柬埔寨热带高地长期免耕种植系统下土壤有机碳和氮动态的非同步评估

IF 5.8 2区 农林科学 Q1 SOIL SCIENCE Soil Pub Date : 2024-10-10 DOI:10.5194/soil-10-699-2024
Vira Leng, Rémi Cardinael, Florent Tivet, Vang Seng, Phearum Mark, Pascal Lienhard, Titouan Filloux, Johan Six, Lyda Hok, Stéphane Boulakia, Clever Briedis, João Carlos de Moraes Sá, Laurent Thuriès
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引用次数: 0

摘要

摘要免耕(NT)种植系统是通过储存土壤有机碳(SOC)和全氮(TN)来应对土壤退化的一种策略。我们采用非同步和等效土壤质量的方法,量化了免耕耕作系统对 SOC 和 TN 储量变化的影响,以及对 100 厘米深的颗粒有机质和矿物相关有机质部分(POM 和 MAOM)的影响。这些实验于 2009 年开始,采用随机完整区组设计(三重复),包括以玉米 (MaiEx)、大豆 (SoyEx) 和木薯 (CasEx) 为基础的种植系统。每个实验包括三个处理:(1) 在传统耕作(CTM)条件下单一种植主要作物(玉米、大豆和木薯);(2) 在使用覆盖作物(NTM)的 NT 系统条件下单一种植主要作物;(3) 在使用覆盖作物(NTR)的 NT 系统条件下一年两次轮作主要作物,每年轮作两种作物,分别以 NTR1 和 NTR2 表示。土壤样本于 2021 年采集,即上次采样的 10 年之后。在 SoyEx 和 MaiEx 中,所有新氮肥系统都明显增加了表层土壤中的 SOC 储量(p<0.05),在 CasEx 中,SOC 储量增加到 40 厘米。从整个剖面(0-100 厘米)来看,MaiEx 和 CasEx 的 SOC 积累率分别为 0.86-1.47 和 0.70-1.07 兆克碳/公顷/年。虽然在 MaiEx 和 CasEx 的 CTM 中,SOC 储量在 0-20 厘米处明显增加,但在所有试验中,SOC 储量在 0-100 厘米处保持稳定。在 0-5 厘米处,NTR 系统在所有实验中都显著增加了 TN 储量,而在 NTM 系统中,只有 MaiEx 和 SoyEx 的 TN 储量显著增加。在 0-100 厘米处,所有实验中的 TN 储量在 NTR 系统下都保持稳定,而在 NTM 系统下,SoyEx 和 CasEx 的 TN 储量则明显减少。虽然在 MaiEx 和 SoyEx 中,所有 NT 系统下的 C-POM 储量都明显增加,但在 MaiEx 和 SoyEx 中,所有 NT 系统都明显增加了 0-10 厘米层的 C-MAOM 储量,在 CasEx 中则增加到 40 厘米。在 MaiEx 和 SoyEx,所有氮氧化物脱氮系统都明显增加了 0-10 厘米处的 N-POM 储量,而在 CasEx,5 厘米以下以及 MaiEx 和 SoyEx,40 厘米以下的 N-MAOM 储量明显减少。我们的研究结果表明,作物物种多样化的长期近地栽培系统不仅在地表积累了 SOC,而且还通过增加 POM 和 MAOM 中的 SOC 在整个剖面中积累了 SOC,即使在以木薯为基础的系统中也是如此。这项研究强调了新氮肥系统长期储存 SOC 的潜力,但也提出了有关土壤氮动态的问题。
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Diachronic assessment of soil organic C and N dynamics under long-term no-till cropping systems in the tropical upland of Cambodia
Abstract. No-till (NT) cropping systems have been proposed as a strategy to combat soil degradation by storing soil organic carbon (SOC) and total nitrogen (TN). We quantified the impacts of NT cropping systems on the changes in SOC and TN stocks and in particulate and mineral-associated organic matter fractions (POM and MAOM), to 100 cm depth, from three 13-year-old experiments in a tropical red Oxisol in Cambodia using diachronic and equivalent soil mass approaches. Established in 2009 and arranged in a randomized complete-block design with triplicates, the experiments included maize (MaiEx)-, soybean (SoyEx)-, and cassava (CasEx)-based cropping systems. Each experiment comprised three treatments: (1) mono-cropping of main crops (maize, soybean, and cassava) under conventional tillage (CTM); (2) mono-cropping of main crops under NT systems with the use of cover crops (NTM); and (3) bi-annual rotation of main crops under NT systems with the use of cover crops (NTR), with both crops being presented every year and represented by NTR1 and NTR2. Soil samples were collected in 2021, 10 years after the last sampling. All the NT systems significantly (p<0.05) increased SOC stock in the topsoil in SoyEx and MaiEx and down to 40 cm in CasEx. Considering the whole profile (0–100 cm), the SOC accumulation rates ranged from 0.86 to 1.47 and from 0.70 to 1.07 Mg C ha−1 yr−1 in MaiEx and CasEx, respectively. Although SOC stock significantly increased in CTM at 0–20 cm in MaiEx and CasEx, it remained stable at 0–100 cm in all the experiments. At 0–5 cm, NTR systems significantly increased TN stock in all the experiments, while, in NTM systems, it was only significant in MaiEx and SoyEx. At 0–100 cm, TN stock in all the experiments remained stable under NTR systems, whereas a significant decrease was observed under NTM systems in SoyEx and CasEx. Although C-POM stock significantly increased under all NT systems limited to 0–10 cm in MaiEx and SoyEx, all the NT systems significantly increased C-MAOM stock in the 0–10 cm layer in MaiEx and SoyEx and down to 40 cm in CasEx. All the NT systems significantly increased N-POM stock at 0–10 cm in MaiEx and SoyEx, while a significant decreased in N-MAOM stock was observed below 5 cm in CasEx and below 40 cm in MaiEx and SoyEx. Our findings showed that long-term NT systems with crop species diversification accumulated SOC not only on the surface but also in the whole profile by increasing SOC in both the POM and MAOM, even in the cassava-based system. This study highlights the potential of NT systems for storing SOC over time but raises questions about soil N dynamics.
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来源期刊
Soil
Soil Agricultural and Biological Sciences-Soil Science
CiteScore
10.80
自引率
2.90%
发文量
44
审稿时长
30 weeks
期刊介绍: SOIL is an international scientific journal dedicated to the publication and discussion of high-quality research in the field of soil system sciences. SOIL is at the interface between the atmosphere, lithosphere, hydrosphere, and biosphere. SOIL publishes scientific research that contributes to understanding the soil system and its interaction with humans and the entire Earth system. The scope of the journal includes all topics that fall within the study of soil science as a discipline, with an emphasis on studies that integrate soil science with other sciences (hydrology, agronomy, socio-economics, health sciences, atmospheric sciences, etc.).
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