.202503.021

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To understand the ecological adaptability of common garden plants, we analyzed the growth characteristics of 17 common garden plant species in the street green site and the campus green site. We measured microenvironmental characteristics, carbon sequestration, oxygen release, cooling and humidification of plants with the same diameter at breast height (herb was the height of the plant) in the two green sites. We used genotype main effect plus genotype-by-environment interaction biplot and Pearson correlation analysis to analyze the interaction between species identity and site type. The results showed that Sophora japonica, Ginkgo biloba, Prunus persica, Aesculus chinensis, Ligustrum × vicaryi, Berberis thunbergii, Ligustrum sinense and Sabina chinensis had significant differences in carbon sequestration and cooling benefits between the two site types. Under the same land area, S. chinensis showed the strongest carbon sequestration and cooling in the campus with the values of 33.79 g·m^-2·d^-1 and 2.30 ℃, respectively. Photinia × fraseri was the strongest species in the street, with values of 31.47 g·m^-2·d^-1 and 0.84 ℃, respectively. The average carbon sequestration and cooling capacity of plants was higher in the campus than in the street. Trees cooled and humidified better in the street. The microclimatic conditions of campus in the summer were more stable than the street, which was closer to the ideal environment for plant growth. To enhance the ecological function of the green sites in small- and medium-sized towns, we should select trees, shrubs and grasses with better carbon sequestration and cooling benefits, including S. japonica, Koelreuteria paniculata, Ligustrum lucidum, Prunus cerasifera, A. chinensis, Pinus bungeana, S. chinensis, L. sinense, Ligustrum × vicaryi, P. × fraseri and Ophiopogon japonicas.

Changes of remote sensing vegetation phenology in Beijing-Tianjin-Hebei region under the background of urbanization

HUA Yiwei, MENG Dan, HU Feifan, ZHAO Yue, ZHANG Congcong, LI Xiaojuan

2025, 36(3):  693-702.  doi:10.13287/j.1001-9332.202503.022

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Urban environments face numerous challenges, including an increase in impervious surfaces, intensification of heat island effect, and severe air pollution, which all affect urban vegetation phenology. We reconstructed the time series of MOD13Q1 enhanced vegetation index data for the Beijing-Tianjin-Hebei region during 2002-2021, extracted the vegetation phenology index based on the dynamic threshold method, and examined the dyna-mics of vegetation phenology under a urbanization gradient. The results showed that the start of growing season (SOS) occurred earlier in the southeastern region of Beijing-Tianjin-Hebei, the end of growing season (EOS) was later in the central and southwestern regions, and the growing season length (GSL) was extended in the central and southeastern regions. SOS had been advanced and EOS had been delayed in most areas of Beijing-Tianjin-Hebei, leading to a significant extension of the GSL. The phenological trends were generally consistent across different vegetation types, with specific manifestations varied. The advance in SOS was most pronounced in farmland. The delay in EOS was greatest in forests. The extension of GSL was most substantial in farmland. During 2002-2021, for every 10% increase in the proportion of impervious surface percentage (ISP), SOS advanced by 1.28 day, EOS was delayed by 1.33 day, and GSL was extended by 2.2 days. With increasing ISP, land surface temperature initially rose but stabilized once it exceeded 40%. As land surface temperature increased, SOS first advanced and then delayed (with an inflection point at 23 ℃), while EOS first delayed and then advanced (with an inflection point at 20 ℃). We speculated that the result was related to the coupling of light and temperature periods. The response degree of vegetation phenology under dynamic urbanization gradient showed significant differences. Surface temperature played an important role in driving the urban-rural phenological difference.

Original Articles

Effect of litters from Juglans mandshurica and Larix gmelinii on the growth of J. mandshurica seedlings

YANG Yibing, SHAN Chengfeng, SHEN Fangyuan, YANG Lixue

2025, 36(3):  703-710.  doi:10.13287/j.1001-9332.202503.002

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We conducted a pot experiment to examine the effects of different proportions (CK: no litter; H₁₀L₀: Juglans mandshurica 10 g; H₇L₃: J. mandshurica 7 g + Larix gmelinii 3 g; H₅L₅: J. mandshurica 5 g + L. gmelinii 5 g; H₃L₇: J. mandshurica 3 g + L. gmelinii 7 g; H₀L₁₀: L. gmelinii 10 g) of J. mandshurica and L. gmelinii litter on nutrients and phenols content in the substrate, and on the growth and physiological characteristics of J. mandshurica seedlings. The results showed that litter input significantly affected ammonium nitrogen, available phosphorus, and phenols contents in the substrate. The content of substrate nutrients (except available phosphorus) was the highest when J. mandshurica and L. gmelinii litter were mixed in equal proportion (H₅L₅). The total phenols and water-soluble phenols contents in the substrate decreased as the proportion of L. gmelinii litter increased, while those of H₀L₁₀ treatment were significantly reduced by 22.7% and 25.3%, respectively. The addition of L. gmelinii litter could effectively promote the growth of J. mandshurica seedlings. The synthetical allelopathic index (M_R) of H₃L₇ and H₀L₁₀ treatments was higher than that of H₁₀L₀ and H₇L₃ treatments, with the highest value under H₀L₁₀ treatment (M_R=-0.07). Litter inputs significantly increased net photosynthetic rate, stomatal conductance, intercellular CO₂ concentration, and transpiration rate of J. mandshurica seedlings. The content of malondialdehyde (MDA) was the highest and net photosynthesis rate was the lowest in CK. Seedlings under H₀L₁₀ treatment had the best growth, with the lowest MDA content, and the highest net photosynthesis rate, which significantly increased 101.6%. The addition of L. gmelinii litter could alleviate the autotoxicity of J. mandshurica seedlings and stimulate their growth. The high litter proportion of L. gmelinii promoted the growth and physiological characteristics of J. mandshurica seedlings.

Effects of resin-tapping on radial variation of sap flow density and whole tree transpiration in Pinus massoniana

QIN Jiashuang, NI Longkang, ZHENG Lu, TAN Yu, JIA Huilin, LIAO Suhui, GU Da-xing

2025, 36(3):  711-718.  doi:10.13287/j.1001-9332.202503.001

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We investigated the effects of resin-tapping on the radial differences of sap flow density and whole-tree transpiration in Pinus massoniana. We used the Granier's thermal diffusion probe method to measure sap flow density at different sapwood depths on non-resin-tapped P. massoniana and both the non-resin-tapped surface and resin-tapped surface of resin-tapped P. massoniana, that had undergone continuous resin tapping from 2004 to 2015. The results showed that the radial distribution patterns of sap flow density in the non-resin-tapped P. massoniana and on the non-resin-tapped surface of resin-tapped P. massoniana were unimodal, while that on the resin-tapped surface of resin-tapped P. massoniana was irregular. Resin-tapping altered the radial distribution pattern of sap flow density on the resin-tapped surface of resin-tapped P. massoniana. In addition, the sap flow density on the resin-tapped surface of P. massoniana was significantly lower than that on the non-resin-tapped surface, indicating that resin tapping reduced water transport capacity of the tapped surfaces. Except for the outer layer (0-2 cm), the density of sap flow on the non-resin-tapped surface was higher than that on the corresponding sapwood depth of the non-resin-tapped P. massoniana in other layers (2-10 cm), which would compensate the decreased water transport capacity of the resin-tapped surface. Furthermore, the whole-tree average daily sap flow density in resin-tapped P. massoniana (710.4 kg·m^-2·d^-1) was 82.9% of that in the non-resin-tapped P. massoniana (856.63 kg·m^-2·d^-1), indicating that the increase in sap flow density on the non-resin-tapped surface could not fully compensate for the decline in water transport capacity of the resin-tapped surface, resulting in a decrease in the overall water transport capacity of the resin-tapped P. massoniana. Moreover, the appearing time of whole-tree daily maximum sap flow density in resin-tapped P. massoniana occurred approximately 1 hour earlier than that of non-resin-tapped P. massoniana, indicating that the decrease in whole-tree water transport capacity caused by resin-tapping had led to moisture deficiency in resin-tapped P. massoniana. There was significant correlation between whole-tree sap flow density and sap flow density in various depths on the non-resin-tapped surface of resin-tapped P. massoniana and non-resin-tapped P. massoniana. By developing an estimation method for the average tree sap flow density based on the easily measurable surface sap flow density, we could obtain a more accurate assessment of overall tree transpiration.

Spatial point pattern of Artemisia ordosica shrubland on fixed sand dunes in the Mu Us Sandy Land, China

TANG Ruyun, ZHANG Dinghai, ZHAO Youyi, SHAN Lishan, YANG Qinghui, YANG Tian, LI Jiale, HUANG Wenqi

2025, 36(3):  719-728.  doi:10.13287/j.1001-9332.202503.003

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We investigated the mechanisms underlying the spatial point patterns of sand-fixing shrubs, including Artemisia ordosica and the coexisting shrubs Corethrodendron fruticosum var. mongolicum, Caragana korshinskii, and Corethrodendron scoparium in the Mu Us Sandy Land. The pair correlation functions g(r) and null models were used to analyze the spatial distribution patterns and correlations of A. ordosica at different growth stages, as well as the spatial dynamics of the three coexisting shrubs. The results showed that under the influence of seed dispersal limitation, A. ordosica and the three coexisting shrubs, predominantly exhibited a spatial pattern of small-scale aggregated and large-scale random distribution. Intraspecific associations of A. ordosica were largely positive or non-significant, primarily influenced by seed dispersal limitations. After excluding habitat heterogeneity, interspecific associations between A. ordosica and C. mongolicum, as well as between A. ordosica and C. korshinskii, displayed positive correlations at small scales (0-4 and 0-2 m) but no significant correlations at medium and large scales (3-20 and 2-11, 13-20 m). There was no significant correlation between A. ordosica and C. scoparium at small and medium scales (0-13 m), but negative correlation at large scales (13-20 m). The spatial associations between young A. ordosica and the three coexisting shrubs were weakest across different growth stages. In contrast, vegetative and reproductive individuals showed similar trends, with both displaying positive associations at small scales.

Effects of color temperature of visible light camera on vegetation index calculation in unmanned aerial vehicle vegetation remote sensing

XU Jing, YANG Long, WANG Junjian, SUN Zhongyu

2025, 36(3):  729-737.  doi:10.13287/j.1001-9332.202503.004

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Vegetation indices based on the spectral information of the RGB three-bands have been widely used in the field of unmanned aerial vehicles (UAVs) vegetation remote sensing. Affected by the automatic color temperature adjustment of cameras, the phenomena of color cast often occur when UAVs acquire RGB images. However, its impacts on the calculations of vegetation indices remain largely unknown. We analyzed the changing trends of 13 vegetation indices for non-vegetation objects, coniferous trees, broad-leaved trees and herbs under the color temperature gradient from 5000 K to 8000 K. The results showed that changes in color temperature significantly affected the calculation results of visible light vegetation indices. With increasing color temperature, the 13 vegetation indices exhibited five changing trends, namely rising, falling, unimodal, stable, and fluctuating. The trends of the normalized green-blue difference index, excess green index, the normalized green-red difference index, modified normalized green-red difference index, visible atmospherically resistant index, blue-green ratio vegetation index, blue-red ratio vegetation index, improved dual greenness index and greenness percentage index with the change in color temperature were affected by neither the object types nor the species. The trends of the triangular greenness index, green leaf index and red-green-blue vegetation index with change in color temperature were affected by both the object types and species identity. The trend of the normalized blue index with change in color temperature was affected by object types but not by species identity. The inter-specific differences within the same vegetation index could be amplified with the increase in color temperature. Weather conditions during image acquisition were a crucial factor influencing data quality. When utilizing vegetation indices calculated from UAV RGB imagery to interpret ecological patterns, strict quality control at the data collection process was necessary. Otherwise, the interpretability of vegetation indices would be weakened due to the impact of color temperature.

C:N:P stoichiometry and homeostasis in leaf, fine root, and soil of Schima superba under different stand ages

YAO Shushu, ZHONG Quanlin, CAI Shifeng, SU Sunqing, LIANG Fengna, XU Chaobin, CHENG Dongliang, CHEN Yuanwang, TANG Lei

2025, 36(3):  738-746.  doi:10.13287/j.1001-9332.202503.006

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To understand nutrient characteristics and stabilization mechanisms of Schima superba plantations with different stand ages, we took stands with five age classes (8, 13, 27, 36, and 54 a) in Youxi County, Fujian Province as the research objects, to explore the variations of carbon (C), nitrogen (N), and phosphorus (P) and their stoichiometric relationships in leaf, fine root, and soil. We further ananlyzed the coupling and homeostasis characteristics between the two components of leaf and fine root of S. superba and soil. The results showed that the C, N, and P contents in leaf and fine root showed a general trend of decreasing and then increasing with the increases of stand age. The minimum values of N (10.38 and 3.45 g·kg^-1) and P contents (0.44 and 0.21 g·kg^-1) of leaf and fine root appeared at the stand with age of 13 a. The C:N and C:P of those two components increased and then decreased with increasing stand age, and both of them reached their maximum values at 13 a. With the increase of stand age, soil C, N, and P contents of woodland showed a pattern of decreasing-increasing-decreasing. All of them were the lowest at 13 a, with 34.27, 1.82, and 0.11 g·kg^-1, respectively; while the maximum values of soil C:N, C:P, and N:P appeared at 13 a, with 19.2, 315.8, and 17.0, respectively. The N and P contents and their stoichiometric ratios of leaf and fine root had significant correlations with soil P content and but not with soil C and N contents. Steady-state model regressions of leaf and fine root C, N, and N:P were all non-significant with absolute stability; and N, P and their stoichiometric ratio of leaf were smaller than those of fine root, but P and C:P of leaf and fine root were more sensitive to change in soil P content. In summary, 13-a was the fast-growing period of S. superba. Soil P content significantly affected leaf and fine root N and P content of S. superba, with the leaf being more sensitive to the variations of soil P content. It was recommended that P fertilizer should be added at the appropriate time to improve soil fertility and focus on the changing of foliar N and P contents.

Seed yield and soil seed bank dynamics of Suaeda salsa population in the Yangtze Estuary, China

PENG Siying, YUAN Lin, CHU Xiangqian, LI Zhaohui, ZHANG Liquan

2025, 36(3):  747-754.  doi:10.13287/j.1001-9332.202503.009

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We examined plant density, seed production, spatial-temporal dynamics of soil seed bank, and seed dormancy and germination characteristics of Suaeda salsa populations along the gradient of tidal elevations in Chongming Dongtan of the Yangtze River Estuary. Suaeda salsa populations emerged after the control of Spartina alterniflora on the natural tidal flats. The results showed that elevation of tidal flats significantly influenced plant density and seed production of S. salsa. The highest plant density and seed production was observed at elevations ≥ 4.0 m, followed by the 3.8-4.0 m elevation range, and the lowest density and seed production occurred at the 3.6-3.8 m range. No individual of S. salsa was found at the elevations below 3.5 m. After seed maturation and dispersal in autumn, the density of soil seed bank initially increased and then sharply declined as seeds germinated into seedlings under favorable temperature and moisture conditions in spring. Soil seed bank density was significantly correlated with S. salsa population density. Seeds could gradually disperse toward the population front through the tidal and wind-driven forces. The results of seed storage, dormancy and germination experiments showed that seeds of S. salsa matured in the autumn with a non-deep physiological dormancy state, with a germination rate of 14.6%. After a cold stratification treatment in laboratory and storage in the field condition during winter, the germination rate could increase to 68%-82%. After dispersed into soil seed bank and winter vernalization in the field, seeds entered an enforced dormancy. When temperature and moisture conditions became suitable in spring, the seeds could germinate quickly. If the seeds experienced environmental stresses and failed to germinate in spring, they could re-enter into induced dormancy under summer high temperature. Seeds in an induced dormancy state required another process of vernalization to break the induced dormancy and could germinate under suitable conditions. The seeds of S. salsa could survive for many years after entering into the induced dormancy, which belongs to a persistent seed bank.

Decomposition characteristics of litter from four plant species in a light-limited aquatic environment of south China

HUANG Zirong, LI Lisha, YANG Gairen, TAN Jiahao, HUANG Yu

2025, 36(3):  755-761.  doi:10.13287/j.1001-9332.202503.007

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The shading of revetment trees and lake herbaceous plants has formed a unique environment of light limi-ting in some water areas of southern lakes. We conducted laboraoty decomposition experiments to analyze the resi-dual amount of decomposition substrates, lignin and cellulose content during the decomposition of fallen leaves of woody plants (Osmanthus fragrans and Ficus microcarpa) and herbaceous plants (Canna glauca and Myriophyllum verticillatum). The aim was to explore the decomposition of fallen leaves and the degradation of lignin and cellulose of woody and herbaceous plants. The results showed that after 140 days of decomposition, the mass loss rates of O. fragrans, F. microcarpa, C. glauca, and M. verticillatum were 46.0%, 42.3%, 74.4%, and 68.6%, respectively. The decomposition rate of woody plants was significantly lower than herbaceous plants. In the early stage of decomposition (0-7 days), the mass loss rate and decomposition rate (k) were the highest throughout the entire experiment for all the four species. The cellulose of the four plants showed a state of high degradation, and the lignin degradation rates of O. fragrans (42.9%) and F. microcarpa (38.9%) were significantly higher than herbaceous plants. The lignin degradation rate of O. fragrans was significantly positively correlated with k value, while the lignin and cellulose degradation rates of F. microcarpa and herbaceous plants were not significantly correlated with k value, indicating that lignin degradation might be a key factor affecting the decomposition of woody plants in shaded water environments and regulating carbon cycling in shaded lakes.

Variation of leaf functional traits and adaptive strategies of dominant woody species in rocky desertification habitats in karst area

LI Mengni, JIANG Yongjun, CHENG Yurui, WU Ze, HE Qiufang, LI Jiabin, ZHAO Chunfeng, QIAN Feng

2025, 36(3):  762-770.  doi:10.13287/j.1001-9332.202503.008

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To clarify the response of leaf functional traits of dominant woody plants in karst areas to variations of soil characteristics across different rocky desertification habitats, we used the method of substituting space for time to examine the characteristics and variation of nine leaf functional traits of five dominant tree species and three domi-nant shrub species in typical primary forest (the early stage of rocky desertification with extremely weak rocky desertification characteristics), secondary forest habitat (the middle stage of rocky desertification with weak rocky desertification characteristics), and rocky desertification habitat (the late stage of rocky desertification with high rocky desertification characteristics), and analyzed the adaptation strategies of those species to habitat change. The results showed that compared with the primary forest habitat, soil water content in the rocky desertification habitat decreased significantly by 60.4%, and soil carbon and nitrogen contents, C:N, and N:P decreased significantly by 72.8%, 35.8%, 55.1% and 56.7%, respectively. Across the three habitats, leaf water content and specific leaf area of dominant tree species were lower than those of shrub species, while leaf dry matter content and leaf carbon content were higher. Among these traits, the variation of specific leaf area was the largest, and that of leaf carbon content was the smallest. The overall variations of leaf traits of shrubs were higher than that of tree species. There were general correlations among leaf traits. The specific leaf area and leaf water content were significantly negatively correlated with leaf dry matter content. Soil water content accounted for 48.6% of the variation in leaf traits, being the main soil factor affecting the variation of karst dominant woody plants. In the dry and barren rocky desertification habitat, leaves presented a combination of high leaf water content, high specific leaf area, low leaf thickness, low leaf dry matter content, low leaf carbon content and low leaf N:P. They adopted a “fast investment-benefit” resource acquisition strategy. In contrast, the combination of leaf traits in the relatively humid and nutrient-rich primary forest habitat was opposite to that in the rocky desertification habitat, adopting a “slow investment-benefit” resource conservative strategy.

Status and potential of carbon sequestration of larch plantations in Liaoning Province, China

ZHANG Yansong, XIA Mian, ZHOU Wangming, ZHOU Li, WU Zhichao, DING Lei, YONG Huanying, YU Dapao

2025, 36(3):  771-779.  doi:10.13287/j.1001-9332.202503.005

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We analyzed the carbon sink status of different management modes of larch plantations in Liaoning Pro-vince using data from a second-class survey, and predicted the dynamics of carbon sink under different management modes by using tree ring data from sample plots. The main aim was to provide technical support for improving carbon sequestration capacity of larch plantations. The results showed that the maximum carbon densities of larch and Korean pine plantations were 70.24 and 63.33 t·hm^-2, respectively. The carbon sequestration potential of current plantations was 11.66 Tg. With the cycle of forest management, carbon sequestration rates of larch (40 years) and Korean pine (80 years) plantations were 1.62 and 0.66 t·hm^-2·a^-1, respectively. The carbon maturity age of larch plantations was 22 years, and stopping the rotation at this age could increase carbon sequestration by 43.8%. Under the larch-Korean pine multi-storied forest model, it was best to plant Korean pine seedlings in 30-year-old larch plantations, and to remove larch trees between 45- and 50-year-old larch plantations. Compared to the larch continuous cropping model, it reduced accumulated stand carbon sink by 36.4% and increased stand carbon density by 18.1%. Under the larch-Korean pine-Fraxinus mandshurica multi-storied forest model, it was best to plant F. mandshurica seedlings in 60-year-old Korean pine plantations, and to selecting cut Korean pine trees in 130-year-old. It increased accumulated stand carbon sink by 2.6% than larch continuous cropping and by 28.1% than Korean pine continuous cropping, and increased stand mean carbon density by 12.6% than Korean pine continuous cropping. The multi-storied forest model could reduce soil carbon loss and maintain arbor and soil carbon sinks. Inducing larch plantations into Korean pine-broadleaf mixed forests would facilitate stand carbon density and carbon sink.

Effect of exogenous growth regulators on physiological characteristics of cold resistance of Rhizophora stylosa seedling with different ages under low temperature stress

OUYANG Zilong, JIA Xianglu, TENG Weichao, SHI Jingzhong, LIU Xiu

2025, 36(3):  780-790.  doi:10.13287/j.1001-9332.202503.012

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Low-temperature stress is a critical abiotic stress limiting the regional distribution, ecological community patterns, and cultivation industry of Rhizophora stylosa. To assess the role of plant growth regulators in enhancing the cold resistance and recovery of R. stylosa seedlings under low-temperature stress and rewarming conditions, we evaluated the physiological responses of 1-year and 2-year old R. stylosa seedlings to low-temperature stress (day 10 ℃/night 5 ℃) and subsequent rewarming (day 30 ℃/night 20 ℃) in a climate chamber. Seedlings were treated with four types of plant growth regulators: 6-benzylpurine (6-BA, 50, 100, and 150 mg·L^-1), naphthaleneacetic acid (NAA, 50, 100, and 150 mg·L^-1), gibberellin (GA₃, 100, 200, and 400 mg·L^-1), and auxin (IAA, 100, 200, and 400 mg·L^-1), with water as the control (CK). We analyzed the changes in antioxidant enzyme activities, osmotic adjustment substances, and malondialdehyde (MDA) content in the leaves. The results showed that low-temperature stress disrupted physiological homeostasis, and increased MDA content by 40.0% and 37.8% in 1- and 2-year old seedlings, respectively. Application of growth regulators significantly enhanced the activities of antioxidant enzymes (superoxide dismutase, peroxidase, catalase, and ascorbate peroxidase) and the soluble protein and soluble sugar content while reduced MDA content. The maximum reduction in MDA content was 35.1% and 42.5% in 1-year-old seedlings and 37.5% and 34.8% in 2-year-old seedlings during stress and rewarming, respectively, indicating improved resistance and recovery. The 2-year-old seedlings had stronger adaptability to low-temperature compared to the 1-year-old seedlings. GA₃(100 and 200 mg·L^-1), IAA (150 mg·L^-1), 6-BA (400 mg·L^-1), and NAA (50 mg·L^-1) were most effective in mitigating low-temperature stress and promoting recovery in R. stylosa seedlings. These findings offered insights to enhance the cold resistance and resilience of R. stylosa under climate-induced abiotic stress.

Comparison on biological communities between karst and non-karst forests in Yachang, Guangxi

JIANG Chaoyou, LI Fuqi, LI Mengli, MENG Fengqun

2025, 36(3):  791-801.  doi:10.13287/j.1001-9332.202503.033

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We investigated the communities of woody plants, ground-dwelling insects, soil bacteria, and soil fungi in both karst and non-karst forests within the Yachang Orchids Natural Reserve, Guangxi, to explore the role of plant communities, stand structure, soil and litter properties in driving the differences in biological community composition. The results revealed that species richness, Shannon index, and Simpson index of plants were significantly higher in karst forest than non-karst forest. There were no significant differences in the species richness or Shannon index of ground-dwelling insects, bacteria, and fungi between the two forest types. However, the Simpson index for ground-dwelling insects and bacteria was significantly lower in karst forest, while the Simpson index for fungi was significantly higher. Community composition of the four biological groups differed significantly between karst and non-karst forests. The difference in plant community composition was primarily driven by soil pH (explaining 24.0% of the variation) and total soil carbon content (19.8%), with most plant species contributing to the dissimilarity. The difference in community composition of ground-dwelling insects was mainly driven by plant community composition (30.3%), understory tree density (13.8%), litter total phosphorus content (29.9%), and soil temperature (7.1%). The dissimilarity in ground-dwelling insect community was largely attributed to the differences in the abundances of Nitidulidae, Blattellidae, Gryllidae, Scarabaeidae, and Pycnoscelidae. The difference in bacteria community composition was primarily driven by soil temperature (39.5%) and pH (10.3%), with an unclassified family 1 of Acidobacteria and Pyrinomonadaceae being the key family contributing to the dissimilarity. The difference in fungal community composition was mainly influenced by plant community composition (21.2%), soil temperature (7.6%), and litter total phosphorus content (7.2%), with Russulaceae being the key family contributing to the dissimilarity. Our results suggested that the alkaline soils in karst forests support higher plant diversity, which offsets the negative effects of exposed rock and low soil temperature, thereby maintaining the diversity of other biological groups.

Effects of exogenous strigolactones on growth and physiological characteristics of two Primulina species under drought stress

CHANG Dan, HUANG Yanhui, TIAN Min, CAI Yanfei, MENG Jing

2025, 36(3):  802-810.  doi:10.13287/j.1001-9332.202503.013

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To investigate the role of strigolactones (SLs) in alleviating the impacts of drought stress on Primulina, we examined the effects of drought and exogenous SLs analogue GR24 (20 μmol·L^-1) on the growth of two Primulina species, P. hiemalis and P. longii, with PEG-6000 (PEG-6000=20%) to simulate drought stress. The results showed that spraying GR24 effectively alleviated the wilting and yellowing degree of leaves in both species, and effectively promoted root growth. Root vitality and total length of new roots of P. hiemalis was significantly increased by 12.1% and 26.2%, respectively. Leaf photosynthetic capacity was improved, which effectively alleviated the inhibitory effect of drought on photosynthesis. The total chlorophyll content, intercellular CO₂ concentration, and net photosynthetic rate of leaves of P. hiemalis were significantly increased by 5.9%, 1.5%, and 27.5%, respectively, while the intercellular CO₂ concentration of P. longii was significantly increased by 2.5%. The activity of antioxidant enzyme was significantly increased in the leaves and roots of both species, among which the activities of superoxide dismutase, peroxidase, and catalase in the leaves and the activities of superoxide dismutase and catalase in the roots of P. hiemalis and P. longii were significantly increased by 50.3%, 22.3%, 31.2%, 67.7%, 12.5%, and 51.2%, 29.0%, 11.1%, 27.6%, 18.2%, respectively. The degree of peroxidation was effectively reduced, and the content of malondialdehyde in leaves of P. hiemalis and P. longii was significantly reduced by 10.0% and 16.6%, respectively. In all, drought stress significantly inhibited the growth of Primulina, and the external application of SLs could significantly alleviate the damage of drought stress on Primulina plants.

Long-term impacts of Cervus nippon on plant community and soil organic carbon accumulation

YANG Manting, ZHENG Meiyang, LIN Song, DU Fangfang, ZHANG Feng, TONG Genping, FU Weijun

2025, 36(3):  811-818.  doi:10.13287/j.1001-9332.202503.014

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Large animal activities directly affect forest ecosystems. To understand the impact of Cervus nippon activi-ties on the ecosystem function of the reserve, we investigated the interrelationships among plant community structure, soil physico-chemical properties, and soil organic carbon stocks (SCS) under the interference of C. nippon in a mixed conifer-broadleaved forest located in Qianqingtang of Zhejiang Qingliangfeng National Nature Reserve, Zhejiang Province. The results showed that the aboveground biomass of understory decreased with increasing duration (10, 15 and 20 years) of C. nippon captivity, with significantly higher biomass in the forbidden area than each captive area. Plant communities in the captive areas were simpler and more homogeneous than the forbidden area. SCS and organic carbon content in the C. nippon captive area were 10.6%-54.3% and 22.7%-64.5% lower, respectively, than those in the forbidden area. SCS decreased with increasing years of C. nippon disturbance. Additionally, aboveground biomass and its importance values were positively correlated with SCS. Plant factors demonstrated significant direct positive effects on soil nutrients (total potassium and available nitrogen) and SCS, with effect values of 0.818 and 1.076, respectively. The years of C. nippon captivity showed a significant indirect negative effect on SCS (-1.207), a highly significant direct positive effect on soil bulk density (0.926), and a markedly significant direct negative effect on plant factors (-1.069). In summary, the long-term disturbance of C. nippon within a limited range may reduce soil nutrients and SCS in the surface soil by destroying plant community and altering soil structure. Therefore, it was recommended to reconsider and expand the scope of protection for C. nippon to foster the harmonious development of both forests and wildlife.

Effects of different earthworm densities on stability and organic carbon of soil aggregates in a Moso bamboo forest

QIU Yufeng, TANG Ronggui, SHEN Yuye, CHEN Youchao, LIU Yihong, CAI Yanjiang

2025, 36(3):  819-827.  doi:10.13287/j.1001-9332.202503.016

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Earthworms play a crucial role in regulating soil aggregates and soil organic carbon content. However, the effects of earthworm density on the composition, stability, and organic carbon of various soil aggregate fractions in Moso bamboo (Phyllostachys edulis) forest remain poorly understood. We conducted a 180-day in situ experiment to investigate the effects of different earthworm densities on composition, stability, organic carbon content of soil aggregates in a Moso bamboo forest. There were three treatments, including control (CK, no earthworm), local earthworm density (OE, 8 earthworms added in 50 cm×50 cm×40 cm), and double earthworm density (DE, 16 earthworms added in 50 cm×50 cm×40 cm). Compared to CK, the OE and DE treatments significantly increased the proportion of water-stable large macroaggregates (>2 mm) by 62.8% and 35.1%, respectively. Earthworm density improved soil aggregate stability, with stronger impacts of DE treatment than the OE treatment. Both OE and DE treatments increased organic carbon content across all soil aggregate fractions, with the organic carbon contents in bulk soil rising by 19.1% and 24.0%, respectively. Organic carbon contents in bulk soil were significantly correlated with the composition, stability, and organic carbon content of soil aggregates. Results of random forest analysis showed that organic carbon content in the bulk soil under the OE treatment was more strongly influenced by the organic carbon content in various soil aggregate fractions, whereas it was more strongly influenced by aggregate stabi-lity under the DE treatment. In conclusion, earthworms improved soil aggregate properties, thereby increasing organic carbon content in bulk soil, as indicated by the fact that higher earthworm densities promoted the formation of more aggregate organic carbon and enhanced soil aggregate stability.

Carbon sink capacity and climate impact assessment of terrestrial ecosystems in Heilongjiang Province

YU Min, JIA Xiaolong, BO Yu, CHENG Chunxiang, RUAN Duo, QIN Yun, WANG Ying

2025, 36(3):  828-836.  doi:10.13287/j.1001-9332.202503.030

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Terrestrial ecosystems in Heilongjiang Province have strong carbon sequestration capacity but vulnerable to climate change. Analyzing the spatio-temporal variations of carbon budget of terrestrial ecosystems in this region and the impacts of climate change is of great significance for improving ecosystem carbon sequestration in Heilongjiang Province. Based on 1961-2022 climate data and leaf area index data, we adopted the ecosystem carbon cycle BEPS model to quantitatively simulate the net primary productivity (NPP) and net ecosystem productivity (NEP) of terrestrial ecosystems in Heilongjiang Province, and assessed the climate impact. The results showed that the BEPS model could simulate carbon sequestration capacity of Heilongjiang Province. From 1961 to 2022, ecosystem carbon sequestration capacity in the study area increased. NPP increased by 1.5 g C·m^-2·a^-1 on average, and the increase trend was more significant after 2010 with an annual rate of 7.5 g C·m^-2. Forest carbon sequestration capacity was the strongest, and the increment of carbon sequestration capacity of farmland ecosystem was the most significant. In the context of climate warming, the minimum temperature, precipitation, and wind speed significantly affected carbon sequestration capacity, with precipitation being the most important factor. During the study period, the correlation coefficient between precipitation and carbon sequestration in Heilongjiang Province increased overall, and the relative contribution rate was the highest, accounting for 46.1%. The relative contribution rate of precipitation to vegetation NEP was 67.1%.

Multifunctionality of urban forest landscapes and their trade-offs and synergies

GUO Yujie, REN Zhi-bin, HE Xingyuan

2025, 36(3):  837-846.  doi:10.13287/j.1001-9332.202503.027

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The assessment of the multifunctionality of urban forest landscapes is crucial for decision-making regar-ding landscaple allocation, optimization, and planning. Due to the high fragmentation and heterogeneity, it is a great challenge to scientifically evaluate the multifunctionality of urban forests and trade-offs/synergies. With Changchun City as the study area, we used plot surveys and remote sensing data to construct a model for estimating urban forest ecological functions. A multifunctional evaluation framework was proposed, which comprehensively considered both the quality and quantity of functions to quantitatively characterize the spatial patterns of multifunctionality and their trade-offs/synergies. The results showed that the annual carbon sequestration of urban forests in Changchun's built-up areas reached 36.78 t, with an average cooling effect of 0.96 ℃, an annual removal of PM_2.5 reaching 527.52 t, and a recreational capacity of 50.08 people·m^-2. Compared to the downtown, the suburban forests were stronger in carbon sequestration, air purification, and recreational functions, displaying a spatial distribution pattern that was lower in the interior and higher along the periphery. There was a significant trade-off between recreational functions and carbon sequestration and cooling functions, while carbon sequestration showed strong synergies with air purification and cooling functions. As urbanization varied, the trade-offs/synergies among functions displayed spatial heterogeneity, with carbon sequestration and cooling functions showing synergies in the city center and weak trade-offs in the suburbs. The multifunctionality of urban forest landscapes in Changchun performed optimally when the threshold was 25%, with high-value areas concentrated in the city's outer ring, exhibiting a stronger west and weaker east pattern. The multifunctionality generally increased from the 1^st ring road (1.61) to the 5^th ring road (2.01). Our results provide a scientific foundation for the planning and management of urban forest landscapes in Changchun, contribute to the optimization of urban forest multifunctionality, and promote sustainable urban development.

Spatial distribution of soil organic carbon components in mainland of China and their response to climate change

SHAN Yaru, TIAN Jiahe, FAN Xiuwen, LIU Lei

2025, 36(3):  847-858.  doi:10.13287/j.1001-9332.202503.019

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Preserving and increasing soil organic carbon pool is an effective natural way to mitigate climate change. However, the sensitivity of soil organic carbon to climate change in different ecosystems in mainland of China is still unclear. To investigate the response of soil organic carbon to climate change, it is important to classify it into particulate (POC) and mineral-associated organic carbon (MAOC) components. In this study, we assessed the spatial distributions of POC and MAOC in mainland of China and simulated their responses to future climate change using machine learning methods. The results showed that: 1) the stocks of soil organic carbon, POC, and MAOC in the top 20 cm soils of mainland China were 45.3, 20.7, and 24.6 Pg, respectively. 2) Soil organic carbon components were positively correlated with altitude and negatively correlated with air temperature. 3) Under the SSP585 scenario, the stocks of POC and MAOC in China would decrease by 4.80 and 2.13 Pg, from 2020 to 2100, respectively. The contents of soil organic carbon components were higher in Northeast China and Qinghai-Tibet Plateau, but lower in the Inner Mongolia Plateau, Sichuan Basin, North China, and Northwest China Plain. The sensitivity of POC to climate change was higher than MAOC. Climate warming would cause the greatest loss of soil organic carbon in the meadow ecosystem.

Isotope characteristics of precipitation and identification of water vapor sources in the northern Greater Khingan Mountains, Inner Mongolia

LYU Chenge, JIA Debin, HAO Yusheng, SHANG Ziqin, GUO Shaofeng, XIE Guoying

2025, 36(3):  859-867.  doi:10.13287/j.1001-9332.202503.015

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We investigated the water cycle and water vapor sources of precipitation in the northern Greater Khingan Mountains in Inner Mongolia, by collecting precipitation samples from June 2022 to May 2024 at the Inner Mongolia National Ecosystem Observation and Research Station. We analyzed the isotopic characteristics of precipitation and the influencing environmental factors by the backward trajectory model, potential source contribution analysis, and concentration weighted trajectory analysis, and explored water vapor sources and the potential evaporation source areas across different seasons. The results indicated that the isotopic composition of precipitation showed significant seasonal variation, with enrichment in the warm season and depletion in the cold season. The slope of the local meteoric water line (7.82) was lower than that of the global meteoric water line, and that of the shelterwood forest (6.57) was lower than the primary forest (7.39), suggesting precipitation in the shelterwood forest was more significantly influenced by secondary evaporation. During the research period and in the cold season, the temperature effect in precipitation was significant, with correlation coefficients of 0.85 and 0.94, while the effect of precipitation amount was not significant. In the warm season, water vapor sources of precipitation primarily originated from the westerly winds (48.9%) and terrestrial evaporation (31.9%), and it predominantly came from westerly winds (66.9%) and Arctic Ocean moisture (42.9%) in the cold season. The potential evaporation source regions during the warm season were mainly located in the northwest, north, and southeast of the study area, while in the cold season, they concentrated in the northwest and north.

Differences in soil aggregates characteristics and soil detachment rate in degraded red soil among different vegetation restoration modes

ZHOU Shiqi, WU Jieling, WU Zehua, LIN Qiang, XI Jie, ZHOU Qin, ZHA Xuan

2025, 36(3):  868-876.  doi:10.13287/j.1001-9332.202503.011

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Soil aggregate traits and anti-erosion ability vary across different vegetation restoration modes. However, it remained unclear how vegetation restoration modes affect soil aggregate characteristics and soil detachment rate. We examined the variations in soil aggregate and soil detachment rate as well as the influencing factors in the low growth efficiency Pinus massoniana forests of Changting County, Fujian Province under five restoration modes, i.e, closure management (M₁), geomantic forest (M₂), planting grass on the whole slope (M₃), low growth efficiency forest transformation (M₄), and the strip grass-shrub belt mode (M₅), with the eroded bare land as the control (CK). The results showed that: 1) Soil detachment rate was significantly decreased by 84.7% to 98.6% under all vegetation restoration modes, while soil organic matter content was significantly increased by 140.2% to 869.4%. 2) The aggregate stability in M₁ was the lowest among the five vegetation restoration modes, and water stable macroaggregates (WR_0.25), mean weight diameter (MWD), geometric mean diameter (GMD) were significantly lower in M₁ mode than those in M₂, M₃, and M₅, while the fractal dimension (D) and the water-stable aggregate destruction rate (PAD) were significantly higher than the M₂, M₃, and M₅. Soil detachment rate of M₅ was 1.4% of CK, with the highest soil aggregate stability. The WR_0.25, MWD, and GMD in M₅ were significantly higher, while D was significantly lower than that in other modes. 3) Soil organic matter content was closely related with aggregate stability. Soil organic matter content had a positive correlation with WR_0.25, MWD, and GMD, but a negative correlation with D and PAD. 4) Soil detachment rate declined exponentially with the increases of WR_0.25. In summary, the increases in soil organic matter content induced by vegetation restoration played a key role in the formation of water-stable macroaggregates and the reduction in soil detachment rate. We recommend the strip grass-shrub belt mode for vegetation restoration in the red soil regions of southern China.

Current status and evaluation of nutrient inputs in wolfberry orchards of different ages in Gansu, China

LU Yongli, HAN Lu, GUO Hao, ZHANG Qiang, ZHOU Peng, LUO Zhuzhu, ZHENG Jie

2025, 36(3):  877-884.  doi:10.13287/j.1001-9332.202503.018

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The wolfberry industry has become a characteristic pillar industry that promotes the rural economic development in many areas in Gansu Province. There are many problems in wolfberry orchards, such as unbalanced nutrient input, extensive management, low utilization rate, and high loss rate, which limit the high-quality, sustainable, and healthy development of the wolfberry industry. We investigated fertilization status and nutrient management problems of wolfberry orchards with different tree ages in Wuhe Town, Jingyuan County, Gansu Province. We put forward regulatory measures and suggestions for the optimized nutrient management of wolfberry orchards. The results showed that nutrient input of wolfberry orchards was generally dominated by chemical fertilizers (with an average of 72.6%). Nutrient input of organic fertilizers was insufficient (with an average of 21.3%). The problem was most prominent in old-aged wolfberry orchards, where the proportion of chemical fertilizer in the total nutrient input was as high as 81.1%, and the proportion of orchards with insufficient organic fertilizer nutrient input accounted for 94.1%. The optimized fertilization amounts for wolfberry orchards were N 244-361 kg·hm^-2, P₂O₅ 209-271 kg·hm^-2, K₂O 121-157 kg·hm^-2, and organic fertilizer 6-10 t·hm^-2 for young-aged orchards (≤4 years); N 354-446 kg·hm^-2, P₂O₅ 262-330 kg·hm^-2, K₂O 175-221 kg·hm^-2, and organic fertilizer 10-22.5 t·hm^-2 for middle-aged orchards (5-7 years); and N 222-265 kg·hm^-2, P₂O₅ 385-460 kg·hm^-2, K₂O 488-583 kg·hm^-2, and organic fertilizer 22.5-24 t·hm^-2 for old-aged orchards (≥8 years). Common problems in the chemical fertilizer input of wolfberry orchards include high phosphorus fertilizer input, and both insufficient and excessive application of nitrogen and potassium fertilizers. In young-aged orchards, the proportion of high nitrogen input accounted for 66.7%, the proportion of high phosphorus input accounted for 61.7%, and the proportion of high potassium input was 75.1%. In middle-aged orchards, the proportion of both high and low nitrogen input was about 40.0%, the proportion of high phosphorus input accounted for 68.4%, and the proportion of both low and high potassium input was about 41.5%. In old-aged orchards, the proportion of low nitrogen input accounted for 53.0%, the proportion of excessive phosphorus input accounted for 44.1%, and the proportion of excessive potassium input was 50.0%. In the study area, the input of organic fertilizers should be substantially increased, the amount of phosphorus fertilizers should be reduced, and the application ratios of nitrogen, phosphorus, and potassium in chemical fertilizers should be optimized. Such strategies would improve nutrient utilization rate, reduce nutrient losses and potential environmental pollution risks, and promote the sustainable and healthy development of wolfberry industry.

Evolution characteristics and influencing factors of water footprint of food crop production in the middle and lower reaches of the Yangtze River during 1989-2018

MENG Qinghao, ZHANG Ying, RU Yan, SHI Junyao, HE Feng, ZHANG Nan, LIU Lijun, ZHANG Hao

2025, 36(3):  885-894.  doi:10.13287/j.1001-9332.202503.026

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The middle and lower reaches of the Yangtze River is an important grain production base in China, which plays an important role in maintaining national food security. Based on the agricultural production and meteo-rological data from 1989 to 2018, we comprehensively analyzed water footprint of three major food crops (rice, wheat, and maize) production in six provinces in the middle and lower reaches of the Yangtze River. The results showed that rice in the six provinces always ranked first in terms of yield per unit area, sown area, and total yield. Water footprint of rice production was also the highest, with an average of 588.6×10⁸ m³, while the water footprint of wheat and maize production was relatively low. In terms of water footprint of per unit yield, wheat had the highest water footprint of per unit yield, with an average of 8.8 m³·kg^-1, followed by maize and rice. In terms of water footprint of per unit area, the three crops showed similar performance, and the overall trend showed a downward trend. The total water footprint of the three crops decreased significantly, from 1000.79×10⁸ m³ in 1989 to 281.34×10⁸ m³ in 2018. Among them, the water footprint of crop production in Zhejiang, Hubei, and Anhui was lower. From the perspective of the composition of water footprint, blue water footprint accounted for the highest proportion, followed by green water and gray water, with the value of 50.1%, 39.6%, and 10.3% respectively. The model analysis showed that economic effect, technical effect, grain planting area, and daily average sunshine hours had a greater impact on water footprint of crop production. Among them, the technical effect had a negative impact and other factors were positive. We proposed strategies to reduce water footprint of production, including the promotion of water-saving irrigation technology, the construction of water conservancy projects, the improvement of fertilizer and pesticide use efficiency, the planting of high water use efficiency varieties and the formulation of relevant policies. Our results revealed the change trend of water footprint of grain crop production in the middle and lower reaches of the Yangtze River, and identified the key factors affecting water footprint, which would provide a scientific basis for the development of water-saving agricultural technologies and water resources management strategies.

Spatio-temporal variations in functional redundancy of fish communities in the Haizhou Bay and its adjacent waters

DING Aiai, ZHANG Chongliang, XUE Ying, JI Yupeng, REN Yiping, XU Bin-duo

2025, 36(3):  895-902.  doi:10.13287/j.1001-9332.202503.032

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To explore the functional redundancy and better understand the stability of fish community in the Haizhou Bay and its adjacent waters, we examined the temporal and spatial variations in functional redundancy of fish community and the influencing factors using functional redundancy index (FR) and correlation analysis based on fish resource survey data in spring and autumn from 2013 to 2023. The results showed that the average value of FR was 9.39 in autumn and was 8.62 in spring. Fish community was more stable in autumn than in spring. There were significant seasonal differences in FR in 2015, 2016, 2018, and 2023. The FR of fish community showed interannual fluctuation, which was more significant in autumn. In autumn, the highest FR (10.36) was found in 2021, while the lowest value (8.61) was found in 2020. In spring, the highest value (9.64) was presented in 2022, and the lowest value (7.96) was in 2018. The FR increased from north to south in spring in most years, and the values were generally higher in the shallow waters less than 20 m in depth, but decreased from the southwest to northeast in most years in autumn. The spatio-temporal variations in functional redundancy may be related to fish biomass, number of species, and environmental factors such as water temperature, salinity and depth. The FR was positively correlated with fish biomass, number of fish species, and water temperature, but negatively correlated with salinity and depth.

Spatiotemporal distribution of Lagocephalus spadiceus and the relationship with environmental factors in the Beibu Gulf

XU Hao, HUANG Liangliang, WANG Caiguang, YANG Yiheng, SONG Jianqiang, XU Peng, WU Zhiqiang

2025, 36(3):  903-910.  doi:10.13287/j.1001-9332.202503.035

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To elucidate the influence of marine environmental factors on the distribution of Lagocephalus spadiceus, we analyzed fisheries and environmental survey data from the Beibu Gulf in April (spring) and August (autumn), 2022. We used the generalized additive model (GAM) to examine the relationship between the distribution of L. spadiceus and marine environmental factors, both before and after the implementation of a fishing moratorium. We showed that the density of L. spadiceus in the Beibu Gulf exhibited significant spatio-temporal variation, which concentrated in the central and northern parts of the gulf during spring and autumn, respectively. Such variation in resource density may be attributed to factors such as chlorophyll a content, salinity, pH, and latitude. The GAM accounted for 91.3% of the cumulative variance in resource density. The resource density of L. spadiceus increased with the increases of chlorophyll content, while it began to decrease after chlorophyll reaching 5 μg·L^-1. Both salinity and pH demonstrated a nonlinear relationship with resource density, characterized by multiple peaks, while latitude was positively correlated with resource density. This research provides valuable scientific evidence for the conservation of L. spadiceus resources.

Accumulation of microbial necromass and glomalin and their contribution to organic carbon in alpine grasslands with different degradation degrees

ZHANG Haolin, LI Yayun, HU Yang, LI Huijun, ZHOU Yue, AN Shaoshan, ZHU Zhaolong

2025, 36(3):  911-917.  doi:10.13287/j.1001-9332.202503.017

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The Qinghai-Xizang Plateau is sensitive to global change. Grassland degradation in this region severely affects soil microorganisms and soil organic carbon (SOC). As stable microbial metabolites, soil microbial necromass C (MNC) and glomalin-related soil proteins (GRSP) play a key role in the formation and stabilization of SOC. We investigated the content of MNC and GRSP in alpine grasslands with different degradation degrees (non-degradation, light degradation, moderate degradation, and heavy degradation) on the Qinghai-Xizang Plateau. We further analyzed their contributions to SOC and influencing factors. The results showed that: 1) The contents of MNC (6.04-14.27 mg·g^-1) and GRSP (2.55-7.64 mg·g^-1) significantly decreased with increasing degradation degrees. T heir contributions to SOC remained stable. 2) The contribution of MNC to SOC (7.5%-68.3%) was 2.8 times as high as that of GRSP (3.3%-26.5%). With the decreases of SOC owing to degradation, the MNC was accordingly reduced at 1.7 times as GRSP. 3) Soil physicochemical properties and microbial biomass were key factors affecting the accumulation of MNC and GRSP. In summary, microbial metabolites (e.g., MNC and GRSP) were key for SOC maintenance, and consequently played a crucial role in alleviating the impacts of alpine grassland degradation.

Reviews

Research progress on the width of ecological corridors in ecological security pattern

ZHOU Ying, FENG Zhe, LIN Qian, WANG Jiabin, ZHANG Kexin, WU Kening

2025, 36(3):  918-926.  doi:10.13287/j.1001-9332.202503.024

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As an important part of ecological security pattern, the scientific setting of the width of ecological corridors is a crucial part of the planning and design. We reviewed literature about ecological corridor width, comprehensively sorted out relevant theories, summarized the extraction methods of ecological corridor width, and put forward future research directions. There are four categories of methods for extracting the width of ecological corridors: determining the width based on the range of movement of protected targets, referencing previous research, considering the cumulative current changes in circuit theory, or combining with other models. The influencing factors included ecological needs of protection targets, edge effects of corridors, construction costs, policy priorities, and others. There are different methods for determining the width of ecological corridors, but the degree of refinement needs to be improved. Future research should focus on the theoretical basis of ecological corridor width, refined setting methods, effectiveness verification, shape, etc. This review could provide effective ideas for ecological corridor width research and enhance the feasibility of its implementation.

eDNA technology for monitoring terrestrial biodiversity: Technical highlights, challenges and progress

LIU Mingqian, ZHANG Zheng, WANG Shang, FENG Kai, GU Songsong, LI Chunge, DENG Ye

2025, 36(3):  927-942.  doi:10.13287/j.1001-9332.202503.031

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Biodiversity is a fundamental prerequisite for human survival, constituting an indispensable component of global ecosystems. The United Nations Sustainable Development Goal 15 (SDG 15) underscores the significance of conserving terrestrial biodiversity and strives to advance the sustainable utilization of terrestrial ecosystems. To achieve this goal, it is of the utmost importance to establish a comprehensive biodiversity monitoring system. As an emerging monitoring tool, environmental DNA (eDNA) metabarcoding technology offers a number of advantages, including species morphology-independent, rapidity, economical, and high accuracy. Consequently, it provides an effective method for monitoring terrestrial biodiversity. We outlined the key technical aspects of using eDNA metabarcoding as a tool for biodiversity monitoring in terrestrial ecosystems, discussed the challenges of using eDNA metabarcoding technology in biodiversity research, along with strategies for addressing these challenges, surveyed recent research advances regarding eDNA from different sources for terrestrial biodiversity monitoring, and proposed future research directions.

Research advances in the impacts of ectomycorrhizal fungi on the formation and decomposition of soil organic matter in forests

YU Shujie, SHEN Rong, LIN Dunmei

2025, 36(3):  943-949.  doi:10.13287/j.1001-9332.202503.034

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Ectomycorrhizal (EcM) fungi are one of the important functional groups of soil fungi, playing a crucial role in the formation, stabilization, and decomposition of soil organic matter (SOM). We summarized the main processes and mechanisms by which EcM fungi contribute to SOM formation, stabilization, and decomposition in forests. Plants allocate a portion of photosynthetic products to symbiotic EcM fungi, which participate in SOM formation by importing them into the soil in the form of mycorrhizal exudates or necromass, whose activities promote the formation of soil aggregate structure and SOM stabilization. EcM fungi decompose SOM directly by secreting extracellular enzymes or by driving the Fenton reaction to generate hydroxyl radicals. They also influence SOM decomposition indirectly by enhancing the activity of saprotrophic fungi (priming effect) or inhibiting their activity (Gadgil effect). The precise quantification of EcM fungi's role in SOM formation remains unclear. Most available studies are concentrated in Europe and North America, but the difference in methodologies makes it difficult to integrate data across regions. Future research should adopt standardized techniques and promote cross-regional collaborative studies. Current understanding of EcM fungi's role in SOM decomposition is mainly based on a few laboratory-cultured species. Future studies should include a broader range of EcM fungal species and investigate their roles in natural environments, particularly in different soil types and forest communities. In addition, the interactions between EcM fungi and saprotrophic fungi have significant impacts on SOM dynamics. Future research should explore the responses of EcM fungi to climate, soil and vegetation in depth to better understand their role in soil carbon cycling.

Research advances in using seaweed fertilizers to mitigate plant water stress

GUO Wenjing, YAN Tengyu, WANG Zongkang, ZENG Nan, JIANG Yuelu

2025, 36(3):  950-968.  doi:10.13287/j.1001-9332.202503.036

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Water stress has a profound and widespread impacts on agriculture globally, leading to slower plant growth, lower yields, and poorer quality. To meet this challenge, the application of seaweed fertilizer came into being. Seaweed fertilizer is rich in polysaccharides, proteins, lipids, plant hormones, minerals, and various other bioactive components, with great potential in water retention and nutrient provision. We systematically summarized the latest research progress on the role of seaweed fertilizers in mitigating water stress, with a focus on elucidating the mechanisms by which seaweed fertilizer enhances stress tolerance of plants. It significantly improves plant growth and yield, promotes root growth and nutrient uptake, ameliorates soil conditions, and enhances plant resis-tance to stress. Additionally, we put forward the challenges associated with the practical application of seaweed fertilizers in agriculture and the future research directions, aiming to provide alternative solutions for the sustainable goals and healthy development of global agriculture.