湖北星斗山地形变化对不同生活型植物叶功能性状的影响
王进1,朱江1,*(
),艾训儒1,姚兰1,黄小1,吴漫玲1,朱强1,洪建峰2
),艾训儒1,姚兰1,黄小1,吴漫玲1,朱强1,洪建峰2
Effects of topography on leaf functional traits across plant life forms in Xingdou Mountain, Hubei, China
WANG Jin1,ZHU Jiang1,*(),AI Xun-Ru1,YAO Lan1,HUANG Xiao1,WU Man-Ling1,ZHU Qiang1,HONG Jian- Feng2
),AI Xun-Ru1,YAO Lan1,HUANG Xiao1,WU Man-Ling1,ZHU Qiang1,HONG Jian- Feng2
图4. 优势种植物叶功能性状变异(物种水平)。图中百分数据为变异系数(CV); 箱体中“█”为平均值、“—”为中位数; “○”为异常值。横坐标1-6代表物种: 1, 川陕鹅耳枥; 2, 齿缘吊钟花; 3, 翅柃; 4, 红果树; 5, 大金刚藤; 6, 中华猕猴桃。
Fig. 4. Variation in leaf functional traits across dominant species (species level). LA, leaf area; LT, leaf thickness; LDM, leaf dry mass; LDMC, leaf dry matter content; SLA, specific leaf area. The figures on top of the boxes are the coefficients of variation of each trait for a species across all sampled plots. In the box, “█” is the average, “—” is the median. “○” is the abnormal value. 1-6 represent species in the abscissa: 1, Carpinus fargesiana; 2, Enkianthus serrulatus; 3, Eurya alata; 4, Stranvaesia davidiana; 5, Dalbergia dyeriana; 6, Actinidia chinensis.
