ECO-PROCESS OF LEAF LITTER DECOMPOSITION IN TROPICAL RAIN FOREST IN XISHUANGBANNA, CHINA. Ⅰ. DECOMPOSITION DYNAMIC OF MIXED LEAF LITTERS

doi:10.17521/cjpe.2006.0100

Abstract

Abstract:

Background and Aims Decomposition of mixed leaf litters in Xishuangbanna tropic rain forest was studied both in the field and laboratory. Negative exponential model x_t/x₀=exp(-k_t) and binomial exponential model x_t/x₀=a×exp(-k₁t)+b×exp(-k₂t) were used to simulate the observed decomposition process with. Bio-models were introduced to analysis the contribution of biotic and abiotic factors to the decay rates of leaf litters.

Methods Coarse (with mesh size of 1 mm) and fine (with mesh size of 100 μm) litterbags were used in the field to examine the effects of different components of soil fauna on litter decomposition by restricting access by most soil macrofauna and mites, respectively, i.e. feasible for most mites to coarse mesh and nematodes to fine mesh. In the laboratory, sterilization and inoculation were adopted to investigate the effects of nematodes and microbiota on leaf litters.

Key Results The decomposition process was a course fast incipiently then slowdown with stagnation periods. The decay rate of mixed leaf litters fluctuated over the decomposing period with the magnitude of fluctuation positively related to complexity of food-web. The binomial exponential model simulated the two different courses of leaf litter decomposition whereas the negative exponential model did not simulate the initial stage well and overestimated the long-term decay process. Soil fauna accounted for 78.1% of the decay rates while abiotic factors for 14.1% and microorganisms only for 7.8%.

Conclusions This study suggests that the decomposition of leaf litters was a cascade process and binomial exponential model can describe the process better than the negative exponential model. Soil fauna played a dominating role in litter decomposition in tropic rain forest.

Key words: Xishuangbanna, Tropic rain forest, Mixed leaf litter, Decomposition, Model

ZHANG Rui-Qing, SUN Zhen-Jun, WANG Chong, GE Yuan, LI Yun-Le, QIAO Yu-Hui, PANG Jun-Zhu, ZHANG Lu-Da. ECO-PROCESS OF LEAF LITTER DECOMPOSITION IN TROPICAL RAIN FOREST IN XISHUANGBANNA, CHINA. Ⅰ. DECOMPOSITION DYNAMIC OF MIXED LEAF LITTERS[J]. Chin J Plant Ecol, 2006, 30(5): 780-790.

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URL: https://www.plant-ecology.com/EN/10.17521/cjpe.2006.0100

https://www.plant-ecology.com/EN/Y2006/V30/I5/780

Figures/Tables 11

References 36

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项目 Item	2004									2005
项目 Item	4月 Apr.	5月 May	6月 June	7月 July	8月 Aug.	9月 Sept.	10月 Oct.	11月 Nov.	12月 Dec.	1月 Jan.	2月 Feb.	3月 Mar.
气温Temperature (℃)	21.5	23.6	24.7	25.5	25.2	25.4	24.2	22.3	19.8	15.0	16.8	19.3
降雨量Precipitation(mm)	263.0	779.0	223.9	79.9	169.0	204.6	160.1	56.8	45.8	0.0	1.5	0.0

项目 Item	2004									2005
项目 Item	4月 Apr.	5月 May	6月 June	7月 July	8月 Aug.	9月 Sept.	10月 Oct.	11月 Nov.	12月 Dec.	1月 Jan.	2月 Feb.	3月 Mar.
气温Temperature (℃)	21.5	23.6	24.7	25.5	25.2	25.4	24.2	22.3	19.8	15.0	16.8	19.3
降雨量Precipitation(mm)	263.0	779.0	223.9	79.9	169.0	204.6	160.1	56.8	45.8	0.0	1.5	0.0

处理 Treatment	因子 Factor				F值 F value
处理 Treatment	a	k₁	b	k₂
C	0.886 2	0.003 52	0.108 3	0.049 8	<0.000 2
F	0.685 5	0.001 75	0.304 4	0.017 4	<0.000 1
MN	0.794 7	0.001 27	0.205 0	0.063 0	<0.000 1
M	0.737 8	0.000 28	0.261 2	0.046 9	<0.000 1

处理 Treatment	因子 Factor				F值 F value
处理 Treatment	a	k₁	b	k₂
C	0.886 2	0.003 52	0.108 3	0.049 8	<0.000 2
F	0.685 5	0.001 75	0.304 4	0.017 4	<0.000 1
MN	0.794 7	0.001 27	0.205 0	0.063 0	<0.000 1
M	0.737 8	0.000 28	0.261 2	0.046 9	<0.000 1

处理 Treatment	指数模型 Model	分解速率 Mass loss rate		分解50%和95%所需要的时间 Time for 50% and 95% decomposition
处理 Treatment	指数模型 Model	d^-1	a^-1	a (t_0.5)	a (t_0.95)
C	1	0.003 96	1.45	0.48	2.08
	2	0.003 52	1.28	0.52	2.26
F	1	0.003 15	1.15	0.60	2.61
	2	0.001 75	0.64	0.96	4.15
M	1	0.002 33	0.85	0.81	3.53
	2	0.000 28	0.10	6.11	26.5
MN	1	0.002 79	1.02	0.68	2.95
	2	0.001 27	0.46	1.39	6.04