Financial Support for Agriculture, Chemical Fertilizer Use, and Carbon Emissions from Agricultural Production in China

Guo, Lili; Guo, Sihang; Tang, Mengqian; Su, Mengying; Li, Houjian

doi:10.3390/ijerph19127155

Cited by 40 publications

(21 citation statements)

References 60 publications

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“…The essence of the urbanization process is a multidimensional transmutation process accompanied by the flow of capital, labor, technology, and other factors from the countryside to the city, and the reconfiguration of factors between urban and rural areas, which has a great impact on the production scale and cultivation structure of agriculture (Tian et al, 2016;Xiong et al, 2020;Joséf, 2022); 4) rural labor education level differences (ED) is expressed by the average years of education of rural residents. The labor force is the decision maker of agricultural production methods and its level of education has a significant impact on the adoption and application of pioneering technologies (Wang et al, 2019;Wu et al, 2021;Khanh and Nguyen, 2022); 5) financial development level differences (FI) is expressed by the ratio of deposit and loan balance of financial institutions to GDP, a sound financial service system can provide financial support for agricultural transformation and upgrading and green technology progress (Huang et al, 2014;Cao et al, 2022;Gao et al, 2022); 6) agricultural irrigation water utilization rate differences (WA) is expressed by the ratio of effective irrigated area to cultivated area in each region, agricultural irrigation water use efficiency can affect agricultural carbon emissions and output efficiency by changing inter-regional agricultural production costs and intra-agricultural production structure (Xu et al, 2022); 7) farmland operation scale differences (SC) is expressed by the per capita crop sown area, it has been proven that the scale of agricultural production leads to differences in the cost of adoption of agricultural technology, and that larger scale of operation makes it easier to obtain economies of scale and adopt advanced technology (Helfand and Taylor, 2021;Mao et al, 2021); 8) financial support differences (IN) is expressed by the proportion of local financial expenditure on agriculture, many scholars have found that financial support for agriculture significantly affects agricultural carbon emissions (Guo et al, 2022); 9) marketization level differences (MA) is expressed by the marketization index measurements, according to (Fan et al, 2011). The level of marketization determines the flow and allocation of production factors and therefore has an impact on the spatial association network .…”

Section: Analysis Of Driving Factors Of Spatial Association Network O...mentioning

confidence: 99%

Spatial correlations and driving mechanisms of low-carbon agricultural development in china

Fang

Zhao

et al. 2022

Front. Environ. Sci.

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Low-carbon agricultural development in China is a prerequisite for rural revitalization and a key to achieving socio-economic green transformation. This paper used agricultural data from 30 Chinese provinces from 2001 to 2020, considering both carbon emissions from farming and livestock, agricultural low-carbon total factor productivity (ALTFP) was measured using the RSBM-GML index. Based on this, the network characteristics and driving mechanisms of low-carbon synergistic development in agriculture were explored with the help of an improved gravity model and social network analysis, and the dominant provinces in low-carbon synergistic development in agriculture are identified. The study revealed that the spatially linked network of ALTFP in China exhibits multi-threaded characteristics of spillover to non-adjacent provinces, and the whole network has a sparse structure and hierarchy. The eastern regions such as Beijing, Tianjin, Shanghai, Jiangsu, and Zhejiang are at the core of the network, with closer ties to other regions and a stronger role in allocating resources. While the western regions such as Xinjiang, Qinghai, and Gansu are located at the periphery of the network, with weaker access to the resources. Meanwhile, the spatial proximity of provinces, the widening of differences in urbanization levels and differences in financial support for agriculture, and the narrowing of differences in the educational attainment of rural labor have significantly contributed to the formation of provincial spatial linkages. This study reveals that China’s government needs to give full play to the role of core regions as “leaders”, and promote the balanced and coordinated regional development of low-carbon agriculture in China. In addition, policy makers should further optimize the spatial allocation of agricultural resource elements between provinces. The findings of the study provide reference suggestions for the development of regionally differentiated agricultural low-carbon development plans.

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Section: Analysis Of Driving Factors Of Spatial Association Network O...mentioning

confidence: 99%

Spatial correlations and driving mechanisms of low-carbon agricultural development in china

Fang

Zhao

et al. 2022

Front. Environ. Sci.

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“…Studies have shown that FDI (Foreign direct investment) in agriculture has a positive impact on the intensity of CO2 equivalent emissions in developing countries (Kastratović 2019). Studies have shown that agricultural financial support and fertiliser use have a significant impact on carbon emissions from agricultural production in China Guo et al (2022).…”

Section: Introductionmentioning

confidence: 99%

Prediction model and demonstration of regional agricultural carbon emissions based on PCA-GS-KNN: a case study of Zhejiang province, China

Qi¹,

Liu²,

Zhao³

et al. 2023

Environ. Res. Commun.

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This paper proposes a prediction algorithm combining principal component analysis (PCA), grid search (GS) and K-nearest neighbor (KNN). First, to solve the multicollinearity problem in multiple regression, principal component analysis is applied to select the principal components of regression variables; then, the K-nearest neighbor regression prediction model is used for data training, and the grid search is used to obtain better prediction model parameters to solve the problem of parameter selection in the traditional prediction model of K-nearest neighbor regression; finally, the optimized prediction model is used to demonstrate the regional agricultural carbon emissions, taking Zhejiang Province of China as a case. The results show that the algorithm is superior to other prediction models in prediction accuracy, and can accurately predict regional agricultural carbon emissions.

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“…Agricultural activity is one sector that contributes to the production of GHG emissions into the atmosphere such as methane (CH 4 ), nitrogen dioxide (NO 2 ), and also carbon dioxide (CO 2 ) [1,2,3,4,5]. Carbon dioxide is produced from decomposition by microbes and burning dead organic matter such as twigs and pruned leaves which can be used as fertilizer [6,7,8].…”

Section: Introductionmentioning

confidence: 99%

Estimation of greenhouse gases in rice fields and plantations in Teluk Bintuni Regency, West Papua

Dudung,

Abbas,

Martanto

et al. 2023

IOP Conf. Ser.: Earth Environ. Sci.

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The study purpose was to estimate greenhouse gases produced in agricultural sector in Teluk Bintuni Regency. Data were taken from 15 farmer groups from 15 districts, and 6 families of rice farmers assisted by Tangguh LNG’ CSR. The calculation method uses IPCC 2006 Tier 2. The correction factor used in calculating Bintuni’s GHG is adjusted based on land area, soil type, type of fertilizer, and type of irrigation used. The results show that paddy farming activities by rice farmers assisted by Tangguh LNG CSR produce CH4 of 964.45 kg/year, or CO2 of 20.253,54 kg/year. Fertilization activities on paddy fields produced direct emissions of 1344.51 kg CO2, indirect emissions of 436.97kg CO2, fertilizing activities of paddy fields using NPK produced direct NO2 emissions equivalent to 456.70 kg CO2, and indirect emissions of 148.43 kg CO2. Fertilization activities on plantation land using ZA fertilizer produced direct NO2 emissions of 2969.74 kg CO2 and indirect emissions of 965.165 kg CO2, NO2 emissions from NPK fertilizer produced direct emissions of 6074.467 and indirect emissions of 1974.20 kg CO2. It is necessary to further implement low-emission agricultural activities through fertilization of the right size and selection of rice varieties and low-emission irrigation systems.

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Financial Support for Agriculture, Chemical Fertilizer Use, and Carbon Emissions from Agricultural Production in China

Cited by 40 publications

References 60 publications

Spatial correlations and driving mechanisms of low-carbon agricultural development in china

Spatial correlations and driving mechanisms of low-carbon agricultural development in china

Prediction model and demonstration of regional agricultural carbon emissions based on PCA-GS-KNN: a case study of Zhejiang province, China

Estimation of greenhouse gases in rice fields and plantations in Teluk Bintuni Regency, West Papua

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