Earthworm communities and their relation to above‐ground organic residues and water infiltration in perennial cup plant (Silphium perfoliatum) and annual silage maize (Zea mays) energy plants

IF 5 3区 农林科学 Q1 SOIL SCIENCE
Lena Wöhl, Thorsten Ruf, Christoph Emmerling, Stefan Schrader
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Abstract

Perennial energy cropping systems are hailed as a sustainable way of mitigating and potentially adapting to climate change. As a result of the absence of tillage, soils cropped with perennials like cup plant (Silphium perfoliatum) promote abundant and functionally diverse earthworm communities. Hence, ecosystem service provision because of earthworm activity and functional redundancy, for example, litter decomposition, water infiltration and nutrient turnover, is considerably enhanced in perennial cropping systems. We studied the abundance and functional role of earthworms in non‐tilled perennial systems and reduced‐tilled annual systems to assess their relationship with the respective above‐ground organic residues and their implications for the soil water dynamic. We sampled earthworms and simultaneously measured the saturated infiltration rate for two consecutive years in cup plant and maize (Zea mays) fields. Furthermore, we sampled above‐ground litter each trimester in both systems and analysed the total C and N content and CN ratios. Our field investigations revealed significantly higher earthworm abundance, species diversity and richness in cup plant systems likely because of the absence of tillage and the formation of a litter layer. High abundances of juveniles in both maize and cup plant systems pointed to harsh habitat conditions likely because of temperature variations, waterlogging and bulk density. The respective field litter was of minor importance as a food source in both systems because of poor quality, but may positively affect the soil water balance in cup plant systems. Earthworm populations in maize may have been supported by organic fertilizer while earthworm populations in cup plants may have additionally benefitted from the extensive root network and a higher on‐site plant diversity. Reduced tillage regimes in maize systems may have enhanced saturated infiltration rates. A direct link between earthworms and infiltration was not validated, but may not be excluded in the future, as earthworm populations may develop slowly because of adverse habitat conditions. Our results show that perennials support abundant and diverse earthworm populations and indicate the importance of functional redundancy and the diversity of food sources. The combination of both earthworm abundance and perennial cropping systems is capable of increasing on‐site ecosystem stability and supporting adaptation to climate change by increasing functional redundancy and, ultimately, providing ecosystem services. The noticeable occurrence of the latter, however, may be delayed because of the slow establishment of earthworm communities and delayed build‐up of ecosystems stability. Hence, a transitional phase is inevitable to reap the benefits of perennial energy cropping systems and must be accounted for.
多年生杯状植物(Silphium perfoliatum)和一年生青贮玉米(Zea mays)能源植物中的蚯蚓群落及其与地上有机残留物和水分渗透的关系
多年生能源作物系统被誉为减缓并有可能适应气候变化的一种可持续方式。由于没有耕作,种植杯状植物(Silphium perfoliatum)等多年生植物的土壤促进了蚯蚓群落的丰富和功能多样性。因此,在多年生耕作系统中,由于蚯蚓的活动和功能冗余(如垃圾分解、水分渗透和养分周转),生态系统服务的提供大大增强。我们研究了非耕作多年生系统和减少耕作的一年生系统中蚯蚓的数量和功能作用,以评估它们与各自地面有机残留物的关系及其对土壤水动态的影响。我们对杯形植物和玉米(玉米)田中的蚯蚓进行了采样,并同时测量了连续两年的饱和入渗率。此外,我们还在两个系统中每三个月对地上垃圾进行取样,并分析了总碳和氮的含量以及碳氮比。我们的田间调查显示,杯状植物系统中的蚯蚓丰度、物种多样性和丰富度明显更高,这可能是因为没有耕作和形成了垃圾层。玉米和杯状植物系统中幼体的高丰度表明栖息地条件恶劣,这可能是由于温度变化、积水和体积密度造成的。由于质量较差,田间废弃物在这两个系统中都是次要的食物来源,但在杯形植物系统中可能会对土壤水分平衡产生积极影响。玉米中的蚯蚓种群可能得到了有机肥料的支持,而杯形植物中的蚯蚓种群可能还得益于广泛的根系网络和较高的现场植物多样性。玉米系统中减少耕作制度可能会提高饱和渗透率。蚯蚓与渗透之间的直接联系没有得到验证,但将来也不排除这种可能,因为蚯蚓种群可能会因为不利的生境条件而发展缓慢。我们的研究结果表明,多年生植物能支持丰富多样的蚯蚓种群,并表明功能冗余和食物来源多样性的重要性。蚯蚓数量和多年生耕作系统的结合能够提高现场生态系统的稳定性,并通过增加功能冗余和最终提供生态系统服务来支持对气候变化的适应。然而,由于蚯蚓群落的建立速度较慢,生态系统稳定性的建立也较迟缓,后者的明显出现可能会被推迟。因此,要从多年生能源作物系统中获益,过渡阶段是不可避免的,必须考虑到这一点。
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来源期刊
Soil Use and Management
Soil Use and Management 农林科学-土壤科学
CiteScore
7.70
自引率
13.20%
发文量
78
审稿时长
3 months
期刊介绍: Soil Use and Management publishes in soil science, earth and environmental science, agricultural science, and engineering fields. The submitted papers should consider the underlying mechanisms governing the natural and anthropogenic processes which affect soil systems, and should inform policy makers and/or practitioners on the sustainable use and management of soil resources. Interdisciplinary studies, e.g. linking soil with climate change, biodiversity, global health, and the UN’s sustainable development goals, with strong novelty, wide implications, and unexpected outcomes are welcomed.
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