郭金堂, 姜鹏, 郭凯, 等. 2016. 针阔混交林华北落叶松生物量模型及碳储量研究. 西北林学院学报, 31(2): 45-48. Guo J T, Jiang P, Guo k, et al. 2016. Biomass model and carbon storage of Larix principis var. Huabei mixed forest. Journal of Northwest Forestry University, 31(2): 45-48. [in Chinese] 贾庆彬, 张含国, 姚宇, 等. 2014. 长白落叶松高固碳种源选择研究. 林业科学研究, 27(3): 341-348. Jia Q B, Zhang H G, Yao Y, et al. 2014. Study on the selection of high carbon fixation provenance of Larix olgensis. Forest Research, 27(3): 341-348. [in Chinese] 康向阳. 2019. 关于林木无性系育种策略的思考. 北京林业大学学报, 41(7): 1-9. Kang X Y. 2019. Thoughts on the strategy of tree clonal breeding. Journal of Beijing Forestry University, 41(7): 1-9. [in Chinese] 李想, 董利虎, 李凤日. 2018. 基于联立方程组的人工樟子松枝下高模型构建. 北京林业大学学报, 40(6): 9-18. Li X, Dong L H, Li F R. 2018. Based on simultaneous equations, the model of the lower branch height of Pinus sylvestris var. Mongolica was established. Journal of Beijing Forestry University, 40(6): 9-18. [in Chinese] 廖国莉, 段劼, 贾忠奎, 等. 2020. 辽东地区不同林龄长白落叶松人工林生态系统碳储量分配特征. 东北林业大学学报, 48(11): 8-13, 22. Liao G L, Duan J, Jia Z K, et al. 2020. Carbon stock distribution characteristics of Larix olgensis plantation ecosystem in eastern Liaoning. Journal of Northeast Forestry University, 48(11): 8-13, 22. [in Chinese] 林玮, 唐昌亮, 白青松, 等. 2020. 华南主要造林树种碳汇能力评价体系构建及优良碳汇树种筛选. 西南林业大学学报(自然科学), 40(1): 28-37. Lin W, Tang C L, Bai Q S, et al. 2020. Construction of carbon sequestration capacity evaluation system of main afforestation tree species in south china and selection of excellent carbon sequestration tree species. Journal of Southwest Forestry University (Natural Science), 40(1): 28-37. [in Chinese] 楼君, 金国庆, 丰忠平, 等. 2014. 柏木无性系扦插育苗技术的研究. 浙江林业科技, 34(4): 34-40. Lou J, Jin G Q, Feng Z P, et al. 2014. Study on the cutting seedling raising technique of Cypress clones. Zhejiang Forestry Science and Technology, 34(4): 34-40. [in Chinese] 纳晓莹. 2016. 高固碳白桦优良家系选择. 哈尔滨: 东北林业大学. Na X Y. 2016. High carbon storage family selection of Betula platyphylla SUK. Harbin: Northeast Forestry University.[in Chinese] 汪金松, 张春雨, 范秀华, 等. 2011. 臭冷杉生物量分配格局及异速生长模型. 生态学报, 31(14): 3918-3927. Wang J S, Zhang C Y, Fan X H, et al. 2011. Biomass distribution pattern and allometric growth model of Abies odorifera. Journal of Ecology, 31(14): 3918-3927. [in Chinese] 杨育林, 李贤伟, 周义贵, 等. 2014. 林窗式疏伐对川中丘陵区柏木人工林生长和植物多样性的影响. 应用与环境生物学报, 20(6): 971-977. Yang Y L, Li X W, Zhou Y G, et al. 2014. Effects of thinning through gaps on growth and plant diversity of cypress plantations in hilly areas of central Sichuan. Journal of Applied and Environmental Biology, 20(6): 971-977. [in Chinese] 张悦, 谢龙飞, 董利虎. 2022. 长白落叶松含碳率分析及含碳量异速生长模型. 应用生态学报, 33(5): 1166-1174. Zhang Y, Xie L F, Dong L H. 2022. Carbon content analysis and carbon content allometric growth model of Larix olgensis. Journal of Applied Ecology, 33(5): 1166-1174. [in Chinese] 郑一, 张振, 金国庆, 等. 2020. 低肥力土壤施用氮磷钾肥影响柏木家系根系发育和养分吸收对钙肥的响应. 植物营养与肥料学报, 26(8): 1501-1512. Zheng Y, Zhang Z, Jin G Q. 2020. Effects of nitrogen, phosphorus and potassium fertilizer application on root development and nutrient absorption of Cypress families in low fertility soil in response to calcium fertilizer. Journal of Plant Nutrition and Fertilizer, 26(8): 1501-1512. [in Chinese] Baltunis B S, Huber D A, White T L, et al. 2007. Genetic gain from selection for rooting ability and early growth in vegetatively propagated clones of loblolly pine. Tree Genetics & Genomes, 3(3): 227–238. Dong L H, Zhang L J, Li F R. 2015. Allometry and partitioning of individual tree biomass and carbon of Abies nephrolepis Maxim in northeast China. Scandinavian Journal of Forest Research, 31(4): 399-411. Dutc I, Mather R, Blujdea V N B, et al. 2018. Site-effects on biomass allometric models for early growth plantations of Norway spruce (Picea abies (L. ) Karst. ). Biomass and Bioenergy, 116: 8-17. Elias M, Potvin C. 2003. Assessing inter- and intra-specific variation in trunk carbon concentration for 32 neotropical tree species. Canadian Journal of Forest Research, 33(6): 1039-1045. Feldpausch T R, Lloyd J, Lewis S L, et al. 2012. Tree height integrated into pantropical forest biomass estimates. Biogeosciences, 9(8): 3381-3403. Lin K M, Liu M K, Jiang M H. 2017. Improved allometric equations for estimating biomass of the three Castanopsis carlesii H. forest types in subtropical China. New Forests, 48(1): 115-135. Meshram S G, Alvandi E, Meshram C, et al. 2020. Application of SAW and TOPSIS in prioritizing watersheds. Water Resources Management, 34(2): 715–732. Moussa M, Mahamane L. 2018. Allometric models for estimating aboveground biomass and carbon in Faidherbia albida and Prosopis africana under agroforestry parklands in drylands of Niger. Journal of Forest Research, 29(6): 1703-1717. Mullin T J, Park Y S. 1994. Genetic parameters and age-age correlations in a clonally replicated test of black spruce after 10 years. Canadian Journal of Forest Research, 24(12): 2330–2341. Stovall J P, Fox T R, Seiler J R. 2013. Allometry varies among 6-year-old Pinus taeda (L. ) clones in the Virginia Piedmont. Forest Science, 59(1): 50-62. Wang X W, Weng Y H, Liu G F, et al. 2015. Variations in carbon concentration, sequestration and partitioning among Betula platyphylla provenances. Forest Ecology and Management, 358: 344-352. Weng Y H, Kershaw J, Tosh K, et al. 2008. Height-diameter relationships for jack pine seed lots of different genetic improvement levels. Silvae Genetica, 57(4/5): 276-282. Widagdo F R A, Xie L F, Dong L H, et al. 2020. Origin-based biomass allometric equations, biomass partitioning, and carbon concentration variations of planted and natural Larix gmelinii in northeast China. Global Ecology and Conservation, 23: e01111. Wu H X. 2019. Benefits and risks of using clones in forestry – a review. Scandinavian Journal of Forest Research, 34(5): 352-359. Wu H X, Ivković M, Gapare W J, et al. 2008. Breeding for wood quality and profit in Pinus radiata: a review of genetic parameter estimates and implications for breeding and deployment. New Zealand Journal of Forestry Science, 38(1): 56–87. Yang H B, Zhang R, Jin G Q, et al. 2016. Assessing the genetic diversity and genealogical reconstruction of cypress (Cupressus funebris Endl. ) breeding parents using SSR markers. Forests, 7(8): 160-174. Zhang Q Z, Wang C K, Wang X C, et al. 2009. Carbon concentration variability of 10 Chinese temperate tree species. Forest Ecology and Management, 258: 722-727. Zhu H Y, Weng Y H, Zhang H G, et al. 2013. Comparing fast- and slow-growing provenances of Picea koraiensis in biomass, carbon parameters and their relationships with growth. Forest Ecology and Management, 307: 178–185.
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