基于PLUS-InVEST模型的区县碳储量时空格局变化与碳汇提升策略——以延庆区为例

doi:10.13287/j.1001-9332.202312.019

摘要/Abstract

摘要： 近年来在碳达峰和碳中和的目标背景下,碳储量时空格局演变成为研究热点,而土地利用与覆被(LULC)变化是碳储量变化的关键原因。在区县级小尺度研究LULC与碳储量的时空演变并提出碳汇提升策略,有助于区县的生态保护修复与可持续发展。本研究以北京市延庆区为研究区,基于InVEST模型计算1990—2020年的碳储量,并采用PLUS模型分别预测2020—2050年3种情景(自然增长、生态保护、经济发展)下的LULC类型变化,并进一步预测碳储量,提出延庆区碳汇提升策略。结果表明: 1990—2020年间,延庆区主要的LULC转换趋势为88.9%的草地转向乔木林、50.1%的耕地转向乔木林、39.5%的耕地转向不透水面;碳储量总体呈上升趋势,增长了3.34×10⁶ Mg,在空间分布上呈现“东北高西南低,山区高川区低”的特征,且乔木林的增加、草地的减少分别是碳储量升高和降低的主要原因。2020—2050年间,生态保护情景下的生态修复力度加大,其他LULC向乔木林转化的概率增加,从而带来碳储量增长5.8%,在3种情景中增幅最大且碳储量值最高。碳储量高值区域在延庆区东北部、西北部和南部出现集聚,基本对应森林覆盖率较高的延庆山区;低值区域基本对应开发强度较大、林木覆盖率较低的平原区。可从林草生态系统保护、水环境生态修复、农田生态修复等方面综合实施生态保护修复措施,推进延庆区可持续发展,助力延庆区实现“双碳”目标。

关键词: 土地利用与覆被变化, 碳储量, PLUS-InVEST模型, 多情景模拟, 延庆区

Abstract: Under the background of the carbon peaking and carbon neutrality goals, the evolution of the spatiotemporal pattern of carbon storage has recently emerged as a research hotspot. The change in land use and land cover (LULC) is the primary driver of carbon storage changes. Understanding the spatiotemporal variations of LULC and carbon storage at the small scale of district and county level and proposing strategies to improve carbon sink, will contribute to the ecological conservation, restoration and sustainable development of districts or counties. With Yanqing District in Beijing as an example, we calculated carbon storage from 1990 to 2020 based on the InVEST model and used the PLUS model to predict LULC type changes under three scenarios (natural growth, ecological conservation and economic development) from 2020 to 2050. We further predicted the carbon storage and proposed mea-sures to improve carbon sink. The results showed that the key LULC change in Yanqing between 1990 and 2020 were the conversion of 88.9% of grassland to forest, 50.1% of farmland to forest, and 39.5% of cropland to impervious surface. The total carbon storage showed an upward trend, with an increase of 3.34×10⁶ Mg. The spatial distribution of carbon storage presented “high in the northeast, low in the southwest, and high in the mountainous areas, low in the riverine areas.” The increase in forest and the decrease in grassland were the main reasons for the increase and decrease in carbon storage, respectively. Between 2020 and 2050, the ecological restoration efforts under the ecological protection scenario increased, and the probability of other LULCs transforming into forest increased, resulting in a 5.8% increase in carbon storage, which had the highest increase and carbon storage under the three scenarios. High-value carbon storage areas were concentrated in the northeast, northwest, and south of Yanqing District, basically corresponding to the mountainous regions of Yanqing with high forest coverage, and the low-value areas generally corresponded to the plains with high development intensity and low forest coverage. We could implement comprehensive ecological protection and restoration measures, including forest and grassland ecosystem protection, water environment ecological restoration, farmland ecological restoration, to promote sustainable development in Yanqing District and to achieve the “dual carbon” goal.

Key words: land use and land cover change, carbon storage, PLUS-InVEST model, multi-scenario simulation, Yanqing District

王想, 王春雨, 吕飞南, 陈水灵, 宇振荣. 基于PLUS-InVEST模型的区县碳储量时空格局变化与碳汇提升策略——以延庆区为例[J]. 应用生态学报, 2023, 34(12): 3373-3384.

WANG Xiang, WANG Chunyu, LYU Feinan, CHEN Shuiling, YU Zhenrong. Temporal and spatial variations of carbon storage and carbon sink improvement strategy at the district and county level based on PLUS-InVEST model: Taking Yanqing District as an example[J]. Chinese Journal of Applied Ecology, 2023, 34(12): 3373-3384.

参考文献

[1] 王天福, 龚直文, 邓元杰. 基于土地利用变化的陕西省植被碳汇提质增效优先区识别. 自然资源学报, 2022, 37(5): 1214-1232
[2] 郭虹宇. 《联合国气候变化框架公约》第25次缔约方大会观察. 世界环境, 2020(1): 46-49
[3] 曲建升, 陈伟, 曾静静, 等. 国际碳中和战略行动与科技布局分析及对我国的启示建议. 中国科学院院刊, 2022, 37(4): 444-458
[4] 王国胜, 孙涛, 昝国盛, 等. 陆地生态系统碳汇在实现“双碳”目标中的作用和建议. 中国地质调查, 2021, 8(4): 13-19
[5] 王晓东, 蒙吉军. 土地利用变化的环境生态效应研究进展. 北京大学学报:自然科学版, 2014, 50(6): 1133-1140
[6] Zaehlez S, Bondeaub A, Carter TR, et al. Projected changes in terrestrial carbon storage in Europe under climate and land-use change, 1990-2100. Ecosystems, 2007, 10: 380-401
[7] 崔旺来, 蔡莉, 奚恒辉, 等. 基于土地利用/覆盖变化的浙江大湾区生态安全评价及多情景模拟分析. 生态学报, 2022, 42(6): 2136-2148
[8] 杨潋威, 赵娟, 朱家田, 等. 基于PLUS和InVEST模型的西安市生态系统碳储量时空变化与预测. 自然资源遥感, 2022, 34(4): 175-182
[9] 邓喆, 丁文广, 蒲晓婷, 等. 基于InVEST模型的祁连山国家公园碳储量时空分布研究. 水土保持通报, 2022, 42(3): 324-334
[10] 庄子薛, 谢梦晴, 张文萍, 等. 基于FLUS-InVEST模型的碳储量时空变迁及多情景模拟预测——以成德眉资地区为例. 风景园林, 2022, 29(5): 38-44
[11] 谢向东, 林孝松, 王莹, 等. 基于PLUS模型的重庆市南川区土地利用多情景模拟. 长江科学院院报, 2023, 40(6): 86-92
[12] Liang X, Guan Q, Clarke KC, et al. Understanding the drivers of sustainable land expansion using a patch-generating land use simulation (PLUS) model: A case study in Wuhan, China. Computers, Environment and Urban Systems, 2021, 85: 101569
[13] 孟帆, 黄江松. 零碳北京的战略意义和实施路径. 前线, 2021(8): 63-66
[14] 中华人民共和国生态环境部. 关于实施“三线一单”生态环境分区管控的指导意见(试行)[EB/OL]. (2021-11-19) [2023-03-30]. https://www.mee.gov.cn/xxgk2018/xxgk/xxgk03/202111/t20211125_961692.html
[15] 张梦迪, 张芬, 李雄. 基于InVEST模型的生境质量评价——以北京市通州区为例. 风景园林, 2020, 27(6): 95-99
[16] Xiang S, Wang Y, Deng H, et al. Response and multi-scenario prediction of carbon storage to land use/cover change in the main urban area of Chongqing, China. Ecological Indicators, 2022, 142: 109205
[17] Li P, Chen J, Li Y, et al. Using the InVEST-PLUS model to predict and analyze the pattern of ecosystem carbon storage in Liaoning Province, China. Remote Sensing, 2023, 15: 4050
[18] 李俊, 杨德宏, 吴锋振, 等. 基于PLUS与In VEST模型的昆明市土地利用变化动态模拟与碳储量评估. 水土保持通报, 2023, 43(1): 378-387
[19] Gong W, Duan X, Sun Y, et al. Multi-scenario simulation of land use/cover change and carbon storage assessment in Hainan coastal zone from perspective of free trade port construction. Journal of Cleaner Production, 2023, 385: 135630
[20] 杨朔, 苏昊, 赵国平. 基于PLUS模型的城市生态系统服务价值多情景模拟——以汉中市为例. 干旱区资源与环境, 2022, 36(10): 86-95
[21] 邵壮, 陈然, 赵晶, 等. 基于FLUS与InVEST模型的北京市生态系统碳储量时空演变与预测. 生态学报, 2022, 42(23): 9456-9469
[22] 林晋大, 多玲花, 邹自力. 城市扩张背景下景观破碎化动态演变及空间自相关分析——以南昌市为例. 水土保持研究, 2022, 29(4): 362-369
[23] Yang J, Huang X. The 30 m annual land cover dataset and its dynamics in China from 1990 to 2019. Earth System Science Data, 2021, 13: 3907-3925
[24] Wu W, Xu L, Zheng H, et al. How much carbon sto-rage will the ecological space leave in a rapid urbanization area? Scenario analysis from Beijing-Tianjin-Hebei Urban Agglomeration. Resources, Conservation and Recycling, 2023, 189: 106774
[25] 梁晨, 安菁, 范雅倩, 等. 北京松山国家级自然保护区典型植被类型表层土壤碳密度及周转速率特征. 地球与环境, 2020, 48(6): 672-679
[26] 聂浩亮, 薄慧娟, 张润哲, 等. 北京海坨山典型林分土壤有机碳含量及有机碳密度垂直分布特征. 林业科学研究, 2020, 33(6): 155-162
[27] 杨鑫, 高雯雯, 李莎, 等. 基于遥感影像估算的北京中心城区碳储量与气候环境关联性研究. 风景园林, 2022, 29(5): 31-37
[28] 蒋九华, 齐实, 胡俊, 等. 基于InVEST模型的北京山区森林生态系统碳储量评估分析. 地球与环境, 2019, 47(3): 326-335
[29] 周萌硕. 基于InVEST的森林生态服务功能碳储量估算. 博士论文. 北京: 北京林业大学, 2019
[30] 李瑾璞. 基于InVEST模型的土地利用变化与生态系统碳储量研究. 博士论文. 保定: 河北农业大学, 2020
[31] 北京延庆. 生态坚守丨延庆:守护绿水青山生态赢得未来[EB/OL]. (2022-04-28) [2023-08-01]. https://www.sohu.com/a/541932592_454655
[32] 北京市人民政府. 延庆概况[EB/OL]. (2023-08-01) [2023-08-01]. https://www.beijing.gov.cn/renwen/bjgk/yqgk/index.html
[33] 岳建兵, 胡理乐. 基于InVEST模型的北京市延庆区自然保护地生境质量评估. 林业调查规划, 2023, 48(3): 59-66
[34] 杜箫宇, 吕飞南, 王春雨, 等. 基于MSPA-Conefor-MCR的县域尺度生态网络构建——以延庆区为例. 应用生态学报, 2023, 34(4): 1073-1082
[35] Liang Y, Hashimoto S, Liu L. Integrated assessment of land-use/land-cover dynamics on carbon storage services in the Loess Plateau of China from 1995 to 2050. Ecological Indicators, 2021, 120: 106939
[36] Li T, Zhang Q, Zhang Y. Modelling a compensation standard for a regional forest ecosystem: A case study in Yanqing District, Beijing, China. International Journal of Environmental Research and Public Health, 2018, 15: 565
[37] 罗明, 宇振荣, 应凌霄. 从生态系统健康视角看土地综合整治. 中国土地, 2020(2): 4-8
[38] 吴文颖. 北京延庆:城乡生态空间碳汇功能初探. 北京规划建设, 2021(5): 105-108
[39] 赖瑾瑾. 城乡生态绿地空间的碳汇功能评估——以北京市延庆县为例. 河南科技学院学报:自然科学版, 2013, 41(4): 30-34