伊犁黄土含砂量对边坡生态修复植物生长的影响

doi:10.11988/ckyyb.20240174

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (5): 104-110.DOI: 10.11988/ckyyb.20240174

伊犁黄土含砂量对边坡生态修复植物生长的影响

袁胜洋¹^,²(), 杨贵侠¹^,², 李思环¹^,², 楚建勋³, 杨小玲¹^,², 马杰¹^,², 刘先峰¹^,²

¹ 西南交通大学土木工程学院,成都 610031
² 西南交通大学高速铁路线路工程教育部重点实验室, 成都 610031
³ 新疆路桥建设集团有限公司, 乌鲁木齐 830000

收稿日期:2024-02-29 修回日期:2024-05-10 出版日期:2025-05-01 发布日期:2025-05-01
作者简介:
袁胜洋(1987-),男,四川泸州人,副教授,博士,博士生导师,从事非饱和膨胀土方面的教学与研究工作。E-mail:shengyang.yuan@swjtu.edu.cn
基金资助:
新疆交通运输厅2022年度交通运输行业科技项目(2022-ZD-018); 新疆交通规划勘察设计研究院有限公司科研基金项目(KY2022042501); 国家自然科学基金项目(52078432); 国家自然科学基金青年科学基金项目(52008355)

Influence of Sand Content in Yili Loess on the Growth of Ecological Restoration Plants

YUAN Sheng-yang¹^,²(), YANG Gui-xia¹^,², LI Si-huan¹^,², CHU Jian-xun³, YANG Xiao-ling¹^,², MA Jie¹^,², LIU Xian-feng¹^,²

¹ School of Civil Engineering, Southwest Jiaotong University, Chengdu 610031, China
² Key Laboratory of Ministry of Education on High Speed Railway Line Engineering, Southwest Jiaotong University, Chengdu 610031, China
³ Xinjiang Road and Bridge Construction Co., Ltd.,Urumqi 830000, China

Received:2024-02-29 Revised:2024-05-10 Published:2025-05-01 Online:2025-05-01

摘要/Abstract

摘要： 为探究不同含砂量对边坡生态修复植物生长的影响,基于层次分析法筛选植物,针对伊犁黄土开展加砂种植试验,结合植物覆盖度、土壤累计蒸发量、最大裂缝率的变化规律展开研究。结果表明:加砂能缩短发芽时间、提高发芽率。生长初期水分足时,发芽率、覆盖度等与含砂量正相关,干旱时覆盖度随含砂量增大而减小。土壤水分累计蒸发量与含砂量正相关,且受温度影响明显,温度升高,不同含砂量试样的累计蒸发量差距增大,温度降低,差距增量减小。以40%含砂量为界,<40%时,含砂量与最大裂缝率正相关,最大覆盖度随最大裂缝率增大而增大;>40%时,二者负相关,最大覆盖度随最大裂缝率增大而减小。野外或缺养护时,20%含砂量最佳;有人为养护时,60%含砂量最佳;平地且有人为养护时,全砂最佳。研究成果可为西北交通线路边坡植物种植提供参考。

关键词: 含砂量, 伊犁黄土, 覆盖度, 累计蒸发量, 最大裂缝率

Abstract:

To investigate the effect of sand content on the growth of slope ecological restoration plants, we used the Analytic Hierarchy Process to select suitable plant species and then conducted planting experiment with sand added in Yili loess slopes. By analyzing changes in plant coverage, cumulative soil evaporation, and maximum crack rate, we found that adding sand to the planting soil can speed up plant germination and improve the soil germination rate. During early growth stage with sufficient water supply, the germination rate and plant coverage are positively correlated with sand content. Nevertheless, under drought conditions, plant coverage decreases as sand content rises. The cumulative evaporation of soil moisture is positively correlated with sand content and varies significantly with temperature fluctuations. Higher temperatures lead to larger differences in cumulative evaporation among samples with different sand contents, but these differences gradually narrow as the temperature drops. Taking 40% sand content as the threshold for optimal conditions: when sand content is below 40%, it is positively correlated with the maximum crack rate, and an increase in the maximum crack rate corresponds to an increase in the peak plant coverage of each sample. However, when sand content exceeds 40%, sand content and the maximum crack rate display a negative correlation. As maximum crack rate increases, the peak plant coverage of sample decreases. For wild or poorly maintained ecological restoration sites, an optimal sand content of 20% is recommended. For artificially maintained ecological restoration sites, a 60% sand content is optimal. In flat, human-intervened ecological restoration and maintenance sites, full sand coverage is the best choice.

Key words: sand content, Ili loess, coverage, accumulated evaporation, maximum crack rate

中图分类号:

U416.1

袁胜洋, 杨贵侠, 李思环, 楚建勋, 杨小玲, 马杰, 刘先峰. 伊犁黄土含砂量对边坡生态修复植物生长的影响[J]. raybet体育在线院报, 2025, 42(5): 104-110.

YUAN Sheng-yang, YANG Gui-xia, LI Si-huan, CHU Jian-xun, YANG Xiao-ling, MA Jie, LIU Xian-feng. Influence of Sand Content in Yili Loess on the Growth of Ecological Restoration Plants[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(5): 104-110.

图/表 9

表1 乡土护坡植物库权重排名

Table 1 Ranking list of rural slope protection plant storage

植物名	总权重	种类	植物名	总权重	种类
披碱草	0.84	禾本科	紫穗槐	0.64	豆科灌木
野牛草	0.79	禾本科	红豆草	0.63	豆科草本
高羊茅	0.74	禾本科	细茎冰草	0.63	禾本科
紫花苜蓿	0.84	豆科草本	狗牙根	0.62	禾本科
柠条	0.79	豆科灌木	野菊花	0.56	菊科
小檗	0.74	灌木	狗尾巴草	0.54	禾本科
绣线菊	0.66	菊科灌木

图1 植物生长情况灰度处理

Fig.1 Grey processing of plant growth images

图2 实际值与理论值拟合曲线

Fig.2 Fitting curve between actual and theoretical values

图3 裂缝标注前后对比

Fig.3 Images before and after cracks annotation

图4 加砂植物生长情况

Fig.4 Plant growth with sand added in the soil

图5 浇水期间和停止浇水后加砂植物覆盖度

Fig.5 Plant coverage with sand added in the soil during watering and after the watering stops

图6 加砂植物累计蒸发量

Fig.6 Accumulated evaporation of plants with sand added

图7 气温变化曲线

Fig.7 Temperature variation

图8 最大覆盖度、含砂量与最大裂缝率关系

Fig.8 Relations of maximum crack rate versus maximum plant coverage and sand content

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伊犁黄土含砂量对边坡生态修复植物生长的影响

Influence of Sand Content in Yili Loess on the Growth of Ecological Restoration Plants

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