Cell characteristics of Larix principis-rupprechtii on the edge of different stand types

doi:10.13287/j.1001-9332.202205.010

Abstract

Abstract: To analyze the effects of forest edge on radial growth and cell characteristics in different stand types of Larix principis-rupprechtii, we investigated the differences on radial growth, cell size and numbers between edge trees and inner trees of L. principis-rupprechtii in pure L. principis-rupprechtii forests and mixed forests of L. principis-rupprechtii and Betula platyphylla in Saihanba mechanical forest farm, China. The results showed that radial growth of the edge trees was significantly faster than that of the inner trees in pure forests, with the total ring width, earlywood width and latewood width of edge trees being 48.9%, 58.9% and 29.6% higher than those of inner trees, respectively. However, there was no difference in radial growth between edge trees and inner trees in mixed forest. The total number of earlywood cells, the number of large cells and small cells in earlywood of edge trees were increased by 63.3%, 55.6% and 70.0%, while the total number of latewood cells, the number of large cells and small cells in latewood of edge trees were increased by 35.4%, 37.5% and 28.5% compared with those of inner trees. There was no significant difference in the cell sizes between edge trees and inner trees. The cell numbers of earlywood and latewood of edge trees were not significantly different from those of inner trees in mixed forest, but the cell size in the earlywood of edge trees was 50.0% larger than those of inner trees in mixed forest. The sizes of the largest cells, the smallest cells, the large cells and the small cells in the earlywood of edge trees were increased by 28.6%, 33.3%, 16.6% and 25.0% compared with those of inner trees, respectively. The fast growth of edge trees and slow growth of inner trees in the pure forests could be effectively alleviated by cultivating mixed forests.

Key words: Larix pricipis-rupprechtii, forest edge, tree cell, pure forest, mixed forest

WANG Chun-kai, HUANG Xuan-rui, LI Xue, Jiang-yu, WANG Xiao-xue, ZHANG Xian-liang. Cell characteristics of Larix principis-rupprechtii on the edge of different stand types[J]. Chinese Journal of Applied Ecology, 2022, 33(5): 1191-1198.

References

[1] Brokaw NVL. Gap-phase regeneration in a tropical forest. Ecology, 1985, 66: 682-687
[2] 王政权, 吴巩胜, 王军邦. 利用竞争指数评价水曲柳落叶松种内种间空间竞争关系. 应用生态学报, 2000, 11(5): 641-645
[3] 国庆喜, 杨光. 红松天然种群邻体影响半径. 应用生态学报, 2006, 17(12): 2302-2306
[4] 丁宝永, 陈祥伟, 陈大我, 等. 森林边缘效应理论及其效应的初步研究. 东北林业大学学报, 1990, 18(增刊3): 13-26
[5] Swartz A, Roon D, Reiter M, et al. Stream temperature responses to experimental riparian canopy gaps along forested headwaters in western Oregon. Forest Ecology and Management, 2020, 474: 118354
[6] 吴甘霖, 羊礼敏, 段仁燕, 等. 大别山五针松林林窗、林缘和林下的微气候特征. 生物学杂志, 2017, 34(4): 64-66
[7] 杜有新, 刘伟, 王军峰, 等. 采伐林窗对白云山3种人工林林下植物多样性的早期影响. 应用生态学报, 2018, 29(7): 2121-2128
[8] Mullally HL, Buckley DS, Fordyce JA, et al. Bee communities across gap, edge, and closed-canopy micro-sites in forest stands with group selection openings. Forest Science, 2019, 65: 751-757
[9] Yang Y, Geng Y, Zhou H, et al. Effects of gaps in the forest canopy on soil microbial communities and enzyme activity in a Chinese pine forest. Pedobiologia, 2017, 61: 51-60
[10] 王壮, 杨万勤, 吴福忠, 等. 高山森林林窗对苔藓及土壤微量元素含量的影响. 生态学报, 2018, 38(6): 2111-2118
[11] Kapos V, Ganade G, Matsui E, et al. δ¹³C as an indicator of edge effects in tropical rainforest reserves. Journal of Ecology, 1993, 81: 425-432
[12] Herbst M, Roberts JM, Rosier PTW, et al. Edge effects and forest water use: A field study in a mixed deciduous woodland. Forest Ecology and Management, 2007, 250: 176-186
[13] 鲜骏仁, 胡庭兴, 王开运, 等. 川西亚高山针叶林林窗边界木特征的研究. 林业科学研究, 2004, 17(5): 636-640
[14] Abreu IN, Johansson AI, Sokołowska K, et al. A metabolite roadmap of the wood-forming tissue in Populus tremula. New Phytologist, 2020, 228: 1559-1572
[15] 季倩雯, 郑成洋, 张磊, 等. 河北塞罕坝樟子松径向生长动态变化及其与气象因子的关系. 植物生态学报, 2020, 44(3): 257-265
[16] 刘春延, 谷建才, 李吉跃, 等. 塞罕坝华北落叶松生长与气候因子的相关分析. 北京林业大学学报, 2009, 31(4): 102-105
[17] 王玲玲, 勾晓华, 夏敬清, 等. 树木形成层活动及其影响因素研究进展. 应用生态学报, 2021, 32(10): 3761-3770
[18] Rossi S, Girard MJ, Morin H. Lengthening of the duration of xylogenesis engenders disproportionate increases in xylem production. Global Change Biology, 2014, 20: 2261-2271
[19] Jyske T, Mäkinen H, Kalliokoski T, et al. Intra-annual tracheid production of Norway spruce and Scots pine across a latitudinal gradient in Finland. Agricultural and Forest Meteorology, 2014, 194: 241-254
[20] Zhang Y, Jiang Y, Wen Y, et al. Comparing primary and secondary growth of co-occurring deciduous and evergreen conifers in an alpine habitat. Forests, 2019, 10: 574
[21] 聂绍荃, 杨国亭, 张志强, 等. 边缘效应理论在次生林改造中的应用. 东北林业大学学报, 1990, 18(增刊3): 1-6
[22] Zhang XL, Li X, Manzanedo RD, et al. High risk of growth cessation of planted larch under extreme drought. Environmental Research Letters, 2021, 16: 014040
[23] 张树梓, 李梅, 张树彬, 等. 塞罕坝华北落叶松人工林天然更新影响因子. 生态学报, 2015, 35(16): 5403-5411
[24] 董雪婷, 张静, 张志东, 等. 树种相互作用、林分密度和树木大小对华北落叶松生产力的影响. 应用生态学报, 2021, 32(8): 2722-2728
[25] Zhang J, Huang S, He F. Half-century evidence from western Canada shows forest dynamics are primarily dri-ven by competition followed by climate. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112: 4009-4014
[26] Liu S, Li X, Rossi S, et al. Differences in xylogenesis between dominant and suppressed trees. American Journal of Botany, 2018, 105: 950-956
[27] Mäkinen H, Jyske T, Nöjd P. Dynamics of diameter and height increment of Norway spruce and Scots pine in southern Finland. Annals of Forest Science, 2018, 75: 1-11
[28] Antonova GF, Stasova VV. Effects of environmental factors on wood formation in Scots pine stems. Trees, 1993, 7: 214-219