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management scheme of Pinus sylvestris var. mongolica XUE RHꎬ JIAO Lꎬ ZHANG Pꎬ et al.ꎬ 2023. Response
plantations in sandy lands based on their decline mechanisms sensitivity processes of conifers radial growth to climate
[J]. Chinese Journal of Ecologyꎬ 36(11): 3249-3256. [宋立 factors based on tree ring width variations [ J]. Global
宁ꎬ 朱教君ꎬ 郑晓ꎬ 2017. 基于沙地樟子松人工林衰退机制 Ecology and Conservationꎬ 48: e02743.
13
的营林方案 [J]. 生态学杂志ꎬ 36(11): 3249-3256.] YU FYꎬ ZHANGꎬ JXꎬ SUN YRꎬ et al.ꎬ 2022. Leaf δ C of the
SU Lꎬ HUANG DHꎬ ZHOU LLꎬ 2024. Differences in sediment main afforestation tree species in Horgin Sandy Land
provenance from rainfall and snowmelt erosion in the Mollisol [J]. Forest Researchꎬ 35(4): 179-187. [于丰源ꎬ 张金
region of Northeast China [J]. Earth Surface Processes and 鑫ꎬ 孙一荣ꎬ 等ꎬ 2022. 科尔沁沙地主要造林树种叶片
13
Landformsꎬ 49(8): 2442-2457. δ C比较研究 [J]. 林业科学研究ꎬ 35(4): 179-187.]
SU JRꎬ XIAO SCꎬ PENG XMꎬ et al.ꎬ 2024. Responses of radial ZHANG SLꎬ GAO RHꎬ GAO MLꎬ et al.ꎬ 2023. Prediction of
growth to climate change for two dominant artificial the potential distribution pattern of Pinus sylvestris var.
coniferous trees [J]. Dendrochronologiaꎬ 83: 126163. mongolica in China under climate change [ J]. Journal of
SUN SJꎬ ZHANG JSꎬ ZHOU Jꎬ et al.ꎬ 2021. Long ̄term effects Zhejiang A & F Universityꎬ 40(3): 560-568. [张世林ꎬ 高
of climate and competition on radial growthꎬ recoveryꎬ and 润红ꎬ 高明龙ꎬ 等ꎬ 2023. 气候变化背景下中国樟子松潜
resistance in Mongolian pines [ J ]. Frontiers in Plant 在分布预测 [J]. 浙江农林大学学报ꎬ 40(3): 560-568.]
Scienceꎬ 12: 729935. ZHANG Xꎬ WU MWꎬ KWON Sꎬ et al.ꎬ 2022. Radial growth
TONG YQꎬ 2023. Estimation of the transpiration based on the responses of Mongolian pine ( Pinus sylvestris var.
radial pattern of sap flow and its response to meteorological mongolica) plantations at different ages to climate and
factors in sandy Pinus sylvestris var. mongolica plantations groundwater level changes [J]. Acta Ecologica Sinicaꎬ 42
[D]. Shenyang: Shenyang Agricultural University. [ 童 郁 (16): 6827 - 6837. [ 张 晓ꎬ 吴 梦 婉ꎬ KWON Sꎬ 等ꎬ
强ꎬ 2023. 基于树干液流径向变化的沙地樟子松蒸腾耗 2022. 不同林龄樟子松人工林径向生长对气候及地下水
水估算及影响因素研究 [D]. 沈阳: 沈阳农业大学.] 位变化的响应 [J]. 生态学报ꎬ 42(16): 6827-6837.]
VAN DE POL Mꎬ BAILEY LDꎬ MCLEAN Nꎬ et al.ꎬ 2016. ZHAO Yꎬ CAI LXꎬ JIN YTꎬ et al.ꎬ 2021. Warming ̄drying
Identifying the best climatic predictors in ecology and climate intensifies the restriction of moisture on radial growth
evolution [J]. Methods in Ecology and Evolutionꎬ 7(10): of Pinus tabuliformis plantation in semi ̄arid area of Northeast
1246-1257. China [J]. Chinese Journal of Applied Ecologyꎬ 32(10):
WANG JXꎬ ZHAO HCꎬ SONG QMꎬ et al.ꎬ 2022. Effects of 3459-3467. [赵莹ꎬ 蔡立新ꎬ 靳雨婷ꎬ 等ꎬ 2021. 暖干化加
stand factors on herbaceous species diversity in Pinus 剧东北半干旱地区油松人工林径向生长的水分限制
sylvestris var. mongolica plantations in Zhanggutai areaꎬ [J]. 应用生态学报ꎬ 32(10): 3459-3467.]
Liaoning Province [ J ]. Protection Forest Science and ZHOU FYꎬ WANG SNꎬ ZHANG Fꎬ et al.ꎬ 2025. Response of
Technology(4): 17-20. [王景玺ꎬ 赵浩唱ꎬ 宋启民ꎬ 等ꎬ radial growth of Pinus sylvestris var. mongolica to climate
2022. 林分因子对辽宁章古台樟子松人工林草本植物多 change at different ages on sandy land [J]. Chinese Journal
样性的影响 [J]. 防护林科技(4): 17-20.] of Ecologyꎬ 44(6): 1847-1856. [周凤艳ꎬ 王赛男ꎬ 张帆ꎬ
WEN Sꎬ SHI ZJꎬ ZHANG Xꎬ et al.ꎬ 2023. Effect of climate and 等ꎬ 2025. 不同林龄沙地樟子松径向生长对气候变化的
competition on radial growth of Pinus sylvestris var. 响应 [J]. 生态学杂志ꎬ 44(6): 1847-1856.]
mongolica forest in Hulunbuir sandy land of Inner Mongoliaꎬ ZHOU YPꎬ LEI ZYꎬ ZHAO GJꎬ et al.ꎬ 2018. Impacts of plant
China [J]. Plants ̄Baselꎬ 12(13). diseases and insect pests on tree height growth of Pinus
WU Jꎬ GAO XJꎬ GIORGI Fꎬ et al.ꎬ 2017. Changes of effective sylvestris var. mongolica plantations on sandy land [J]. Arid
temperature and cold/ hot days in late decades over China Zone Researchꎬ 35(3): 653-661. [周晏平ꎬ 雷泽勇ꎬ 赵国
based on a high resolution gridded observation dataset 军ꎬ 等ꎬ 2018. 病虫害对沙地樟子松树高生长的影响
[J]. International Journal of Climatologyꎬ 37(S1): 788-800. [J]. 干旱区研究ꎬ 35(3): 653-661.]
WU Jꎬ GAO XJꎬ 2013. A gridded daily observation dataset over ZHU JJꎬ ZHENG Xꎬ 2019. The prospects of development of the
China region and comparison with the other datasets Three ̄North Afforestation Program(TNAP): On the basis of
[J]. Chinese Journal of Geophysicsꎬ 56 ( 4 ): 1102 - the results of the 40 ̄year construction general assessment of
1111. [吴佳ꎬ 高学杰ꎬ 2013. 一套格点化的中国区域逐日 the TNAP [J]. Chinese Journal of Ecologyꎬ 38(5): 1600-
观测资料及与其它资料的对比 [J]. 地球物理学报ꎬ 1610. [朱教君ꎬ 郑晓ꎬ 2019. 关于三北防护林体系建设的
56(4): 1102-1111.] 思考与展望———基于 40 年建设综合评估结果 [J]. 生态
XU Yꎬ GAO XJꎬ SHEN Yꎬ et al.ꎬ 2009. A daily temperature 学杂志ꎬ 38(5): 1600-1610.]
dataset over China and its application in validating a RCM
simulation [J]. Advances in Atmospheric Sciencesꎬ 26(4): (责任编辑 周翠鸣)
763-772.
