东北大兴安岭演替初期泰加林灌草层典型植物开花物候与生长对模拟暖干化气候的响应

doi:10.17521/cjpe.2018.0042

摘要/Abstract

摘要：

为了揭示暖干化气候变化趋势对演替初期泰加林灌草层植物开花物候和生长的影响, 以东北大兴安岭演替初期泰加林灌草层(高度<50 cm)植物为研究对象, 根据植物生活史, 选择典型的早花植物圆锥薹草(Carex diandra)和水葡萄茶藨子(Ribes procumbens), 中花植物杜香(Ledum palustre)及晚花植物齿叶风毛菊(Saussurea neoserrata), 监测模拟增温和排水处理2年后其完整的开花物候及生长状况, 以期为认识气候变化下泰加林火后植被恢复演替提供依据。结果显示: 1)模拟增温和排水处理后, 早花植物开花温度限制的提早解除使其花期提前, 而水分限制使得晚花植物花期呈延后趋势, 这可能为中花植物提供更大的生态位空隙, 使其开花数量趋向于增加, 花期提前且呈延长趋势; 2)模拟增温和排水处理后, 圆锥薹草、杜香和齿叶风毛菊的盖度和频度均呈增加的趋势, 以杜香最显著, 而水葡萄茶藨子的盖度和频度均下降; 3)模拟增温与排水处理对植物开花物候的影响无显著交互作用, 但土壤水分降低影响部分植物生长对增温的响应。研究结果表明, 植物开花物候对暖干化气候的响应表现出明显的种间差异, 因植物开花功能群而异。早、中花植物花期趋于提前, 晚花期植物花期趋于延后, 一方面可能导致群落生态位变化, 对种间竞争产生潜在影响, 引发群落组成和结构改变; 另一方面可能成为群落调节其整体物候, 以适应气候变化的重要途径。

关键词: 繁殖物候, 恢复更新, 模拟增温, 土壤水分降低, 火烧迹地

Abstract:

Aims We studied flowering phenology and growth of four typical shrub grass plants (Carex diandra, Ribes procumbens, Ledum palustre, Saussurea neoserrata) with different life histories in the Da Hinggan Ling of northeast China to explore changes of flowering phenology and growth of early succession Taiga forests and to learn about the post-fire succession of the Taiga forests in warmer and drier climate.

Methods Open-top chambers (OTCs) and artificial drainage ditches were used to simulate the warmer and drier climate in the field. After two years of experimental warming and drainage, we recorded the flowering phenology and growth indices of four typical shrub grass plants. Flowering phenology included the first flowering date, peak flowering date, last flowering date, flowering duration and maximum flowering number. The growth indices of plants included height, coverage, frequency and above-ground biomass.

Important findings Our results revealed that: 1) Under experimental warming and drainage treatment, the first flowering dates for Carex diandra and Ribes procumbens were advanced due to early elimination of the temperature limit, which for Saussurea neoserrata were delayed by the water stress. Moreover, the Ledum palustre had longer flowering duration and more followers under the experimental warming and drainage because of the adverse shift in flowering phenology of the earlier flowering plant and the later flowering plant. 2) The Carex diandra, Saussurea neoserrata and Ledum palustre had higher coverage and frequency under experimental warming and drainage, especially in Ledum palustre, while the coverage and frequency of Ribes procumbens were declined. 3) There was no significant interaction effect between the warming and drainage on plant flowering phenology, but the responses of plant growth characteristics to warming were affected by drainage. These results indicated that species respond differently to warmer and drier climate due to different flower functional groups they belong to. The first flowering date of the early flowering plants had been progressed, and that of the late flowering plants was delayed. On the one hand, these changes can change niches in the community and interspecific competition and further alter the composition and structure of the community. On the other hand, these changes could be a way for the community to regulate community phenology to adapt climate change.

Key words: reproductive phenology, restoration, simulated warming, soil moisture decreasing, fire scar

宋小艳, 王根绪, 冉飞, 杨燕, 张莉, 肖瑶. 东北大兴安岭演替初期泰加林灌草层典型植物开花物候与生长对模拟暖干化气候的响应. 植物生态学报, 2018, 42(5): 539-549. DOI: 10.17521/cjpe.2018.0042

SONG Xiao-Yan, WANG Gen-Xu, RAN Fei, YANG Yan, ZHANG Li, XIAO Yao. Flowering phenology and growth of typical shrub grass plants in response to simulated warmer and drier climate in early succession Taiga forests in the Da Hinggan Ling of northeast China. Chinese Journal of Plant Ecology, 2018, 42(5): 539-549. DOI: 10.17521/cjpe.2018.0042

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https://www.plant-ecology.com/CN/Y2018/V42/I5/539

图/表 5

参考文献 44

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	对照 Control	增温 Warming	排水 Drainage	增温+排水 Warming + Drainage
空气温度 Air temperature (℃)	7.62	8.36	7.69	8.68
土壤温度 Soil temperature at 5 cm (℃)^{W, D}	5.37 ± 0.14	5.38 ± 0.14	5.97 ± 0.04	5.91 ± 0.13
土壤水分 Soil moisture at 0-10 cm (%)^{W, D}	45.52 ± 2.31	38.16 ± 6.82	25.36 ± 2.47	19.52 ± 1.05
最大融化深度 Maximun thaw depth (cm)^D	62.4 ± 1.2	65.1 ± 1.2	57.5 ± 1.8	55.2 ± 1.6
生长季平均水位 Mean water table (cm)	-20.0	ND	-26.3	ND

	对照 Control	增温 Warming	排水 Drainage	增温+排水 Warming + Drainage
空气温度 Air temperature (℃)	7.62	8.36	7.69	8.68
土壤温度 Soil temperature at 5 cm (℃)^{W, D}	5.37 ± 0.14	5.38 ± 0.14	5.97 ± 0.04	5.91 ± 0.13
土壤水分 Soil moisture at 0-10 cm (%)^{W, D}	45.52 ± 2.31	38.16 ± 6.82	25.36 ± 2.47	19.52 ± 1.05
最大融化深度 Maximun thaw depth (cm)^D	62.4 ± 1.2	65.1 ± 1.2	57.5 ± 1.8	55.2 ± 1.6
生长季平均水位 Mean water table (cm)	-20.0	ND	-26.3	ND

物种 Species		n	增温 Warming		排水 Drainage		增温 × 排水 Warming × Drainage
物种 Species			系数 Coefficient	显著性 Significance	系数 Coefficient	显著性 Significance	系数 Coefficient	显著性 Significance
圆锥薹草 Carex diandra	高度 Height	13	4.073	0.085	13.212	0.082	-12.960	0.007
	盖度 Coverage	13	-27.000	0.108	-11.583	0.725	0.833	0.974
	频度 Frequency	13	-14.015	0.385	-18.246	0.671	-30.882	0.268
	地上生物量 Above-ground biomass	13	-2.692	0.362	-1.731	0.774	-0.322	0.934
	开花初始期 First flowering date	7	-	-	8.000	0.210	-	-
	开花结束期 Last flowering date	7	-	-	10.250	0.009	-	-
	开花峰值期 Flowering peak date	7	-	-	11.167	0.076	-	-
	开花持续时间 Flowering duration	7	-	-	2.250	0.727	-	-
	最大开花数量 Maximum flowering number	7	-	-	-13.167	0.496	-	-
水葡萄茶藨子 Ribes procumbens	高度 Height	16	2.070	0.512	-2.947	0.550	3.880	0.352
	盖度 Coverage	16	-5.000	0.741	-17.333	0.468	34.000	0.105
	频度 Frequency	16	-5.200	0.785	-13.867	0.641	26.533	0.298
	地上生物量 Above-ground biomass	16	-6.507	0.263	-8.738	0.299	10.792	0.138
	开花初始期 First flowering date	15	1.727	0.449	1.382	0.799	-2.524	0.604
	开花结束期 Last flowering date	15	3.788	0.097	3.164	0.542	3.595	0.434
	开花峰值期 Flowering peak date	15	5.576	0.104	4.327	0.581	4.571	0.512
	开花持续时间 Flowering duration	15	2.061	0.418	1.782	0.768	6.119	0.247
	最大开花数量 Maximum flowering number	15	1.424	0.813	3.073	0.832	14.548	0.252
杜香 Ledum palustre	高度 Height	29	6.000	0.040	1.223	0.870	-10.108	0.024
	盖度 Coverage	29	19.250	0.025	-11.590	0.541	-21.502	0.089
	频度 Frequency	29	3.500	0.591	-3.088	0.832	-23.450	0.023
	地上生物量 Above-ground biomass	29	12.999	0.249	-20.981	0.579	5.287	0.824
	开花初始期 First flowering date	16	4.088	0.177	3.514	0.642	6.933	0.241
	开花结束期 Last flowering date	16	-1.546	0.642	-0.139	0.987	-0.039	0.996
	开花峰值期 Flowering peak date	16	6.097	0.043	3.042	0.671	-3.051	0.457
	开花持续时间 Flowering duration	16	-5.634	0.243	-3.653	0.763	-7.315	0.470
	最大开花数量 Maximum flowering number	16	0.838	0.982	-24.736	0.796	-52.318	0.493
齿叶风毛菊 Saussurea neoserrata	高度 Height	11	-9.412	0.614	-12.858	0.759	5.733	0.828
	盖度 Coverage	11	-1.914	0.671	-1.052	0.918	-1.315	0.837
	频度 Frequency	11	4.000	0.757	4.667	0.866	-18.667	0.336
	地上生物量 Above-ground biomass	11	-3.670	0.186	-3.098	0.438	3.361	0.326
	开花初始期 First flowering date	8	3.464	0.623	-17.036	0.289	-15.500	0.311
	开花结束期 Last flowering date	8	3.143	0.447	-9.857	0.287	-1.000	0.916
	开花峰值期 Flowering peak date	8	3.714	0.448	-12.284	0.265	-12.201	0.235
	开花持续时间 Flowering duration	8	-0.321	0.943	7.179	0.477	14.500	0.105
	最大开花数量 Maximum flowering number	8	-3.929	0.344	-2.929	0.734	3.000	0.746

物种 Species		n	增温 Warming		排水 Drainage		增温 × 排水 Warming × Drainage
物种 Species			系数 Coefficient	显著性 Significance	系数 Coefficient	显著性 Significance	系数 Coefficient	显著性 Significance
圆锥薹草 Carex diandra	高度 Height	13	4.073	0.085	13.212	0.082	-12.960	0.007
	盖度 Coverage	13	-27.000	0.108	-11.583	0.725	0.833	0.974
	频度 Frequency	13	-14.015	0.385	-18.246	0.671	-30.882	0.268
	地上生物量 Above-ground biomass	13	-2.692	0.362	-1.731	0.774	-0.322	0.934
	开花初始期 First flowering date	7	-	-	8.000	0.210	-	-
	开花结束期 Last flowering date	7	-	-	10.250	0.009	-	-
	开花峰值期 Flowering peak date	7	-	-	11.167	0.076	-	-
	开花持续时间 Flowering duration	7	-	-	2.250	0.727	-	-
	最大开花数量 Maximum flowering number	7	-	-	-13.167	0.496	-	-
水葡萄茶藨子 Ribes procumbens	高度 Height	16	2.070	0.512	-2.947	0.550	3.880	0.352
	盖度 Coverage	16	-5.000	0.741	-17.333	0.468	34.000	0.105
	频度 Frequency	16	-5.200	0.785	-13.867	0.641	26.533	0.298
	地上生物量 Above-ground biomass	16	-6.507	0.263	-8.738	0.299	10.792	0.138
	开花初始期 First flowering date	15	1.727	0.449	1.382	0.799	-2.524	0.604
	开花结束期 Last flowering date	15	3.788	0.097	3.164	0.542	3.595	0.434
	开花峰值期 Flowering peak date	15	5.576	0.104	4.327	0.581	4.571	0.512
	开花持续时间 Flowering duration	15	2.061	0.418	1.782	0.768	6.119	0.247
	最大开花数量 Maximum flowering number	15	1.424	0.813	3.073	0.832	14.548	0.252
杜香 Ledum palustre	高度 Height	29	6.000	0.040	1.223	0.870	-10.108	0.024
	盖度 Coverage	29	19.250	0.025	-11.590	0.541	-21.502	0.089
	频度 Frequency	29	3.500	0.591	-3.088	0.832	-23.450	0.023
	地上生物量 Above-ground biomass	29	12.999	0.249	-20.981	0.579	5.287	0.824
	开花初始期 First flowering date	16	4.088	0.177	3.514	0.642	6.933	0.241
	开花结束期 Last flowering date	16	-1.546	0.642	-0.139	0.987	-0.039	0.996
	开花峰值期 Flowering peak date	16	6.097	0.043	3.042	0.671	-3.051	0.457
	开花持续时间 Flowering duration	16	-5.634	0.243	-3.653	0.763	-7.315	0.470
	最大开花数量 Maximum flowering number	16	0.838	0.982	-24.736	0.796	-52.318	0.493
齿叶风毛菊 Saussurea neoserrata	高度 Height	11	-9.412	0.614	-12.858	0.759	5.733	0.828
	盖度 Coverage	11	-1.914	0.671	-1.052	0.918	-1.315	0.837
	频度 Frequency	11	4.000	0.757	4.667	0.866	-18.667	0.336
	地上生物量 Above-ground biomass	11	-3.670	0.186	-3.098	0.438	3.361	0.326
	开花初始期 First flowering date	8	3.464	0.623	-17.036	0.289	-15.500	0.311
	开花结束期 Last flowering date	8	3.143	0.447	-9.857	0.287	-1.000	0.916
	开花峰值期 Flowering peak date	8	3.714	0.448	-12.284	0.265	-12.201	0.235
	开花持续时间 Flowering duration	8	-0.321	0.943	7.179	0.477	14.500	0.105
	最大开花数量 Maximum flowering number	8	-3.929	0.344	-2.929	0.734	3.000	0.746