玉米田养鹅措施对杂草群落生态特征的影响

doi:10.3724/SP.J.1003.2014.14002

摘要/Abstract

摘要：

探索如何在利用和控制农田杂草的同时又能维持较高的杂草群落多样性的生产方式, 是当前农业发展的重要方向。作者以“农牧一体化”生产方式下的“玉米(Zea mays)田养鹅”处理和常规玉米种植处理为研究对象, 探讨了玉米田养鹅处理放牧前后及同期常规玉米种植处理下杂草生态位、功能群结构和杂草群落生物多样性的变化。结果表明: (1)在玉米田养鹅模式下, 黑麦草(Lolium multiflorum)、紫花苜蓿(Medicago sativa)和灰绿藜(Chenopodium glaucum)在放牧前的生态位宽度较大, 但放牧后黑麦草、紫花苜蓿的生态位宽度减小, 而灰绿藜、尼泊尔蓼(Polygonum nepalense)、西南草莓(Fragaria moupinensis)和老鹳草(Geranium sibiricum)等物种的生态位宽度则有不同程度的增大, 放牧后群落内新增加了7种杂草; 对照中, 前期丝叶球柱草(Bulbostylis densa)的生态位宽度最大, 而后期鼠麹草(Gnaphalium affine)的生态位宽度变为最大, 新增2种杂草。(2)放牧前玉米田养鹅处理下的黑麦草和紫花苜蓿的重叠度最大, 而放牧后黑麦草和西南草莓的重叠度变为最大; 在常规玉米种植模式下, 前期丝叶球柱草和马唐(Digitaria sanguinalis)的重叠度最高, 而后期丝叶球柱草和鼠麹草的重叠度最高。(3)两种模式下放牧前后均是一年生双子叶(DA)杂草功能群占据最大优势, 但玉米田养鹅处理模式下放牧后多年生功能类群所占的比例较放牧前增加, 且分配更均匀。(4)放牧前, 玉米田养鹅处理的Shannon-Wiener多样性指数、Margalef物种丰富度指数和Simpson多样性指数均高于对照, 其中Shannon-Wiener多样性指数和Margalef物种丰富度指数差异显著(P<0.05, n=3), 而Pielou均匀度指数低于对照, 但差异并不显著(P>0.05, n=3); 放牧后玉米田养鹅处理的Shannon-Wiener多样性指数和Margalef物种丰富度指数仍显著高于对照(P<0.05, n=3), 而Pielou均匀度指数和Simpson多样性指数则分别显著低于对照 (P<0.05, n=3)。放牧前后, 玉米田养鹅处理杂草群落的地上总生物量均高于对照, 但差异不显著(P>0.05, n=3)。(5)玉米田养鹅处理的玉米产量与对照相比减产4.0%, 但并未达到显著差异(P>0.05, n=12)。总的来看, 玉米田养鹅生产方式维持了较高的农田生态系统生物多样性, 虽然造成了一定的减产, 但可通过鹅的产出获得更高的经济效益。

关键词: 杂草, 农牧一体化, 生态位, 功能群, 生物多样性, 产量

Abstract

Weeds have a direct impact on crop quality and yield in agricultural systems. In order to explore a production mode which can control and utilize weeds while maintaining a high weed diversity and a high crop yield, we experimentally compared weeds by raising geese in corn fields (hereinafter referred to as RGICF) and conventionally planting corn fields (CK) in 2013. Weed niche breadth, the structure of community and functional groups and diversity were compared between the periods of BG (before the RGICF treatment was grazed by geese) and AG (after the RGICF treatment was grazed by geese) to observe changes. RGICF is a compound production pattern based on the principle of “Agro-pastoral Integration”, a concept proposed in 2011, that uses resources like weeds and the bottom leaves of crops in a tillage system to raise poultry. However, questions remain about the system including its effects on biodiversity, weed community structure, and total biomass. Results indicated that Lolium multiflorum, Medicago sativa, and Chenopodium glaucum had the highest niche breadth during BG in RGICF, and the niche breadths of C. glaucum, Polygonum nepalense, Fragaria moupinensis and Geranium pratense increased to different extents while those of L. multiforum and M. sativa decreased during AG. Additionally, seven weed species were found only during AG. In the CK treatment, Bulbostylis densa had the highest niche breadth during BG, while Gnaphalium affine had the highest during AG. Here, two new weed species were found only during AG. The niche overlap of L. perenne and M. sativa was the highest during BG, and L. perenne overlapped most with F. moupinensis during AG. While in CK, the niche overlap of Bulbostylis densa and Digitaria sanguinalis was greatest during BG, and the niches of B. densa and Gnaphalium affine overlapped the most during AG. In the two treatments, the dicotyledonous annuals (DA) was the dominant functional group during both BG and AG, and the distribution proportion of perennials increased with a more balanced distribution during AG in RGICF. During BG, Shannon-Wiener diversity index and Margalef richness index were significantly higher in RGICF than in CK (P<0.05, n=3), and these measures increase during AG and remained higher in RGICF. Pielou evenness index did not differ between the treatments (P>0.05, n=3). Simpson diversity index of weeds in RGICF was higher than CK during BG but significantly lower than CK (P<0.05, n=3) during AG. The biomass of above ground weeds in RGICF was higher than that of CK (P>0.05, n=3), during both BG and AG. Compared with CK, the corn yield in RGICF was lower (P>0.05, n=3); yields decreased 4%. In summary, although the RGICF production mode reduced corn yields, the practice maintains high biodiversity in agro-ecosystems, and may compensate or even overcompensate yield loss through the production of geese.

Key words: weeds, agro-pastoral integration, niche, functional groups, biodiversity, yield

张宇阳, 沙志鹏, 关法春, 王军峰 (2014) 玉米田养鹅措施对杂草群落生态特征的影响. 生物多样性, 22, 492-501. DOI: 10.3724/SP.J.1003.2014.14002.

Yuyang Zhang, Zhipeng Sha, Fachun Guan, Junfeng Wang (2014) Effect of raising geese in cornfield on ecological characteristics of weed community. Biodiversity Science, 22, 492-501. DOI: 10.3724/SP.J.1003.2014.14002.

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链接本文: https://www.biodiversity-science.net/CN/10.3724/SP.J.1003.2014.14002

https://www.biodiversity-science.net/CN/Y2014/V22/I4/492

图/表 8

参考文献 30

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种号 No.	种名 Species	放牧前 Before grazing		放牧后 After grazing
种号 No.	种名 Species	玉米田养鹅种植模式RGICF	常规种植模式 CK	玉米田养鹅种植模式RGICF	常规种植模式 CK
1	黑麦草 Lolium multiflorum	0.998	-	0.988	-
2	紫花苜蓿 Medicago sativa	0.993	-	0.961	-
3	灰绿藜 Chenopodium glaucum	0.920	-	0.925	0.500
4	牛膝菊 Galinsoga parviflora	0.814	0.460	0.859	-
5	鼠麹草 Gnaphalium affine	0.850	0.828	0.898	0.955
6	丝叶球柱草 Bulbostylis densa	0.764	0.977	0.895	0.900
7	尼泊尔蓼 Polygonum nepalense	0.888	0.500	0.929	0.700
8	早熟禾 Poa annua	0.306	-	-	-
9	平车前 Plantago depressa	0.290	-	0.631	-
10	马唐 Digitaria sanguinalis	0.886	0.797	0.813	0.795
11	毛蕊花 Verbascum thapsus	-	-	0.793	-
12	倒提壶 Cynoglossum amabile	0.712	-	0.579	-
13	加拿大白酒草 Conyza Canadensis	-	0.543	0.869	0.702
14	大籽蒿 Artemisia sieversiana	0.846	0.000	0.849	0.901
15	川滇香薷 Elsholtzia souliei	0.802	-	0.813	-
16	藏蓟 Cirsium lanatum	0.650	-	0.306	-
17	白草 Pennisetum flaccidum	0.609	-	0.728	-
18	尼泊尔酸模 Rumex nepalensis	0.290	-	0.830	-
19	西南草莓 Fragaria moupinensis	-	-	0.949	-
20	萨嘎苔草 Carex sagaensis	-	-	0.710	-
21	播娘蒿 Descurainia sophia	-	-	0.473	-
22	蕨 Pteridium aquilinum	-	-	0.000	-
23	节节草 Hippochaete ramosissimum	0.000	-	0.362	0.529
24	老鹳草 Geranium sibiricum	-	-	0.937	-

种号 No.	种名 Species	放牧前 Before grazing		放牧后 After grazing
种号 No.	种名 Species	玉米田养鹅种植模式RGICF	常规种植模式 CK	玉米田养鹅种植模式RGICF	常规种植模式 CK
1	黑麦草 Lolium multiflorum	0.998	-	0.988	-
2	紫花苜蓿 Medicago sativa	0.993	-	0.961	-
3	灰绿藜 Chenopodium glaucum	0.920	-	0.925	0.500
4	牛膝菊 Galinsoga parviflora	0.814	0.460	0.859	-
5	鼠麹草 Gnaphalium affine	0.850	0.828	0.898	0.955
6	丝叶球柱草 Bulbostylis densa	0.764	0.977	0.895	0.900
7	尼泊尔蓼 Polygonum nepalense	0.888	0.500	0.929	0.700
8	早熟禾 Poa annua	0.306	-	-	-
9	平车前 Plantago depressa	0.290	-	0.631	-
10	马唐 Digitaria sanguinalis	0.886	0.797	0.813	0.795
11	毛蕊花 Verbascum thapsus	-	-	0.793	-
12	倒提壶 Cynoglossum amabile	0.712	-	0.579	-
13	加拿大白酒草 Conyza Canadensis	-	0.543	0.869	0.702
14	大籽蒿 Artemisia sieversiana	0.846	0.000	0.849	0.901
15	川滇香薷 Elsholtzia souliei	0.802	-	0.813	-
16	藏蓟 Cirsium lanatum	0.650	-	0.306	-
17	白草 Pennisetum flaccidum	0.609	-	0.728	-
18	尼泊尔酸模 Rumex nepalensis	0.290	-	0.830	-
19	西南草莓 Fragaria moupinensis	-	-	0.949	-
20	萨嘎苔草 Carex sagaensis	-	-	0.710	-
21	播娘蒿 Descurainia sophia	-	-	0.473	-
22	蕨 Pteridium aquilinum	-	-	0.000	-
23	节节草 Hippochaete ramosissimum	0.000	-	0.362	0.529
24	老鹳草 Geranium sibiricum	-	-	0.937	-

种号 No.	1	2	3	4	5	6	7	8	9	10	12	14	15	16	17	18	23
1	1.000	0.904	0.761	0.617	0.664	0.606	0.716	0.211	0.195	0.740	0.551	0.670	0.620	0.522	0.410	0.195	0.121
2		1.000	0.748	0.555	0.725	0.605	0.697	0.196	0.220	0.689	0.524	0.645	0.702	0.506	0.459	0.220	0.098
3			1.000	0.589	0.557	0.553	0.707	0.280	0.200	0.634	0.480	0.530	0.500	0.391	0.320	0.200	0.080
4				1.000	0.391	0.448	0.607	0.269	0.231	0.535	0.638	0.625	0.292	0.265	0.278	0.231	0.308
5					1.000	0.689	0.604	0.074	0.397	0.425	0.366	0.705	0.794	0.338	0.396	0.358	0.041
6						1.000	0.380	0.216	0.549	0.546	0.510	0.686	0.727	0.418	0.483	0.490	0.000
7							1.000	0.151	0.151	0.502	0.441	0.587	0.477	0.375	0.264	0.151	0.264
8								1.000	0.333	0.257	0.294	0.129	0.175	0.511	0.162	0.600	0.000
9									1.000	0.114	0.412	0.452	0.400	0.222	0.351	0.667	0.000
10										1.000	0.548	0.525	0.561	0.543	0.371	0.114	0.114
12											1.000	0.634	0.343	0.222	0.280	0.412	0.177
14												1.000	0.584	0.319	0.415	0.452	0.161
15													1.000	0.497	0.464	0.358	0.025
16														1.000	0.556	0.222	0.000
17															1.000	0.351	0.000
18																1.000	0.000
23																	1.000

种号 No.	1	2	3	4	5	6	7	8	9	10	12	14	15	16	17	18	23
1	1.000	0.904	0.761	0.617	0.664	0.606	0.716	0.211	0.195	0.740	0.551	0.670	0.620	0.522	0.410	0.195	0.121
2		1.000	0.748	0.555	0.725	0.605	0.697	0.196	0.220	0.689	0.524	0.645	0.702	0.506	0.459	0.220	0.098
3			1.000	0.589	0.557	0.553	0.707	0.280	0.200	0.634	0.480	0.530	0.500	0.391	0.320	0.200	0.080
4				1.000	0.391	0.448	0.607	0.269	0.231	0.535	0.638	0.625	0.292	0.265	0.278	0.231	0.308
5					1.000	0.689	0.604	0.074	0.397	0.425	0.366	0.705	0.794	0.338	0.396	0.358	0.041
6						1.000	0.380	0.216	0.549	0.546	0.510	0.686	0.727	0.418	0.483	0.490	0.000
7							1.000	0.151	0.151	0.502	0.441	0.587	0.477	0.375	0.264	0.151	0.264
8								1.000	0.333	0.257	0.294	0.129	0.175	0.511	0.162	0.600	0.000
9									1.000	0.114	0.412	0.452	0.400	0.222	0.351	0.667	0.000
10										1.000	0.548	0.525	0.561	0.543	0.371	0.114	0.114
12											1.000	0.634	0.343	0.222	0.280	0.412	0.177
14												1.000	0.584	0.319	0.415	0.452	0.161
15													1.000	0.497	0.464	0.358	0.025
16														1.000	0.556	0.222	0.000
17															1.000	0.351	0.000
18																1.000	0.000
23																	1.000

种号 No.	4	5	6	7	10	13
4	1.000	0.478	0.258	0.167	0.176	0.167
5		1.000	0.660	0.348	0.436	0.403
6			1.000	0.427	0.670	0.408
7				1.000	0.235	0.667
10					1.000	0.382
13						1.000