Effects of litter placement, soil moisture and temperature on soil carbon dioxide emissions in a sandy grassland soil

IF 1.1 4区 农林科学 Q3 AGRICULTURE, MULTIDISCIPLINARY
Elnazsadat Hosseiniaghdam, Haishun Yang, Martha Mamo, Michael Kaiser, Walter H. Schacht, Kent M. Eskridge, Gandura O. Abagandura
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Abstract

Semiarid grasslands contribute significantly to global soil carbon (C) storage. Carbon loss from these systems via microbial decomposition is controlled by abiotic and biotic factors such as soil moisture and temperature and C input. Plant litter in these systems can be present above the soil surface or mixed with surface soil by trampling, especially in intensively grazed areas. A quantitative understanding of abiotic factors' interactive effect is critical for predicting soil C dynamics in response to grassland management and environmental conditions changes. Therefore, we conducted a 3-month laboratory incubation experiment to quantify the impact of litter placement and soil moisture on soil carbon dioxide (CO2) emissions under three controlled temperatures. The treatments including three litter placements (no litter, litter on top and litter mixed with surface soil) and three soil moisture levels (23%, 37% and 50% water-filled pore space [WFPS]) were incubated at three temperatures (10°C, 20°C and 30°C). Carbon dioxide fluxes were measured every 2 weeks. Soil CO2 fluxes were higher for all moisture and litter treatments initially and declined overtime at 20°C and 30°C. Mixing litter with soil increased the cumulative CO2 emissions by 24% and 19.5% at 20°C and 30°C, respectively, compared to no litter. Also, soil-litter mixing compared with litter on top showed a 14.3% and 21.6% increase in cumulative CO2 emissions at temperatures of 20°C and 30°C, respectively. At all temperatures, 37% and 50% WFPS resulted in similar cumulative CO2 emissions. The results from this study indicate that rising temperatures from 10°C to 30°C accelerate the effect of soil litter mixing on increasing CO2 emissions compared to litter on top and no litter.

Abstract Image

凋落物放置、土壤湿度和温度对沙质草地土壤二氧化碳排放的影响
半干旱草原对全球土壤碳(C)储量贡献显著。这些系统通过微生物分解产生的碳损失受土壤湿度、温度和碳输入等非生物和生物因素的控制。这些系统中的植物凋落物可出现在土壤表面以上或通过践踏与表层土壤混合,特别是在密集放牧地区。定量了解非生物因子的交互作用对于预测草地管理和环境条件变化下土壤C的动态变化至关重要。为此,我们进行了为期3个月的室内培养实验,以量化在3种控制温度下凋落物放置和土壤湿度对土壤二氧化碳(CO2)排放的影响。在3种温度(10°C、20°C和30°C)下培养3种凋落物(无凋落物、顶部凋落物和与表层土壤混合凋落物)和3种土壤水分水平(23%、37%和50%孔隙充水空间[WFPS])。每2周测量一次二氧化碳通量。在20°C和30°C条件下,土壤CO2通量在初始阶段均较高,随着时间的推移呈下降趋势。在20°C和30°C条件下,与不凋落物相比,凋落物与土壤混合的累积CO2排放量分别增加了24%和19.5%。在20°C和30°C温度下,土壤凋落物混合比顶部凋落物累积CO2排放量分别增加14.3%和21.6%。在所有温度下,37%和50%的粮食产量导致相似的累积二氧化碳排放量。本研究结果表明,与枯落物和无凋落物相比,温度从10°C升高到30°C加速了土壤凋落物混合对二氧化碳排放增加的影响。
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来源期刊
Grassland Science
Grassland Science Agricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
2.70
自引率
7.70%
发文量
38
审稿时长
>12 weeks
期刊介绍: Grassland Science is the official English language journal of the Japanese Society of Grassland Science. It publishes original research papers, review articles and short reports in all aspects of grassland science, with an aim of presenting and sharing knowledge, ideas and philosophies on better management and use of grasslands, forage crops and turf plants for both agricultural and non-agricultural purposes across the world. Contributions from anyone, non-members as well as members, are welcome in any of the following fields: grassland environment, landscape, ecology and systems analysis; pasture and lawn establishment, management and cultivation; grassland utilization, animal management, behavior, nutrition and production; forage conservation, processing, storage, utilization and nutritive value; physiology, morphology, pathology and entomology of plants; breeding and genetics; physicochemical property of soil, soil animals and microorganisms and plant nutrition; economics in grassland systems.
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