基于刈割与除草剂结合措施的互花米草除控效果研究

doi:10.3969/j.issn.1000-5641.2025.06.013

摘要/Abstract

摘要：

为探究治理入侵植物互花米草(Spartina alterniflora)的有效措施, 通过野外实验, 将4种不同处理措施 (直接施用盖草能、草甘膦与扬花期刈割后施用盖草能、草甘膦) 对互花米草的治理效果进行对比, 探究刈割与低用量除草剂结合治理互花米草的有效性, 并研究了刈割与除草剂结合对土壤微生物多样性的影响. 实验结果显示: ① 扬花期刈割后施用盖草能处理可以有效除控互花米草, 150 mg/m²的盖草能在生长季末能够达到98.93%的除控效果, 用量为300 mg/m²和600 mg/m²时, 可使样方内的互花米草植株完全死亡; 不同用量浓度的盖草能处理在抑制次年萌发方面同样效果显著, 抑制率分别达到了93.49%、92.68%和96.48%; ② 在扬花期对互花米草进行刈割处理, 能够显著降低其再生植株的有性繁殖能力; ③ 刈割与除草剂结合使用的处理方式虽然降低了土壤真菌中子囊菌门的相对丰度, 但对土壤细菌和真菌的多样性并未产生显著影响. 研究表明: 刈割后施用150 mg/m²的盖草能即可有效除控互花米草, 并显著抑制其次年萌发, 同时该处理方式对土壤微生物多样性无显著不良影响.

关键词: 互花米草, 刈割, 除草剂, 综合法

Abstract:

Spartina alterniflora is a globally invasive plant that has caused significant damage to coastal ecosystems, including biodiversity loss, decline of native vegetation, alteration of benthic communities, and degradation of bird habitats. Effective control of S. alterniflora is therefore critical for coastal ecological conservation. Current control methods—physical, chemical, biological, and integrated—have limitations: physical removal alone is often inefficient, and chemical control poses risks of ecological pollution. This study evaluates an integrated approach combining mechanical cutting with low-dose herbicide application to improve control efficacy and assesses its impact on soil microbial diversity. In August 2022, two sites with uniformly growing S. alterniflora were selected, each divided into 21 quadrats of 1 m × 1 m. One site was mowed at the end of August, while the other remained uncut. In September, three concentrations of Haloxyfop-P-methyl (HP) and Glyphosate (GP) were applied. Plant responses were monitored during the flowering stage (September), seed-setting stage (October), the end of the growing season (December), and the following April. Four treatments were compared: HP alone, GP alone, cutting followed by HP, and cutting followed by GP. Soil samples were collected from herbicide-treated and control quadrats for physicochemical analysis. High-throughput sequencing was used to characterize bacterial and fungal community structure and diversity. Data were analyzed using one-way ANOVA with LSD post-hoc tests following validation of homogeneity of variances (Levene’s test). Results showed that: (1) Cutting followed by HP application during the flowering stage effectively controlled S. alterniflora, with a dose of 150 mg/m² achieving 98.93% control efficiency by the end of the growing season, while doses of 300 mg/m² and 600 mg/m² achieved complete plant mortality; all doses significantly inhibited regrowth the following year, with suppression rates of 93.49%, 92.68%, and 96.48%, respectively. (2) Cutting during flowering significantly reduced the sexual reproduction capacity of regenerated plants. (3) Although the combined treatment reduced the relative abundance of Ascomycota in soil fungi, it did not significantly affect overall bacterial or fungal diversity. The combined treatment of cutting followed by Haloxyfop-P-methyl application at 150 mg/m² effectively controls S. alterniflora and strongly suppresses its regrowth without causing significant adverse effects on soil microbial diversity, supporting the development of efficient and environmentally sustainable management strategies for this invasive species.

Key words: Spartina alterniflora, cutting, herbicides, integrated management

中图分类号:

Q148

刘宗悦, 池云怡, 王强. 基于刈割与除草剂结合措施的互花米草除控效果研究[J]. 华东师范大学学报（自然科学版）, 2025, 2025(6): 116-127.

Zongyue LIU, Yunyi CHI, Qiang WANG. A study on the control effectiveness of Spartina alterniflora based on combined cutting and herbicide application measures[J]. J* E* C* N* U* N* S*, 2025, 2025(6): 116-127.

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试剂	有效成分占比/%	C1/(mg/m²)	C2/(mg/m²)	C3/(mg/m²)	生产厂家
HP	10.8	150	300	600	科迪华
GP	30.0	300	600	1200	中保科技

组别	土壤含水率/%	土壤电导率/(mS/m)	pH值	土壤有机质含量/(g/kg)
CK	37.27 ± 2.24^d	22.33 ± 0.58^b	8.38 ± 0.06^a	17.82 ± 1.14^ac
HP-C1	42.80^b	47.00^a	8.42 ± 0.13^a	16.19 ± 1.90^a
HP-C2	43.50^a	47.00^a	8.27 ± 0.12^a	17.02 ± 2.11^a
HP-C3	41.20^c	41.00^a	8.42 ± 0.06^a	12.07 ± 1.24^a
GP-C1	41.90^c	28.00^a	8.27 ± 0.05^a	14.74 ± 2.95^a
GP-C2	43.60^c	31.00^a	8.38 ± 0.04^a	14.55 ± 3.18^a
GP-C3	42.70^c	37.00^a	8.32 ± 0.07^a	15.04 ± 1.54^a

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