The lateral transport of labile organic carbon represents a critical pathway for soil organic carbon(SOC) loss,reducing organic carbon sequestration and increasing the risk of waterbody pollution.Livestock manure appl...The lateral transport of labile organic carbon represents a critical pathway for soil organic carbon(SOC) loss,reducing organic carbon sequestration and increasing the risk of waterbody pollution.Livestock manure application on croplands serves as a common fertilizer reduction practice to sustain crop yields,enhance SOC sequestration,and reduce water erosion.However,limited quantitative assessments have examined the effects of livestock manure substitution on labile organic carbon lateral loss and fluxes in long-term experiments.This study conducted a three-year field investigation on subtropical sloping croplands to assess the impact of livestock manure substitution on dissolved organic carbon(DOC) and particulate organic carbon(POC) loss via surface runoff,interflow and eroded sediments.There are four treatments:no fertilization(CK);chemical nitrogen fertilizer(SF),40% nitrogen substitution with pig manure(PMF),and 100% nitrogen substitution from pig manure(PM).Compared to SF treatment,long-term livestock manure substitution in PMF and PM treatments significantly(P<0.05) reduced annual cumulative surface runoff fluxes by 13.5 and 21.6%,respectively.Manure applications decreased annual sediment fluxes by 12.9 and 19.1%,respectively.Soil water stable aggregates for mean weight diameter(MWD) increased significantly by 37.7 and 73.6%.Annual cumulative POC loss flux via eroded sediment under PMF and PM treatments increased significantly(P<0.05) by 61.1 and 47.9%,respectively.The labile organic carbon loss fluxes,including DOC and POC losses,under PMF and PM treatments increased significantly(P<0.05) by 11.9 and 31.4%,respectively.These results demonstrate that while water erosion intensity decreases due to enhanced soil aggregate stability,the risk of labile organic carbon loss increases after long-term livestock manure substitution in subtropical sloping croplands.Future research should examine labile organic carbon lateral migration under various soil types and slope gradients for livestock manure application in subtropical agricultural ecosystem croplands to better understand extreme rainfall effects.展开更多
Cropland nitrate leaching is the major nitrogen(N) loss pathway, and it contributes significantly to water pollution. However, cropland nitrate leaching estimates show great uncertainty due to variations in input data...Cropland nitrate leaching is the major nitrogen(N) loss pathway, and it contributes significantly to water pollution. However, cropland nitrate leaching estimates show great uncertainty due to variations in input datasets and estimation methods. Here, we presented a re-evaluation of Chinese cropland nitrate leaching, and identified and quantified the sources of uncertainty by integrating three cropland area datasets, three N input datasets, and three estimation methods. The results revealed that nitrate leaching from Chinese cropland averaged 6.7±0.6 Tg N yr^(-1)in 2010, ranging from 2.9 to 15.8 Tg N yr^(-1)across 27 different estimates. The primary contributor to the uncertainty was the estimation method, accounting for 45.1%, followed by the interaction of N input dataset and estimation method at 24.4%. The results of this study emphasize the need for adopting a robust estimation method and improving the compatibility between the estimation method and N input dataset to effectively reduce uncertainty. This analysis provides valuable insights for accurately estimating cropland nitrate leaching and contributes to ongoing efforts that address water pollution concerns.展开更多
Cropland suitability analysis is a vital tool for ensuring food security and sustainable agriculture,coordinating ecological space with human activity space on the Qinghai-Tibet Plateau(QTP).However,there are few stud...Cropland suitability analysis is a vital tool for ensuring food security and sustainable agriculture,coordinating ecological space with human activity space on the Qinghai-Tibet Plateau(QTP).However,there are few studies on complete and accurate cropland suitability assessments on the QTP,let alone on identifying key potential areas for cropland development.We used a novel assessment model to generate a 30-m cropland suitability map for the QTP.The identification of areas with cropland development potential and the evaluation of potentially available cropland were further integrated into a unified analytical framework.We found that only 10.18%of the study area is suitable for large-scale and permanent cropland.Moreover,approximately 72.75%of the existing cropland was found to be distributed in suitable or marginally suitable areas.Considering the trade-offs related to irrigation water supply convenience,approximately 1.07%of the study area was identified as having high potential for cropland development.Four key potential areas were further identified:the Shannan Valley,the Nyingchi Valley,the Zanda Valley,and the Gonghe Basin.These areas boast abundant potentially available cropland resources and ecological resettlement capacities,which leads us to recommend strategic priorities for comprehensive land consolidation and water development.This study has practical significance for optimizing land resource allocation and guiding decision-making related to ecological migration on the QTP.展开更多
Global population growth and rising standards of living are the driving factors for the cropland expansion to meet increasing demands.However,there is no clear assessment of the specific losses on ecosystem services c...Global population growth and rising standards of living are the driving factors for the cropland expansion to meet increasing demands.However,there is no clear assessment of the specific losses on ecosystem services caused by China's expansion of cropland to ensure food security at the cost of losing ecological land such as forests and grasslands.This study employed the ArcGIS platform and integrated valuation of ecosystem services and tradeoffs(InVEST)model to explore the cropland expansion in China from 2000 to 2020 and its impact on ecosystem services,so as to predict the priority areas of future cropland expansion in different scenarios.The results indicated that in the past 20 years,the total area of cropland expansion in China was 17.04 million hm^(2)with 70.79% conversion from forests and grasslands.Cropland expansion has contributed to an overall improvement in the food supply services with the Northern Arid and Semi-Arid Region exhibiting an increase of 18.76×10^(6) tons,while concurrently leading to a decline in habitat quality services.The priority areas for future cropland expansion without ecological loss were found to be 1.42 million hm^(2),which only account for 9.44% of the total reclaimable land.To minimize the loss of ecosystem services,there is a need to adjust the cropland replenishment policies and provide an operational solution for global food security and ecological protection.展开更多
The health of cropland systems is directly related to the degree of food security guarantee,and the‘quantity-quality-ecology as a whole’protection is of great significance for maintaining the health of cropland syst...The health of cropland systems is directly related to the degree of food security guarantee,and the‘quantity-quality-ecology as a whole’protection is of great significance for maintaining the health of cropland systems.Taking the typical black soil region in Northeast China(TBSN)as an example,this paper combined the concept of‘quantity-quality-ecology as a whole’protection with crop-land systems health,constructed a health assessment model for cropland systems,and used Google Earth Engine to conduct a quantitat-ive analysis of the temporal and spatial evolution of cropland systems health in TBSN during 2003–2023.By coupling the geographical detector and the Multi-scale Geographically Weighted Regression(MGWR)model,the driving factors of cropland health changes were explored.The study finds that during the research period,the health status of cropland systems in TBSN showed a slight downward trend,and the distribution pattern of cropland systems health gradually shifted from‘better in the east’to‘high in the northeast and low in the southwest’.Changes in average annual sunshine duration,relative humidity,and precipitation had a significant impact on the spa-tial differentiation of cropland systems health in the early stages,and were considered as dominant factors.Meanwhile,the influence of dual dominant factors in the natural environment on cropland systems health is increasing.Furthermore,the MGWR model performed better in revealing the complex relationships between natural and social factors and changes in cropland systems health,demonstrating the significant spatial heterogeneity of the impacts of natural environment and human activities on cropland systems health.The re-search can provide scientific guidance for the sustainable development of TBSN and formulate more precise and effective cropland pro-tection policies.展开更多
Cropland abandonment is prevalent throughout China,particularly in mountainous regions.However,the varying degrees of land marginalization and the specific factors influencing different types of cropland remain insuff...Cropland abandonment is prevalent throughout China,particularly in mountainous regions.However,the varying degrees of land marginalization and the specific factors influencing different types of cropland remain insufficiently understood.This knowledge gap hampers targeted management strategies for mitigating cropland abandonment in these areas.This study used spatial analysis,logistic regression,and random forest models to explore the spatial patterns and key drivers of abandonment across flatland,terrace,and slopeland in Chongyi county,a mountainous region in Jiangxi Province of South China,utilizing data from the 2009 and 2019 national land surveys of China.Results showed that the overall cropland abandonment rate in Chongyi county was 36.46%,with particularly high rates in core terrace conservation areas.Abandoned cropland was spatially clustered,predominantly in high-elevation regions.The abandonment rates were 9.71%for flatland,37.52%for terrace,and 43.02%for slopeland.Variations in vegetation cover on abandoned cropland suggest that abandonment started earlier on slopeland and later extended to terraces and flatlands.The factors driving the abandonment of flatland,terrace,and slopeland included land altitude,cultivation height difference,and distance to forest land,respectively.Consequently,the results recommend implementing land consolidation and developing small machinery projects for the fragmented flatland.Promoting the multifunctional use of terraces could realize their ecological value.Additionally,the Program of Converting Farmland to Forest should be implemented on the low-quality slopeland.展开更多
In many existing dictionaries,cropland is defined as land that is suitable for or used to grow crops.It has several synonyms,such as“farmland”,“arable land”,and“cultivated land”.However,in scientific literature,...In many existing dictionaries,cropland is defined as land that is suitable for or used to grow crops.It has several synonyms,such as“farmland”,“arable land”,and“cultivated land”.However,in scientific literature,the nuances of these terms are often overlooked.The inconsistent terminology usage could lead to ambiguity and confusion in research and policy discussions.In particular,it creates difficulties for newcomers and students when they search for precise information in the published literature.Hence,exploring the variations of terminology applications is important for the cropland-related research community.In this study,the differences in six cropland-related terminologies were explored through a review of 5,214 scientific articles,by employing the independence test,clustering approach,and correlation analysis.The results showed that disparities exist across disciplines.For example,biodiversity&conservation studies preferentially use“farmland”to highlight effects from human activities,while studies in geology and computer science use“cropland”.The term“cultivated land”tends to be used in geography research for clear geographical demarcation,while“arable land”is related to engineering studies.Moreover,further disparities based on the geographical affiliations of the authors were found.The correlation between China and“cultivated land”was reliable and a close link was found between“agricultural land”and the USA.The regional variations in cropland terminology can be influenced by multiple factors,including the degree of agricultural mechanization,colonial history,and migration patterns.This study reveals variations in cropland-related terminology across disciplines and regions.The results highlight the importance of standardizing cropland terminology to foster interdisciplinary research,improve data comparability,and support global agricultural and environmental policymaking.展开更多
Sustainable Development Goal 2(SDG 2,zero hunger)highlights that global hunger and food insecurity have worsened since 2015,driven in part by growing imbalance.Addressing the challenge of achieving SDG 2 in the face o...Sustainable Development Goal 2(SDG 2,zero hunger)highlights that global hunger and food insecurity have worsened since 2015,driven in part by growing imbalance.Addressing the challenge of achieving SDG 2 in the face of rapid global population growth requires sustained attention to global and national cropland changes.Accurately quantifying the correlation between population and cropland area(i.e.,SDG 2.4.1 per capita cropland)and analyzing the trends of global cropland imbalance are essential for a comprehensive understanding of SDG 2.In this study,we utilized a new global 30 m land-cover dynamic dataset(GLC_FCS30D)to analyze cropland dynamics,quantify per capita cropland and its changes across various countries and levels of development.Our results indicate that the global cropland area expanded by 0.944 million km^(2)from 1985 to 2022,with an average expansion rate of 2.42×10^(4)km^(2)/yr.However,the global per capita cropland area decreased from 0.347 ha in 1985 to 0.217 ha in 2022,mainly due to a higher population increase of nearly 65%in the same period.In the context of globalization,cropland expansion and per capita cropland exhibited spatial imbalances globally,particularly in developing countries.Developing countries saw an increase in total cropland area by 7.09%but a significant decrease in per capita cropland area by 37.38%.From a temporal perspective,the global imbalance has been steadily increasing with the Gini index rising from 0.895 in 1985 to 0.909 in 2022.Consequently,this study reveals an increasing imbalance of global per capita cropland across various countries,which threatens the attainment of the targets of SDG 2.展开更多
Cropland is persistently affected by soil loss by water erosion in China,which causes economic loss and threatens soil health.Integrating crop switching and improved management provides a promising strategy for contro...Cropland is persistently affected by soil loss by water erosion in China,which causes economic loss and threatens soil health.Integrating crop switching and improved management provides a promising strategy for controlling soil loss by water erosion in cropland and promoting sustainable agriculture.However,optimizing crop composition with fewer inputs involves balancing agricultural resource use with environmental costs.Aiming to explore the potential of crop switching as a strategy for mitigating soil erosion in cropland,we develop a spatial optimization model that redistributes the sown areas of different crops in each prefecture-level city based on existing resource availability.Our findings gained from our simulations show that crop switching in China alone can reduce total soil erosion in cropland by an estimated 13%.Furthermore,combining crop switching with improved agricultural management practices can further reduce soil erosion in cropland by an estimated 25%.Cereals including maize,wheat,and rice demonstrate significant potential for reducing soil erosion in cropland.Shifting major maize-producing areas northward could result in a substantial decrease in soil erosion,ranging from 10% to 19% of historical soil erosion in cropland.These results offer implications for formulating regional strategy in mitigating soil erosion challenges in China while maximizing the benefits from existing agricultural resource.展开更多
Cropland abandonment has become a global issue that poses significant threats to sustainable cropland management,national food security,and the ecological environment.Remote sensing technology is crucial for identifyi...Cropland abandonment has become a global issue that poses significant threats to sustainable cropland management,national food security,and the ecological environment.Remote sensing technology is crucial for identifying and monitoring abandoned cropland in large-scale areas.However,limited information is available on the effective identification methods and spatial distribution patterns of abandoned cropland in the hilly and gully regions.This study introduced two methods-the land-use trajectory and normalized difference vegetation index(NDVI)time series-for monitoring abandoned cropland and evaluating its spatial distribution in Yanhe River Basin using Landsat-8 images from 2019 to 2021.The results showed that using a random forest algorithm,high-precision annual land-use classifications were achieved with the generation of reliable land-cover samples and an optimized feature dataset.The overall accuracy(OA)and Kappa coefficient of the land-use maps exceeded 90% and 0.88,respectively,demonstrating the effectiveness of the classification over three years.These two distinct change detection methods were used to identify abandoned cropland in the study area,and their accuracy and effectiveness were evaluated.The land-use trajectory method performed better than the NDVI time series method for extracting abandoned cropland,with an OA of 83.5% and an F1 score of 84.7%.According to the land-use trajectory detection results,the study area had 164.6 km^(2) of abandoned cropland area in 2021,with an abandonment rate of 16.3%.Furthermore,cropland abandonment mainly occurred in the northwestern part of the region,which has harsh natural conditions,while abandonment was rare in the southern and eastern regions.Topography and landforms significantly influenced the spatial distribution of abandoned cropland,with most abandoned cropland located in mountainous regions with higher elevations and steeper slopes.The abandonment rate generally increased with the elevation and slope.These findings provide valuable references and guidance for selecting appropriate methods to identify abandoned cropland and analyze its spatial distribution in the hilly and gully regions.Our proposed methods offer robust solutions for monitoring abandoned cropland and optimizing land-use change detection in similar regions with complex landforms.展开更多
Exposure assessment is critical for hazard risk management.It is important to investigate the cropland exposure to compound drought and heatwave(CDHW)events because of their severe impacts on agriculture.We quantified...Exposure assessment is critical for hazard risk management.It is important to investigate the cropland exposure to compound drought and heatwave(CDHW)events because of their severe impacts on agriculture.We quantified the variations in CDHW characteristics(i.e.,frequency,duration,and magnitude)and the cropland exposure to CDHW events in Northeast China using 20 CMIP6 climate projections for each of the four Shared Socioeconomic Pathways(i.e.,SSP126,SSP245,SSP370,and SSP585).The results indicate that the intensification of CDHW events leading to an anticipated increase in cropland exposure ranges from 1.6-fold to 5.8-fold(the range describes the differences among SSPs),with the west and northeast of the region poised to experience more pronounced increases.Notably,adherence to the SSP126 pathway can reduce both the increase rate of CDHW magnitude and cropland exposure compared to other SSPs.Path analysis demonstrates that cropland exposure is primarily driven by maximum temperature(Tmax).Although precipitation(Pre)increases(0.36-0.75 mm year^(-1)),the rise in potential evapotranspiration(PET)due to global warming is higher than that of Pre(0.26-1.07 mm year^(-1))except for SSP126,resulting in more drought events.Futhermore,elevated Tmax increases the frequency of extreme temperature events.Therefore,increases in Tmax and agricultural land area collectively contribute to exposure rise,with Tmax being the dominant factor in this process.Our findings emphasize the pivotal role of regulating the development pathway into SSP126 for sustainable agriculture,and optimizing crop patterns and planting heat-tolerant crop varieties are recommended for CDHW adaption.展开更多
Agricultural greenhouse gas(GHG)emissions are influenced by a combination of climate,soil and agricultural management practices.Over the past 30 years,approximately 5% of China's cropland has shifted from the sout...Agricultural greenhouse gas(GHG)emissions are influenced by a combination of climate,soil and agricultural management practices.Over the past 30 years,approximately 5% of China's cropland has shifted from the south to the north.This shift has significantly altered the geographical environment,with potential substantial impacts on agricultural GHG emissions.This study used the DeNitrification DeComposition(DNDC)process-based model to simulate GHG emissions(CH_(4)and N_(2)O)from the production of China's 10 major food crops and explored changes in agricultural GHG emissions caused by the spatial shift of cropland in China.Results from the validated DNDC model indicate that total emissions from the major food crop production in China were approximately 343 Tg CO_(2)-eq yr^(-1)with CH_(4)emissions accounting for about 74%.Meanwhile,the spatial shift of cropland from 1990 to 2020 resulted in a 3% decrease in average CH_(4)emissions per unit cropland area and an 8% increase in average N_(2)O emissions per unit cropland area,respectively.The expansion of dryland in the Northwest Arid Region emitted less CH_(4)but significantly more N_(2)O,thereby driving changes in national GHG emissions.This study provides a scientific foundation for the sustainable use of cropland and the formulation of strategies to reduce agricultural GHG emissions.展开更多
Rapid climate and cropland use changes in recent decades have posed major challenges to food security in China.Hainan Is-land is the only tropical island in China and is blessed with natural conditions for crop produc...Rapid climate and cropland use changes in recent decades have posed major challenges to food security in China.Hainan Is-land is the only tropical island in China and is blessed with natural conditions for crop production.This study first simulates the climate scenarios of Hainan Island for 2030,2040 and 2050 under the four Socio-economic Pathways(SSPs)based on the climate models in ScenarioMIP of Coupled Model Intercomparison Project Phase 6(CMIP6),and then simulates the land use scenarios of Hainan Island for 2030,2040 and 2050 based on the Cellular Automata(CA)-Markov model.Finally,based on the Global Agro-Ecological Zones(GAEZ)model,the rice potential yield in Hainan Island for 2030,2040 and 2050 are simulated,and the effects of future climate and cropland use changes on rice potential yields are investigated.The results show that:1)from 2020 to 2050,mean maximum temperature first decreases and then increases,while mean minimum temperature increase sharply followed by a leveling off under the four SSPs.Precipitation decreases and then increases under other three SSPs except SSP2-4.5.Net solar radiation increases continuously under SSP1-2.6,2-4.5,and 5-8.5,and has the lowest simulated values under SSP3-7.0.Mean wind speed increases continuously under SSP1-2.6,fluctuates more under SSP2-4.5 and SSP5-8.5,and increases slowly and then decreases sharply under SSP3-7.0.Relative humidity basically decreases continuously under the four SSPs.2)Areas of paddy field are 302.49 thousand,302.41 thousand and 302.71 thou-sand ha for 2030,2040 and 2050,respectively,all less than that in 2020.Paddy field is mainly converted into built-up land and wood-land.As for the conversion of other land types to paddy field,woodland is the main source.3)Under the effects of future climate and cropland use changes,the mean potential productions in Hainan Island under the four SSPs increase 1.17 million,1.13 million and 1.11 million t,respectively,and the mean potential yields increase 3873.21,3766.71 and 3672.38 kg/ha,respectively for the three periods.The largest increases in mean rice potential production and mean potential yield are 1.21 million t and 4008.00 kg/ha,1.16 million t and 3846.65 kg/ha,as well as 1.13 million t and 3732.75 kg/ha,respectively under SSP 3-7.0,indicating that SSP3-7.0 is the most suitable scenario for rice growth.This study could provide scientific basis for crop planting planning and agricultural policy adjustment.展开更多
There are more people but less land in China,so food safety has always been a most important issue government concerned.With continuous population increase,economic development and environment protection,cropland occu...There are more people but less land in China,so food safety has always been a most important issue government concerned.With continuous population increase,economic development and environment protection,cropland occupation and supplement are unavoidable.It not only leads to the variation of cropland area,but also makes the light-temperature potential productivity per unit area different due to regional climate differentiation,therefore impacts the total potential productivity and food output eventually.So,it is necessary to analyze the climate differentiation between occupation and supplement cropland areas and to study its impact on total potential productivity,which is significant to reasonably develop natural resources and instruct agricultural arrangement.This study firstly discussed the variation and distribution of occupation and supplement croplands in China from 2000 to 2008,then analyzed the climate differentiation between occupation and supplement cropland areas and its effect on light-temperature potential productivity.The results demonstrate:1) From 2000 to 2008,the cropland variation presented occupation in the south and supplement in the north,but overall decreased.Supplement cropland was mainly from ecological reclamation(77.78%) and was mainly distributed in Northeast China and Northwest China with poor climatic and natural conditions.Occupation cropland was mainly used for construction(52.88%) and ecological restoration(44.78%) purposes,and was mainly distributed in the Huang-Huai-Hai Plain,and the middle and lower reaches of the Changjiang(Yangtze) River with better climatic and natural conditions.2) The climate conditions were quite different in supplement and occupation cropland areas.The annual precipitation,annual accumulated temperature and average annual temperature were lower in the supplement cropland area,and its average po-tential productivity per unit was only 62% of occupation cropland area,which was the main reason for the decrease of total potential productivity.3) Cropland occupation and supplement led to the variation of total potential productivity and its spatial distribution.The productivity decreased in the south and increased in the north,but had a net loss of 4.38315×107 t in the whole country.The increase of cropland area was at the cost of reclaiming natural forest and grassland resources,and destroying natural ecological environment,while the decrease of cropland area was mainly due to a lot of cropland occupied by urban-rural construction,which threatened the sustainable use of cropland resources.展开更多
In order to deal with the global change and to reduce emission of greenhouse gas, a number of countries have strengthened studies on carbon sequestration in cropland. Carbon sequestration in cropland is not only an im...In order to deal with the global change and to reduce emission of greenhouse gas, a number of countries have strengthened studies on carbon sequestration in cropland. Carbon sequestration in cropland is not only an important component for the global carbon stock, but also is the most active part to sequestrate the carbon in soil from atmosphere. In this sense, it is of necessity and significance to strengthen the study on management of carbon sequestration in cropland. Based on the main factors affecting carbon cycle in agro-ecosystems, this paper summarizes the relevant management measures to strengthen the capacity of reducing emission of carbon and increasing the carbon sequestration in cropland, and evaluates the effects of these measures after being implemented at a regional extent.展开更多
Methane is an important greenhouse gas, and farmland is one of the im- portant emission sources of methane. Therefore, it's important to study the discharge of methane from cropland. This paper reviewed the methane e...Methane is an important greenhouse gas, and farmland is one of the im- portant emission sources of methane. Therefore, it's important to study the discharge of methane from cropland. This paper reviewed the methane emission from agricultural ecosystem, the factors controlling CH4 fluxes from soil, such as water regime, the soil characteristics, and the type and amount of applied fertilizers and so on, the management for mitigation of CH4 emission from cropland, especially from paddy field, and put forward some research suggestions on methane emission in the future. The objective of this paper is to provide reference for controlling methane emission in cropland.展开更多
[Objective] This study aimed to analyze the sustainability of cropland use in cropping-pastoral ecotone before and after the Grain-for-Green Policy. [Method] Using Yanchi County in Ningxia Hui Autonomous Region as a c...[Objective] This study aimed to analyze the sustainability of cropland use in cropping-pastoral ecotone before and after the Grain-for-Green Policy. [Method] Using Yanchi County in Ningxia Hui Autonomous Region as a case study area, this investigation used the annual transfer rate of land use types, cropland suitability and emergy analysis to examine the major pressures affecting the sustainable use of cropland before and after the Grain-for-Green Policy. [Result] The expansion of con- struction land onto cropland was significant; the annual cropland area was still larger than the land area suitable for cropping after the policy; agrochemical inputs used for crop production gradually increased and unit crop outputs required more agro- chemical inputs. Cropland use sustainability showed a fluctuating downward trend. [Conclusion] The results imply that the protection of high quality cropland, further im- plementation of the policy and control of agrochemical inputs according to precipita- tion are the main measures needed for sustainable cropland use in cropping-pastoral ecotone.展开更多
Agriculture is a large source of carbon emissions. The cropland practices of fertilizer substitution, crop straw and conservation tillage are beneficial and help to rebuild local soil carbon stocks and reduce soil car...Agriculture is a large source of carbon emissions. The cropland practices of fertilizer substitution, crop straw and conservation tillage are beneficial and help to rebuild local soil carbon stocks and reduce soil carbon emissions, in addition to reducing the consumption of fertilizers and fossil fuels. These improved cropland practices can directly and indirectly mitigatecarbon emissions, benefiting the sustainability of croplands. For these three improved practices, we estimated carbon mitigation potentials in rice, wheat and maize croplands in China. The combined contribution of these practices to carbon mitigation was 38.8 Tg C yr-1, with fertilizer substitution, crop straw return, and conservation tillage contributing 26.6, 3.6 and 8.6 Tg C yr-1, respectively. Rice, wheat and maize croplands had potentials to mitigate 13.4, 11.9 and 15.5 Tg C yr-1, respectively, with the combined direct and indirectpotential of 33.8 and 5.0 Tg C yr-1. Because of differences in local climate and specific diets, the regional cropland carbon mitigation potentials differed greatly among provinces in China. In China, 18 provinces had a "target surplus" for which the carbon mitigation from these three practices was larger than the mitigation target set for 2020. At the national level, a net "target surplus"of 4.84 Tg C yr-1 would be attained for Chinese croplands with full implementation of the three improved practices. Regional cooperation must be developed to achieve carbon mitigation targets using such measures as carbon trading, establishing regional associations, and strengthening research programs to improve practices.展开更多
The study of the spatial patterns and temporal changes of cropland is important to understand the underlying factors and the functional effects of the agricultural landscape. On the other hand, crop dynamics mapping i...The study of the spatial patterns and temporal changes of cropland is important to understand the underlying factors and the functional effects of the agricultural landscape. On the other hand, crop dynamics mapping is essential to know the overall agro-spatial diversity of the area. Therefore, this paper addressed a spatio-temporal analysis of cropland and cropping pattern change in the Bogra district of Bangladesh over the last 16 years (between 1988/89 and 2004/05). In this paper, crop mapping from multi-temporal and multi-sensor satellite images was described. Landsat TM and IRS P6 LlSS Ⅲ satellite images were used with GIS for spatial dynamics of cropland and cropping pattern change analysis. First, seasonal cropland maps were derived from object-based classification of satellite images, then two-date classified image differencing with GIS overlay technique and decision rules were applied. Cropping pattern change was analyzed in a spatial and quantitative way for the 16 years and for this, Integrated Land and Water Information System (ILWIS) and Land Change Modular (LCM) of IDRISl Andes were used. The results showed that in the area, mono crop cultivation was found in summer, but in winter, areas under different crop cultivation had changed dramatically. Change analysis showed that the changes mainly occurred in the north northwest and southwest of the areas, and during the time the highest change area was found under the rice-potato pattern.展开更多
From 1992 to 2015, ecological environment has been threatened by the changes of cropland around the world. In order to evaluate the impact of cropland changes on ecosystem, we calculated the response of terrestrial ec...From 1992 to 2015, ecological environment has been threatened by the changes of cropland around the world. In order to evaluate the impact of cropland changes on ecosystem, we calculated the response of terrestrial ecosystem service values (TESVs) variation to cropland conversion based on land-use data from European Space Agency (ESA). The results showed that cropland changes were responsible for an absolute loss of $166.82 billion, equivalent to 1.17% of global TESVs in 1992. Among the different regions, the impact of cropland changes on TESVs was significant in South America and Africa but not obvious in Oceania, Asia and Europe. Cropland expansion from tropical forest was the main reason for decreases in TESVs globally, especially in South America, Africa and Asia. The effect of wetland converted to cropland was notable in North America and Europe while grassland converted to cropland played an important role in Oceania, Africa and Asia. In Europe, the force of urban expansion cannot be ignored as well. The conversion of cropland to tropical or temperate forest partly compensated for the loss of TESVs globally, especially in Asia.展开更多
基金funded by the Joint Funds of the National Natural Science Foundation of China (U20A20107 and U22A20562)the National Key Research and Development Program of China (2023YFD1900201-3)the International Cooperation Project,Ministry of Science and Technology of China (G2023019005L)。
文摘The lateral transport of labile organic carbon represents a critical pathway for soil organic carbon(SOC) loss,reducing organic carbon sequestration and increasing the risk of waterbody pollution.Livestock manure application on croplands serves as a common fertilizer reduction practice to sustain crop yields,enhance SOC sequestration,and reduce water erosion.However,limited quantitative assessments have examined the effects of livestock manure substitution on labile organic carbon lateral loss and fluxes in long-term experiments.This study conducted a three-year field investigation on subtropical sloping croplands to assess the impact of livestock manure substitution on dissolved organic carbon(DOC) and particulate organic carbon(POC) loss via surface runoff,interflow and eroded sediments.There are four treatments:no fertilization(CK);chemical nitrogen fertilizer(SF),40% nitrogen substitution with pig manure(PMF),and 100% nitrogen substitution from pig manure(PM).Compared to SF treatment,long-term livestock manure substitution in PMF and PM treatments significantly(P<0.05) reduced annual cumulative surface runoff fluxes by 13.5 and 21.6%,respectively.Manure applications decreased annual sediment fluxes by 12.9 and 19.1%,respectively.Soil water stable aggregates for mean weight diameter(MWD) increased significantly by 37.7 and 73.6%.Annual cumulative POC loss flux via eroded sediment under PMF and PM treatments increased significantly(P<0.05) by 61.1 and 47.9%,respectively.The labile organic carbon loss fluxes,including DOC and POC losses,under PMF and PM treatments increased significantly(P<0.05) by 11.9 and 31.4%,respectively.These results demonstrate that while water erosion intensity decreases due to enhanced soil aggregate stability,the risk of labile organic carbon loss increases after long-term livestock manure substitution in subtropical sloping croplands.Future research should examine labile organic carbon lateral migration under various soil types and slope gradients for livestock manure application in subtropical agricultural ecosystem croplands to better understand extreme rainfall effects.
基金supported by the National Key Research and Development Program of China (2023YFD1902703)the National Natural Science Foundation of China (Key Program) (U23A20158)。
文摘Cropland nitrate leaching is the major nitrogen(N) loss pathway, and it contributes significantly to water pollution. However, cropland nitrate leaching estimates show great uncertainty due to variations in input datasets and estimation methods. Here, we presented a re-evaluation of Chinese cropland nitrate leaching, and identified and quantified the sources of uncertainty by integrating three cropland area datasets, three N input datasets, and three estimation methods. The results revealed that nitrate leaching from Chinese cropland averaged 6.7±0.6 Tg N yr^(-1)in 2010, ranging from 2.9 to 15.8 Tg N yr^(-1)across 27 different estimates. The primary contributor to the uncertainty was the estimation method, accounting for 45.1%, followed by the interaction of N input dataset and estimation method at 24.4%. The results of this study emphasize the need for adopting a robust estimation method and improving the compatibility between the estimation method and N input dataset to effectively reduce uncertainty. This analysis provides valuable insights for accurately estimating cropland nitrate leaching and contributes to ongoing efforts that address water pollution concerns.
基金The Second Tibetan Plateau Scientific Expedition and Research ProgramNo.2019QZKK0406。
文摘Cropland suitability analysis is a vital tool for ensuring food security and sustainable agriculture,coordinating ecological space with human activity space on the Qinghai-Tibet Plateau(QTP).However,there are few studies on complete and accurate cropland suitability assessments on the QTP,let alone on identifying key potential areas for cropland development.We used a novel assessment model to generate a 30-m cropland suitability map for the QTP.The identification of areas with cropland development potential and the evaluation of potentially available cropland were further integrated into a unified analytical framework.We found that only 10.18%of the study area is suitable for large-scale and permanent cropland.Moreover,approximately 72.75%of the existing cropland was found to be distributed in suitable or marginally suitable areas.Considering the trade-offs related to irrigation water supply convenience,approximately 1.07%of the study area was identified as having high potential for cropland development.Four key potential areas were further identified:the Shannan Valley,the Nyingchi Valley,the Zanda Valley,and the Gonghe Basin.These areas boast abundant potentially available cropland resources and ecological resettlement capacities,which leads us to recommend strategic priorities for comprehensive land consolidation and water development.This study has practical significance for optimizing land resource allocation and guiding decision-making related to ecological migration on the QTP.
基金supported by the National Natural Science Foundation of China(Grant No.52374170)the Major Special Projects of the Third Comprehensive Scientific Exploration in Xinjiang(Grant No.2022xjkk1005)the Fundamental Research Funds for the Central Universities(Grant No.B230207001)。
文摘Global population growth and rising standards of living are the driving factors for the cropland expansion to meet increasing demands.However,there is no clear assessment of the specific losses on ecosystem services caused by China's expansion of cropland to ensure food security at the cost of losing ecological land such as forests and grasslands.This study employed the ArcGIS platform and integrated valuation of ecosystem services and tradeoffs(InVEST)model to explore the cropland expansion in China from 2000 to 2020 and its impact on ecosystem services,so as to predict the priority areas of future cropland expansion in different scenarios.The results indicated that in the past 20 years,the total area of cropland expansion in China was 17.04 million hm^(2)with 70.79% conversion from forests and grasslands.Cropland expansion has contributed to an overall improvement in the food supply services with the Northern Arid and Semi-Arid Region exhibiting an increase of 18.76×10^(6) tons,while concurrently leading to a decline in habitat quality services.The priority areas for future cropland expansion without ecological loss were found to be 1.42 million hm^(2),which only account for 9.44% of the total reclaimable land.To minimize the loss of ecosystem services,there is a need to adjust the cropland replenishment policies and provide an operational solution for global food security and ecological protection.
基金Under the auspices of National Natural Science Foundation Youth Fund Project(No.41701424)Open Research Fund of State Key Laboratory of Remote Sensing Science(No.OFSLRSS201716)+1 种基金Jilin Province Science and Technology Development Plan Project(No.20240701167FG)Science and Technology Research Project of Education Department of Jilin Province(No.JJKH20230502KJ)。
文摘The health of cropland systems is directly related to the degree of food security guarantee,and the‘quantity-quality-ecology as a whole’protection is of great significance for maintaining the health of cropland systems.Taking the typical black soil region in Northeast China(TBSN)as an example,this paper combined the concept of‘quantity-quality-ecology as a whole’protection with crop-land systems health,constructed a health assessment model for cropland systems,and used Google Earth Engine to conduct a quantitat-ive analysis of the temporal and spatial evolution of cropland systems health in TBSN during 2003–2023.By coupling the geographical detector and the Multi-scale Geographically Weighted Regression(MGWR)model,the driving factors of cropland health changes were explored.The study finds that during the research period,the health status of cropland systems in TBSN showed a slight downward trend,and the distribution pattern of cropland systems health gradually shifted from‘better in the east’to‘high in the northeast and low in the southwest’.Changes in average annual sunshine duration,relative humidity,and precipitation had a significant impact on the spa-tial differentiation of cropland systems health in the early stages,and were considered as dominant factors.Meanwhile,the influence of dual dominant factors in the natural environment on cropland systems health is increasing.Furthermore,the MGWR model performed better in revealing the complex relationships between natural and social factors and changes in cropland systems health,demonstrating the significant spatial heterogeneity of the impacts of natural environment and human activities on cropland systems health.The re-search can provide scientific guidance for the sustainable development of TBSN and formulate more precise and effective cropland pro-tection policies.
基金supported by the National Natural Science Foundation of China[Grant No.42201232]the Science and Technology Research Project of Jiangxi Provincial Department of Education[Grant No.GJJ210539].
文摘Cropland abandonment is prevalent throughout China,particularly in mountainous regions.However,the varying degrees of land marginalization and the specific factors influencing different types of cropland remain insufficiently understood.This knowledge gap hampers targeted management strategies for mitigating cropland abandonment in these areas.This study used spatial analysis,logistic regression,and random forest models to explore the spatial patterns and key drivers of abandonment across flatland,terrace,and slopeland in Chongyi county,a mountainous region in Jiangxi Province of South China,utilizing data from the 2009 and 2019 national land surveys of China.Results showed that the overall cropland abandonment rate in Chongyi county was 36.46%,with particularly high rates in core terrace conservation areas.Abandoned cropland was spatially clustered,predominantly in high-elevation regions.The abandonment rates were 9.71%for flatland,37.52%for terrace,and 43.02%for slopeland.Variations in vegetation cover on abandoned cropland suggest that abandonment started earlier on slopeland and later extended to terraces and flatlands.The factors driving the abandonment of flatland,terrace,and slopeland included land altitude,cultivation height difference,and distance to forest land,respectively.Consequently,the results recommend implementing land consolidation and developing small machinery projects for the fragmented flatland.Promoting the multifunctional use of terraces could realize their ecological value.Additionally,the Program of Converting Farmland to Forest should be implemented on the low-quality slopeland.
基金supported by the National Key Research and Development Program of China(2023YFD2300501)the National Natural Science Foundation of China(41921001 and 42401440)。
文摘In many existing dictionaries,cropland is defined as land that is suitable for or used to grow crops.It has several synonyms,such as“farmland”,“arable land”,and“cultivated land”.However,in scientific literature,the nuances of these terms are often overlooked.The inconsistent terminology usage could lead to ambiguity and confusion in research and policy discussions.In particular,it creates difficulties for newcomers and students when they search for precise information in the published literature.Hence,exploring the variations of terminology applications is important for the cropland-related research community.In this study,the differences in six cropland-related terminologies were explored through a review of 5,214 scientific articles,by employing the independence test,clustering approach,and correlation analysis.The results showed that disparities exist across disciplines.For example,biodiversity&conservation studies preferentially use“farmland”to highlight effects from human activities,while studies in geology and computer science use“cropland”.The term“cultivated land”tends to be used in geography research for clear geographical demarcation,while“arable land”is related to engineering studies.Moreover,further disparities based on the geographical affiliations of the authors were found.The correlation between China and“cultivated land”was reliable and a close link was found between“agricultural land”and the USA.The regional variations in cropland terminology can be influenced by multiple factors,including the degree of agricultural mechanization,colonial history,and migration patterns.This study reveals variations in cropland-related terminology across disciplines and regions.The results highlight the importance of standardizing cropland terminology to foster interdisciplinary research,improve data comparability,and support global agricultural and environmental policymaking.
基金supported by the National Key Research and Development Program of China(Grant No.2023YFB3907403)the National Natural Science Foundation of China(Grant No.42201499)the Open Research Program of the International Research Center of Big Data for Sustainable Development Goals(Grant No.CBAS2022ORP03).
文摘Sustainable Development Goal 2(SDG 2,zero hunger)highlights that global hunger and food insecurity have worsened since 2015,driven in part by growing imbalance.Addressing the challenge of achieving SDG 2 in the face of rapid global population growth requires sustained attention to global and national cropland changes.Accurately quantifying the correlation between population and cropland area(i.e.,SDG 2.4.1 per capita cropland)and analyzing the trends of global cropland imbalance are essential for a comprehensive understanding of SDG 2.In this study,we utilized a new global 30 m land-cover dynamic dataset(GLC_FCS30D)to analyze cropland dynamics,quantify per capita cropland and its changes across various countries and levels of development.Our results indicate that the global cropland area expanded by 0.944 million km^(2)from 1985 to 2022,with an average expansion rate of 2.42×10^(4)km^(2)/yr.However,the global per capita cropland area decreased from 0.347 ha in 1985 to 0.217 ha in 2022,mainly due to a higher population increase of nearly 65%in the same period.In the context of globalization,cropland expansion and per capita cropland exhibited spatial imbalances globally,particularly in developing countries.Developing countries saw an increase in total cropland area by 7.09%but a significant decrease in per capita cropland area by 37.38%.From a temporal perspective,the global imbalance has been steadily increasing with the Gini index rising from 0.895 in 1985 to 0.909 in 2022.Consequently,this study reveals an increasing imbalance of global per capita cropland across various countries,which threatens the attainment of the targets of SDG 2.
基金financially supported by the National Natural Science Foundation of China(Grant No.42377321)。
文摘Cropland is persistently affected by soil loss by water erosion in China,which causes economic loss and threatens soil health.Integrating crop switching and improved management provides a promising strategy for controlling soil loss by water erosion in cropland and promoting sustainable agriculture.However,optimizing crop composition with fewer inputs involves balancing agricultural resource use with environmental costs.Aiming to explore the potential of crop switching as a strategy for mitigating soil erosion in cropland,we develop a spatial optimization model that redistributes the sown areas of different crops in each prefecture-level city based on existing resource availability.Our findings gained from our simulations show that crop switching in China alone can reduce total soil erosion in cropland by an estimated 13%.Furthermore,combining crop switching with improved agricultural management practices can further reduce soil erosion in cropland by an estimated 25%.Cereals including maize,wheat,and rice demonstrate significant potential for reducing soil erosion in cropland.Shifting major maize-producing areas northward could result in a substantial decrease in soil erosion,ranging from 10% to 19% of historical soil erosion in cropland.These results offer implications for formulating regional strategy in mitigating soil erosion challenges in China while maximizing the benefits from existing agricultural resource.
基金supported by the National Key R&D Program of China(2023YFD1900300)the State Administration of Foreign Experts Affairs of China(B12007)+1 种基金the 111 Project of Chinathe support by the China Scholarship Council(202306300092).
文摘Cropland abandonment has become a global issue that poses significant threats to sustainable cropland management,national food security,and the ecological environment.Remote sensing technology is crucial for identifying and monitoring abandoned cropland in large-scale areas.However,limited information is available on the effective identification methods and spatial distribution patterns of abandoned cropland in the hilly and gully regions.This study introduced two methods-the land-use trajectory and normalized difference vegetation index(NDVI)time series-for monitoring abandoned cropland and evaluating its spatial distribution in Yanhe River Basin using Landsat-8 images from 2019 to 2021.The results showed that using a random forest algorithm,high-precision annual land-use classifications were achieved with the generation of reliable land-cover samples and an optimized feature dataset.The overall accuracy(OA)and Kappa coefficient of the land-use maps exceeded 90% and 0.88,respectively,demonstrating the effectiveness of the classification over three years.These two distinct change detection methods were used to identify abandoned cropland in the study area,and their accuracy and effectiveness were evaluated.The land-use trajectory method performed better than the NDVI time series method for extracting abandoned cropland,with an OA of 83.5% and an F1 score of 84.7%.According to the land-use trajectory detection results,the study area had 164.6 km^(2) of abandoned cropland area in 2021,with an abandonment rate of 16.3%.Furthermore,cropland abandonment mainly occurred in the northwestern part of the region,which has harsh natural conditions,while abandonment was rare in the southern and eastern regions.Topography and landforms significantly influenced the spatial distribution of abandoned cropland,with most abandoned cropland located in mountainous regions with higher elevations and steeper slopes.The abandonment rate generally increased with the elevation and slope.These findings provide valuable references and guidance for selecting appropriate methods to identify abandoned cropland and analyze its spatial distribution in the hilly and gully regions.Our proposed methods offer robust solutions for monitoring abandoned cropland and optimizing land-use change detection in similar regions with complex landforms.
基金financially supported by the National Key Research and Development Program of China(Grant No.2023YFF0805704)the Strategic Priority Research Program of the Chinese Academy of Sciences(Grant No.XDA28020503)。
文摘Exposure assessment is critical for hazard risk management.It is important to investigate the cropland exposure to compound drought and heatwave(CDHW)events because of their severe impacts on agriculture.We quantified the variations in CDHW characteristics(i.e.,frequency,duration,and magnitude)and the cropland exposure to CDHW events in Northeast China using 20 CMIP6 climate projections for each of the four Shared Socioeconomic Pathways(i.e.,SSP126,SSP245,SSP370,and SSP585).The results indicate that the intensification of CDHW events leading to an anticipated increase in cropland exposure ranges from 1.6-fold to 5.8-fold(the range describes the differences among SSPs),with the west and northeast of the region poised to experience more pronounced increases.Notably,adherence to the SSP126 pathway can reduce both the increase rate of CDHW magnitude and cropland exposure compared to other SSPs.Path analysis demonstrates that cropland exposure is primarily driven by maximum temperature(Tmax).Although precipitation(Pre)increases(0.36-0.75 mm year^(-1)),the rise in potential evapotranspiration(PET)due to global warming is higher than that of Pre(0.26-1.07 mm year^(-1))except for SSP126,resulting in more drought events.Futhermore,elevated Tmax increases the frequency of extreme temperature events.Therefore,increases in Tmax and agricultural land area collectively contribute to exposure rise,with Tmax being the dominant factor in this process.Our findings emphasize the pivotal role of regulating the development pathway into SSP126 for sustainable agriculture,and optimizing crop patterns and planting heat-tolerant crop varieties are recommended for CDHW adaption.
基金National Natural Science Foundation of China,No.42361144881,No.42201310The Third Xinjiang Scientific Expedition Program,No.2021xjkk0900。
文摘Agricultural greenhouse gas(GHG)emissions are influenced by a combination of climate,soil and agricultural management practices.Over the past 30 years,approximately 5% of China's cropland has shifted from the south to the north.This shift has significantly altered the geographical environment,with potential substantial impacts on agricultural GHG emissions.This study used the DeNitrification DeComposition(DNDC)process-based model to simulate GHG emissions(CH_(4)and N_(2)O)from the production of China's 10 major food crops and explored changes in agricultural GHG emissions caused by the spatial shift of cropland in China.Results from the validated DNDC model indicate that total emissions from the major food crop production in China were approximately 343 Tg CO_(2)-eq yr^(-1)with CH_(4)emissions accounting for about 74%.Meanwhile,the spatial shift of cropland from 1990 to 2020 resulted in a 3% decrease in average CH_(4)emissions per unit cropland area and an 8% increase in average N_(2)O emissions per unit cropland area,respectively.The expansion of dryland in the Northwest Arid Region emitted less CH_(4)but significantly more N_(2)O,thereby driving changes in national GHG emissions.This study provides a scientific foundation for the sustainable use of cropland and the formulation of strategies to reduce agricultural GHG emissions.
基金Under the auspices of Hainan Provincial Natural Science Foundation of China(No.321QN187,723RC466)Scientific Research Foundation of Hainan University(No.kyqd(sk)2135)Young Scholars Support Program of Hainan University(No.24QNFC-05)。
文摘Rapid climate and cropland use changes in recent decades have posed major challenges to food security in China.Hainan Is-land is the only tropical island in China and is blessed with natural conditions for crop production.This study first simulates the climate scenarios of Hainan Island for 2030,2040 and 2050 under the four Socio-economic Pathways(SSPs)based on the climate models in ScenarioMIP of Coupled Model Intercomparison Project Phase 6(CMIP6),and then simulates the land use scenarios of Hainan Island for 2030,2040 and 2050 based on the Cellular Automata(CA)-Markov model.Finally,based on the Global Agro-Ecological Zones(GAEZ)model,the rice potential yield in Hainan Island for 2030,2040 and 2050 are simulated,and the effects of future climate and cropland use changes on rice potential yields are investigated.The results show that:1)from 2020 to 2050,mean maximum temperature first decreases and then increases,while mean minimum temperature increase sharply followed by a leveling off under the four SSPs.Precipitation decreases and then increases under other three SSPs except SSP2-4.5.Net solar radiation increases continuously under SSP1-2.6,2-4.5,and 5-8.5,and has the lowest simulated values under SSP3-7.0.Mean wind speed increases continuously under SSP1-2.6,fluctuates more under SSP2-4.5 and SSP5-8.5,and increases slowly and then decreases sharply under SSP3-7.0.Relative humidity basically decreases continuously under the four SSPs.2)Areas of paddy field are 302.49 thousand,302.41 thousand and 302.71 thou-sand ha for 2030,2040 and 2050,respectively,all less than that in 2020.Paddy field is mainly converted into built-up land and wood-land.As for the conversion of other land types to paddy field,woodland is the main source.3)Under the effects of future climate and cropland use changes,the mean potential productions in Hainan Island under the four SSPs increase 1.17 million,1.13 million and 1.11 million t,respectively,and the mean potential yields increase 3873.21,3766.71 and 3672.38 kg/ha,respectively for the three periods.The largest increases in mean rice potential production and mean potential yield are 1.21 million t and 4008.00 kg/ha,1.16 million t and 3846.65 kg/ha,as well as 1.13 million t and 3732.75 kg/ha,respectively under SSP 3-7.0,indicating that SSP3-7.0 is the most suitable scenario for rice growth.This study could provide scientific basis for crop planting planning and agricultural policy adjustment.
基金Under the auspices of Knowledge Innovation Programs of Chinese Academy of Sciences (No KSCX1-YW-09-01)
文摘There are more people but less land in China,so food safety has always been a most important issue government concerned.With continuous population increase,economic development and environment protection,cropland occupation and supplement are unavoidable.It not only leads to the variation of cropland area,but also makes the light-temperature potential productivity per unit area different due to regional climate differentiation,therefore impacts the total potential productivity and food output eventually.So,it is necessary to analyze the climate differentiation between occupation and supplement cropland areas and to study its impact on total potential productivity,which is significant to reasonably develop natural resources and instruct agricultural arrangement.This study firstly discussed the variation and distribution of occupation and supplement croplands in China from 2000 to 2008,then analyzed the climate differentiation between occupation and supplement cropland areas and its effect on light-temperature potential productivity.The results demonstrate:1) From 2000 to 2008,the cropland variation presented occupation in the south and supplement in the north,but overall decreased.Supplement cropland was mainly from ecological reclamation(77.78%) and was mainly distributed in Northeast China and Northwest China with poor climatic and natural conditions.Occupation cropland was mainly used for construction(52.88%) and ecological restoration(44.78%) purposes,and was mainly distributed in the Huang-Huai-Hai Plain,and the middle and lower reaches of the Changjiang(Yangtze) River with better climatic and natural conditions.2) The climate conditions were quite different in supplement and occupation cropland areas.The annual precipitation,annual accumulated temperature and average annual temperature were lower in the supplement cropland area,and its average po-tential productivity per unit was only 62% of occupation cropland area,which was the main reason for the decrease of total potential productivity.3) Cropland occupation and supplement led to the variation of total potential productivity and its spatial distribution.The productivity decreased in the south and increased in the north,but had a net loss of 4.38315×107 t in the whole country.The increase of cropland area was at the cost of reclaiming natural forest and grassland resources,and destroying natural ecological environment,while the decrease of cropland area was mainly due to a lot of cropland occupied by urban-rural construction,which threatened the sustainable use of cropland resources.
基金Supported by National Natural Science Foundation of China(70873118)the Chinese Academy of Sciences (kzcx2-yw-305-2)the national key scientific and technological project(2006BAC08B03,2006BAC08B06,2008BAC43B01)~~
文摘In order to deal with the global change and to reduce emission of greenhouse gas, a number of countries have strengthened studies on carbon sequestration in cropland. Carbon sequestration in cropland is not only an important component for the global carbon stock, but also is the most active part to sequestrate the carbon in soil from atmosphere. In this sense, it is of necessity and significance to strengthen the study on management of carbon sequestration in cropland. Based on the main factors affecting carbon cycle in agro-ecosystems, this paper summarizes the relevant management measures to strengthen the capacity of reducing emission of carbon and increasing the carbon sequestration in cropland, and evaluates the effects of these measures after being implemented at a regional extent.
基金Supported by National Natural Science Foundation of China(31270488,31501274)~~
文摘Methane is an important greenhouse gas, and farmland is one of the im- portant emission sources of methane. Therefore, it's important to study the discharge of methane from cropland. This paper reviewed the methane emission from agricultural ecosystem, the factors controlling CH4 fluxes from soil, such as water regime, the soil characteristics, and the type and amount of applied fertilizers and so on, the management for mitigation of CH4 emission from cropland, especially from paddy field, and put forward some research suggestions on methane emission in the future. The objective of this paper is to provide reference for controlling methane emission in cropland.
基金Supported by the National Basic Research Program of China [2009CB421307 (2009-2013)]the Natural Science Foundation of China [40971282(2010-2012)]~~
文摘[Objective] This study aimed to analyze the sustainability of cropland use in cropping-pastoral ecotone before and after the Grain-for-Green Policy. [Method] Using Yanchi County in Ningxia Hui Autonomous Region as a case study area, this investigation used the annual transfer rate of land use types, cropland suitability and emergy analysis to examine the major pressures affecting the sustainable use of cropland before and after the Grain-for-Green Policy. [Result] The expansion of con- struction land onto cropland was significant; the annual cropland area was still larger than the land area suitable for cropping after the policy; agrochemical inputs used for crop production gradually increased and unit crop outputs required more agro- chemical inputs. Cropland use sustainability showed a fluctuating downward trend. [Conclusion] The results imply that the protection of high quality cropland, further im- plementation of the policy and control of agrochemical inputs according to precipita- tion are the main measures needed for sustainable cropland use in cropping-pastoral ecotone.
基金supported by the National Science and Technology Major Project(2015ZX07203-005)the National Program for Support of Top-notch Young Professionals
文摘Agriculture is a large source of carbon emissions. The cropland practices of fertilizer substitution, crop straw and conservation tillage are beneficial and help to rebuild local soil carbon stocks and reduce soil carbon emissions, in addition to reducing the consumption of fertilizers and fossil fuels. These improved cropland practices can directly and indirectly mitigatecarbon emissions, benefiting the sustainability of croplands. For these three improved practices, we estimated carbon mitigation potentials in rice, wheat and maize croplands in China. The combined contribution of these practices to carbon mitigation was 38.8 Tg C yr-1, with fertilizer substitution, crop straw return, and conservation tillage contributing 26.6, 3.6 and 8.6 Tg C yr-1, respectively. Rice, wheat and maize croplands had potentials to mitigate 13.4, 11.9 and 15.5 Tg C yr-1, respectively, with the combined direct and indirectpotential of 33.8 and 5.0 Tg C yr-1. Because of differences in local climate and specific diets, the regional cropland carbon mitigation potentials differed greatly among provinces in China. In China, 18 provinces had a "target surplus" for which the carbon mitigation from these three practices was larger than the mitigation target set for 2020. At the national level, a net "target surplus"of 4.84 Tg C yr-1 would be attained for Chinese croplands with full implementation of the three improved practices. Regional cooperation must be developed to achieve carbon mitigation targets using such measures as carbon trading, establishing regional associations, and strengthening research programs to improve practices.
文摘The study of the spatial patterns and temporal changes of cropland is important to understand the underlying factors and the functional effects of the agricultural landscape. On the other hand, crop dynamics mapping is essential to know the overall agro-spatial diversity of the area. Therefore, this paper addressed a spatio-temporal analysis of cropland and cropping pattern change in the Bogra district of Bangladesh over the last 16 years (between 1988/89 and 2004/05). In this paper, crop mapping from multi-temporal and multi-sensor satellite images was described. Landsat TM and IRS P6 LlSS Ⅲ satellite images were used with GIS for spatial dynamics of cropland and cropping pattern change analysis. First, seasonal cropland maps were derived from object-based classification of satellite images, then two-date classified image differencing with GIS overlay technique and decision rules were applied. Cropping pattern change was analyzed in a spatial and quantitative way for the 16 years and for this, Integrated Land and Water Information System (ILWIS) and Land Change Modular (LCM) of IDRISl Andes were used. The results showed that in the area, mono crop cultivation was found in summer, but in winter, areas under different crop cultivation had changed dramatically. Change analysis showed that the changes mainly occurred in the north northwest and southwest of the areas, and during the time the highest change area was found under the rice-potato pattern.
基金National Natural Science Foundation of China,No.41771116,No.41501095National Basic Research Program of China,No.2015CB452705National Key Research and Development Program of China,No.2016YFC0502103
文摘From 1992 to 2015, ecological environment has been threatened by the changes of cropland around the world. In order to evaluate the impact of cropland changes on ecosystem, we calculated the response of terrestrial ecosystem service values (TESVs) variation to cropland conversion based on land-use data from European Space Agency (ESA). The results showed that cropland changes were responsible for an absolute loss of $166.82 billion, equivalent to 1.17% of global TESVs in 1992. Among the different regions, the impact of cropland changes on TESVs was significant in South America and Africa but not obvious in Oceania, Asia and Europe. Cropland expansion from tropical forest was the main reason for decreases in TESVs globally, especially in South America, Africa and Asia. The effect of wetland converted to cropland was notable in North America and Europe while grassland converted to cropland played an important role in Oceania, Africa and Asia. In Europe, the force of urban expansion cannot be ignored as well. The conversion of cropland to tropical or temperate forest partly compensated for the loss of TESVs globally, especially in Asia.
