高宇, 刘欢, 鲍立佳, 石琳, 吴江. 基于格网和PLUS模型的大西安地区碳排放量估算与模拟[J]. 中国生态农业学报 (中英文), 2023, 31(10): 1553−1564. DOI: 10.12357/cjea.20230081
引用本文: 高宇, 刘欢, 鲍立佳, 石琳, 吴江. 基于格网和PLUS模型的大西安地区碳排放量估算与模拟[J]. 中国生态农业学报 (中英文), 2023, 31(10): 1553−1564. DOI: 10.12357/cjea.20230081
GAO Y, LIU H, BAO L J, SHI L, WU J. Estimation and simulation of carbon emissions in Great Xi’an based on grid and patch-generated land-use simulation models[J]. Chinese Journal of Eco-Agriculture, 2023, 31(10): 1553−1564. DOI: 10.12357/cjea.20230081
Citation: GAO Y, LIU H, BAO L J, SHI L, WU J. Estimation and simulation of carbon emissions in Great Xi’an based on grid and patch-generated land-use simulation models[J]. Chinese Journal of Eco-Agriculture, 2023, 31(10): 1553−1564. DOI: 10.12357/cjea.20230081

基于格网和PLUS模型的大西安地区碳排放量估算与模拟

Estimation and simulation of carbon emissions in Great Xi’an based on grid and patch-generated land-use simulation models

  • 摘要: 土地利用变化导致区域碳排放显著变化, 估算由土地利用变化导致的碳排量变化可以为区域“双碳”目标的实现提供重要实践参考。为摸清大西安地区1990—2020年土地利用类型时空演变规律及其碳排放效应, 基于排放因子法和PLUS (patch-generating land use simulation)模型, 从行政单元和栅格两种尺度, 探索研究区土地利用和碳排放的时空演变关系并模拟其未来分布模式。研究结果表明: 1) 1990—2020年, 耕地面积持续减少, 年均减少21.86 km2; 林地、草地和水域面积波动减少, 年均减少面积分别为0.28 km2、1.69 km2和0.08 km2; 建设用地面积持续扩张, 年均扩张面积23.88 km2; 未利用地面积波动增加, 增加面积为1.14 km2。2) 1990—2020年, 大西安地区碳排放量由280.00 t(C)∙a−1增长至2342.27 t(C)∙a−1, 年均增长68.74 t(C); 空间分布总体呈“南高北低”的格局。3) 1990—2020年, 大西安地区碳排放强度最大值由7461.94 t(C)∙km−2∙a−1增加至45 400.90 t(C)∙km−2∙a−1, 增长了5.08倍。空间上, 该地区碳排放强度始终呈现出“北高南低”的分布模式。4) 2025年和2030年, 大西安地区依旧是以耕地和林地为主要土地利用类型, 其面积之和分别占研究区总面积的63.53%和62.45%; 2020—2030年, 该区域内耕地、林地、水域和未利用地面积持续减少, 而草地和建设用地面积增加, 碳排放总量增加2.96×103万 t(C)∙a−1, 碳排放强度呈现出“东高西低”的分布格局。过去30年, 大西安地区的碳排放量和碳排放强度都在迅速增加。

     

    Abstract: Land use change leads to substantial changes in regional carbon emissions, and estimating changes in carbon emissions caused by land use change provides an important practical reference for promoting the regional realization of “dual carbon” goals. This study aimed to investigate the spatial and temporal evolution patterns of land use types and their carbon emission effects in the Great Xi’an area from 1990 to 2020 and to predict its future carbon emission characteristics. Therefore, in this study, carbon emissions and carbon intensity involving the study area were estimated based on the emission factor method on two scales, administrative units and grids, and carbon emission characteristics of the study area in 2025 and 2030 were simulated using a patch-generated land-use simulation model. The results showed that: 1) from 1990 to 2020, the area of cultivated land continued to decrease, with an average annual decrease of 21.86 km2; the fluctuation of forest land, grassland, and water areas decreased, with an average annual decrease of 0.28 km2, 1.69 km2 and 0.08 km2, respectively; and construction land area continued to expand, with an average annual expansion area of 23.88 km2. The area of unused land fluctuated and increased by 1.14 km2. 2) From 1990 to 2020, carbon emissions in Great Xi’an increased from 280.00 t∙a−1 to 2342.27 t∙a−1, with an average annual growth of 68.74 t. From 2005 to 2010, it had the fastest growth rate of carbon emissions with an average annual growth of 125.86 t, whereas from 1990 to 2000, these grew at the slowest rate, averaging only 10.06 t per year. Whereas spatial distribution patterns were generally high in the south and low in the north, carbon emissions of Chang’an District in the south of the study area were much higher than those of Yanliang District in the north. 3) From 1990 to 2020, the maximum carbon emission intensity in Great Xi’an increased from 7461.94 t(C)∙km−2∙a−1 to 45 400.90 t(C)∙km−2∙a−1, an increase of nearly five-fold. In terms of space, the carbon emission intensity in the region always exhibited a distribution pattern of high in the north and low in the south, the carbon emission intensity of the main city of Great Xi’an was much higher than that of other regions. 4) Between 2025 and 2030, cropland and forest land will continue to be the primary land-use types in the Great Xi’an area, with the sum of their areas accounting for 63.53% and 62.45% of the total study area, respectively. From 2020 to 2030, the areas of cropland, forest land, water, and unused land in the region will continue to decrease, whereas the areas of grassland and construction land will increase. The total carbon emission increased by 2.96×107 t(C)∙a−1, and the carbon emission intensity revealed a distribution pattern of high in the east and low in the west. Carbon emissions and their intensity in the Great Xi’an region have increased rapidly over the past 30 years.

     

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