Your search keyword '"soil management"' showing total 3,596 results

1. Toxicological effects and stress tolerance mechanisms in <italic>Triticum durum</italic> (Nachit) and <italic>Triticum aestivum</italic> (Ibtissam) under caesium stress.

Author

Ammar, Ayyoub, El Mouridi, Zineb, Nouira, Asmae, and Boughribil, Said

Subjects

*POISONS, *TILLAGE, *CESIUM, *SOIL management, *GERMINATION

Abstract

This study examines the toxic effects of caesium (Cs) on Triticum aestivum (Ibtissam) and Triticum durum (Nachit), focusing on seed germination, root and shoot growth, and overall growth parameters. Cs exposure significantly impairs growth, with dose-dependent reductions in germination, root and shoot lengths, and fresh/dry weights. Notably, T. durum shows greater resilience to Cs stress than T. aestivum, maintaining better growth at higher Cs levels. The differing tolerance suggests T. durum may have more effective mechanisms to mitigate Cs toxicity. These findings highlight wheat’s sensitivity to Cs and T. durum’s potential for cultivation in contaminated soils. This research enhances understanding of Cs toxicity in wheat and offers insights for developing Cs-tolerant crops and better soil management practices. [ABSTRACT FROM AUTHOR]

Published

2024

2. Investigating soil health and resilience in small-scale agroecosystems of Mount-Lebanon.

Author

Nour Eddine, Mayassi, Thérèse, Atallah, Beshr, Sukkariyah, and Pandi, Zdruli

Subjects

*AGRICULTURE, *SOIL management, *SOIL productivity, *CONSERVATION tillage, *SOIL respiration, *TILLAGE, *NO-tillage

Abstract

In response to Lebanon's 2019 economic crisis, agricultural activities intensified to enhance national food security, with implications for soil health. We investigated soil management practices on 26 small-scale farms in a mountainous region, focusing on reconciling static sustainability definitions with dynamic resilience concepts. Surveying farmers revealed varied adoption rates of regenerative practices: intercropping (85%), residue retention (73%), cover crops (61%), organic amendments (46%), integrated organic/mineral amendments (46%), improved irrigation (38%), conservation tillage (30%), crop rotation (19%), and organic/biological pest/disease treatment (11%). Farms were categorized as conventional (C), neutral (N), and regenerative (R) based on practices. Qualitative assessments using seven indicators yielded scores of 4.28 (C), 6.34 (N), and 7.88 (R). Quantitative analyses showed significant differences in soil organic matter percentage (1.86 C, 2.75 N, 3.32 R), soil respiration (156 C, 296 N, 380 R), and earthworm abundance (2.92 C, 4.24 N, 5.72 R). The Soil Quality Index (SQI) indicated varying soil health from 0.05 (C) to 0.49 (R). Our findings highlight the importance of adopting synergistic, sustainable soil management practices to ensure enduring agricultural productivity and safeguard soil resilience, especially in the Mediterranean region. [ABSTRACT FROM AUTHOR]

Published

2024

3. The Impact of Long‐Term Tillage Systems on Soil Carbon and Nitrogen Dynamics and Other Nutrient Contents.

Author

Öztürk, Feyzullah, Ortaş, Ibrahim, and Anwar, Tauseef

Subjects

*CARBON in soils, *SOIL management, *TILLAGE, *WHEAT, *SOIL sampling, *TRACE elements, *SOIL mineralogy, *NITROGEN

Abstract

Different long‐term tillage systems were examined for their effects on the amount of native mycorrhizal spores in the rhizosphere and nonrhizosphere soils, as well as their effects on the organic carbon and mineral nutrient content of the soil. The long‐term study was initiated in 2006, using a Typic Haploxerert soil series, with the current study conducted in 2018–2019 using the Adana‐99 wheat variety. Seven tillage systems were examined: two no‐tills (NT and ST), three reduced tillage systems (RT‐1, RT‐2, and RT‐3), two conventional tillage systems (CT‐1 and CT‐2), and one strategic/occasional tillage system with three replicates as randomized blocks. The effects of tillage management on soil quality parameters were found by analyzing N, P, K, Mg, Ca, Cu, Fe, Zn, and Mn contents, as well as inorganic and organic carbon in soil samples taken before sowing and postharvest. Tillage systems had a significant influence on mineral nutrient concentrations. Reduced and no‐tillage methods, particularly strategic and no‐tillage, contribute positively to soil organic carbon (SOC) sequestration and nutrient retention and the number of mycorrhizae spores. The results show that as the tillage intensity decreased, the soil C, N, K, Ca, and Mg contents increased mycorrhizal spores. The rhizosphere soils under no‐tillage and reduced tillage practices had higher soil carbon content and higher mycorrhizae spore counts at the postharvest stage than soils under conventional tillage (CT) practices. Conclusively, after 13 years of different soil tillage treatments, more carbon was sequestrated under NT than under heavy tillage CT treatment. The ST tillage treatment sequestrated 19.37 Mt SOC (0–15 cm) and 10.06 (15–30 cm) Mt SOC compared with the CT‐1 tillage treatment. Comparing CT treatments, RT tillage and NT maintained higher carbon concentrations of up to 17% and 31%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

4. Effects of tillage management on soil organic carbon mineralization under double cropping rice system of southern China.

Author

Tang, Haiming, Shi, Lihong, Wen, Li, Cheng, Kaikai, Li, Chao, Li, Weiyan, and Xiao, Xiaoping

Subjects

*DOUBLE cropping, *SOIL management, *CROP residues, *PADDY fields, *SOIL enzymology, *NO-tillage, *TILLAGE

Abstract

Soil organic carbon (SOC) plays a vital role in maintaining or enhancing soil fertility and quality of paddy field, but there is still limited information about how SOC mineralization responds to different tillage managements under the double-cropping rice (Oryza sativa L.) system in southern of China. Therefore, this study was designed to explore the changes in SOC content, soil enzyme activities (invertase, cellulose and urease), SOC mineralization at 0–10 cm and 10–20 cm layers and its relationship with 7-years tillage management under the double-cropping rice system of southern China. The experiment included four tillage managements: rotary tillage with all residues removed as a control (RTO), conventional tillage with residue incorporation (CT), rotary tillage with residue incorporation (RT), and no-tillage with residue retention (NT). The results indicated that SOC and soil labile organic carbon contents at 0–10 cm and 10–20 cm layers in paddy field with CT and RT treatments were significantly higher than the RTO treatment. Compared to the RTO treatment, SOC mineralization and accumulation at 0–10 cm and 10–20 cm layers in paddy field with CT, RT and NT treatments were increased. SOC accumulation and potential mineralization at 0–10 cm layer with NT treatment were significantly higher than the CT, RT and RTO treatments. Soil mineralization constant at 10–20 cm layer with CT treatment was significantly higher than those of RT, NT and RTO treatments. This result indicated SOC mineralization rate and accumulation at 10–20 cm layer of CT, RT, NT and RTO treatments were lower than those of treatments at 0–10 cm layer. Compared to RTO treatment, soil invertase, cellulose and urease activities with CT and RT treatments were significantly increased. Compared to RTO treatment, soil invertase, cellulose and urease activities at 0–20 cm layer of CT treatment increased by 22.6%, 46.2% and 89.0%, respectively. There was significantly positive correlation between SOC accumulation and SOC content, soil invertase, cellulose, urease activities, but SOC accumulation was significantly negative correlated with soil pH, bulk density. Therefore, CT and RT treatments were beneficial managements to improve SOC content and SOC mineralization in the double-cropping rice field of southern China. [ABSTRACT FROM AUTHOR]

Published

2024

5. Vineyard cover crop management strategies and their effect on soil properties across Europe.

Author

Liebhard, Gunther, Guzmán, Gema, Gómez, José A., Winter, Silvia, Zaller, Johann G., Bauer, Thomas, Nicolai, Annegret, Cluzeau, Daniel, Popescu, Daniela, Bunea, Claudiu‐Ioan, and Strauss, Peter

Subjects

*SOIL permeability, *SOIL management, *CROP management, *CARBON in soils, *SOIL structure

Abstract

Vineyard soils are often of inherently poor quality with low organic carbon content. Management can improve soil properties and thus soil fertility. In European wine‐growing regions, a broad range of inter‐row management strategies evolved based on specific local site conditions and the varying effects of management intensities on soil, water balance, yield and grape quality. Accordingly, there is a need to investigate the effects of locally common cover crop management strategies and tillage intensity on soil organic carbon content and soil physical parameters. In this study, we investigated the impact of the most common inter‐row management practices in Austria, France, Romania and Spain. In all countries, we compared paired sites. Each site with cover crops and inter‐row management of low intensity was compared with one site with (temporarily) bare soil and high management intensity. All studied sites with cover crops and low management intensity, except those in Spain, had higher organic carbon contents than the paired more intensively managed vineyards. However, the highly water‐limited Spanish vineyards with temporary cover crops had lower organic carbon contents than the paired sites with bare soil. Sites with more organic carbon had better results for bulk density, percolation stability (PS), hydraulic conductivity and available soil water, with soil hydraulic parameters being less pronounced than others. Country comparison of inter‐row weed control systems showed that PS was particularly low in sampled vineyards in Romania and Spain, where weed control is based on intensive mechanical tillage. Alternating management systems with tillage every second inter‐row showed a decrease in soil structure compared with permanent green cover. Thus, inter‐row management with cover crops and reduced tillage increases soil organic carbon content and improves soil structure compared with bare soil management. If local constraints, such as water scarcity, do not allow year‐round planting, alternating inter‐row management with several years of alternating periods may be an option to mitigate those adverse effects. However, negative impact on the soil structure occurs with the very first tillage operation, whereas negative effects on the carbon balance only appear after long‐term use of tillage. [ABSTRACT FROM AUTHOR]

Published

2024

6. X-ray Microtomography Analysis of Integrated Crop–Livestock Production's Impact on Soil Pore Architecture.

Author

Gaspareto, José V. and Pires, Luiz F.

Subjects

*SOIL management, *X-ray computed microtomography, *TILLAGE, *SOIL structure, *SOIL classification

Abstract

Integrated crop–livestock production (ILP) is an interesting alternative for more sustainable soil use. However, more studies are needed to analyze the soil pore properties under ILP at the micrometer scale. Thus, this study proposes a detailed analysis of the soil pore architecture at the micrometer scale in three dimensions. For this purpose, samples of an Oxisol under ILP subjected to minimum tillage (MT) and no tillage (NT) with ryegrass as the cover crop (C) and silage (S) were studied. The micromorphological properties of the soil were analyzed via X-ray microtomography. The MT(C) system showed the highest values of porosity (c. 20.4%), connectivity (c. 32.8 × 103), volume (c. 26%), and the number of pores (c. 32%) in a rod-like shape. However, the MT(S), NT(C), and NT(S) systems showed greater tortuosity (c. 2.2, c. 2.0, and c. 2.1) and lower pore connectivity (c. 8.3 × 103, c. 6.9 × 103, and c. 6.2 × 103), especially in S use. Ellipsoidal and rod-shaped pores predominated over spheroidal and disc-shaped pores in all treatments. The results of this study show that the use of ryegrass as a cover crop improves the soil physical properties, especially in MT. For S use, the type of soil management (MT or NT) did not show any differences. [ABSTRACT FROM AUTHOR]

Published

2024

7. Advancing the agave‐soil nexus approach: A systematic review.

Author

Queiroz, Hermano Melo, Ferreira, Tiago Osório, Cerri, Carlos Eduardo Pellegrino, Pereira, Gonçalo Amarante Guimarães, and Cherubin, Maurício Roberto

Subjects

*TILLAGE, *SUSTAINABLE agriculture, *SUSTAINABILITY, *SOIL science, *SOIL amendments

Abstract

Agave plants, found primarily in arid and semi‐arid regions, have been utilized by indigenous communities for various purposes for thousands of years. They currently serve as crops to produce alcoholic beverages and fibers. Despite their importance, there is limited understanding of the relationship between agave and soil. This article addresses some of the knowledge gaps regarding the interactions and benefits of the agave‐soil approach. Among all the documents reviewed, 153 discussed individual soil parameters (45 physical, 68 chemical, and 40 biological), 59 explored interactions between them, and 130 did not address soil aspects (i.e., soil was merely presented as a substrate for the growth and development of plants and was not examined in the study's findings). Moreover, the historical evolution of the research highlights two distinct periods (from 1985 to 2000 and between 2010 to 2023) of notable publication activity, with recent years witnessing a surge in studies involving soil management techniques, genetic improvement of agave species, bioremediation, and the use of residues for bioenergy, biofuel, and soil amendments. There is a notable increasing trend in diverse research areas interested in these interactions, reflecting a broader recognition of the importance of understanding soil functioning in agave cultivation. Indeed, from 2010 to 2023, the use of the keyword 'soil' increased by 96% in studies of agave cultivation. This shift in research trends suggests that scientific advances in agave cultivation and soil science can be expected, contributing to sustainable agriculture and the long‐term viability of agave‐based industries. This article underscores an opportunity for further research to optimize agave cultivation and processing (e.g., soil management and productivity), for different purposes while conserving soil health and promoting sustainable land‐use practices. [ABSTRACT FROM AUTHOR]

Published

2024

8. Winter wheat yield stability as affected by fertilizer-N, tillage, and yield environment.

Author

Obour, Augustine K., Holman, Johnathan D., Prasad, P. V. V., and Assefa, Yared

Subjects

SOIL management, WHEAT, CROP rotation, TILLAGE, REVENUE management, SORGHUM, NO-tillage, WINTER wheat

Abstract

With an increase in the frequency of hot-dry-windy weather and reported significant increase in winter wheat (Triticum aestivum L.) in-season average temperatures, it is important to understand how soil management affects yield stability. This study quantified the combined effects of tillage and fertilizer-N on winter wheat yield stability in a wheat–sorghum [Sorghum bicolor (L.) Moench]–fallow crop rotation. The research was conducted from 1975 to 2022 and the experimental design was a randomized complete block with a split-split-plot arrangement. Crop phases were the main plots, tillage (conventional tillage [CT], reduced tillage [RT], and no-tillage [NT]) in the sub-plot, and N application rates (0, 22, 45, and 67 kg N ha−1 or 0, 45, 90, and 134 kg N ha−1) in the sub-sub-plot. Results showed winter wheat yield under NT increased by 0.8 Mg ha−1, compared with about 1.1 Mg ha−1 for CT and RT, when environmental average increased by 1 Mg ha−1 for N rates ≤90 kg ha−1. Yields with CT and RT increased by 0.8 Mg ha−1, compared with about 1.1 Mg ha−1 rate for NT, when environmental average increased by 1 Mg ha−1 for N >90 kg ha−1. In 30%–52% of the time, CT wheat yield was greater than NT, but yield advantage with CT decreased as fertilizer-N rate increases. Yield stability of winter wheat varied by tillage and fertilizer rate. We concluded that NT wheat required greater N rates to reach the same yield potential as CT and RT, and long-term CT or RT wheat at 45 kg N ha−1 was most stable [ABSTRACT FROM AUTHOR]

Published

2024

9. Fire Impacts on Soil Properties and Implications for Sustainability in Rotational Shifting Cultivation: A Review.

Author

Arunrat, Noppol, Kongsurakan, Praeploy, Solomon, Lemlem Wondwossen, and Sereenonchai, Sukanya

Subjects

TILLAGE, SHIFTING cultivation, SOIL management, SOIL erosion, BACTERIAL diversity

Abstract

Fire, a prevalent land management tool in rotational shifting cultivation (RSC), has long been debated for its immediate disruption of surface soil, vegetation, and microbial communities. While low-intensity and short-duration slash-and-burn techniques are considered beneficial for overall soil function, the dual nature of fire's impact warrants a comprehensive exploration. This review examines both the beneficial and detrimental effects of fire on soil properties within the context of RSC. We highlight that research on soil microbial composition, carbon, and nitrogen dynamics following fire events in RSC is gaining momentum. After fires, soil typically shows decreases in porosity, clay content, aggregation, and cation exchange capacity, while sand content, pH, available phosphorus, and organic nitrogen tend to increase. There remains ongoing debate regarding the effects on bulk density, silt content, electrical conductivity, organic carbon, total nitrogen, and exchangeable ions (K+, Ca2+, Mg2+). Certain bacterial diversity often increases, while fungal communities tend to decline during post-fire recovery, influenced by the soil chemical properties. Soil erosion is a major concern because fire-altered soil structures heighten erosion risks, underscoring the need for sustainable post-fire soil management strategies. Future research directions are proposed, including the use of advanced technologies like remote sensing, UAVs, and soil sensors to monitor fire impacts, as well as socio-economic studies to balance traditional practices with modern sustainability goals. This review aims to inform sustainable land management practices that balance agricultural productivity with ecological health in RSC systems. [ABSTRACT FROM AUTHOR]

Published

2024

10. Microbiological Soil Quality Indicators Associated with Long-Term Agronomical Management of Mediterranean Fruit Orchards.

Author

Arous, Aissa, Gargouri, Kamel, Palese, Assunta Maria, Pane, Catello, Scotti, Riccardo, Zaccardelli, Massimo, Altieri, Gessica, and Celano, Giuseppe

Subjects

ELECTRIC conductivity of soils, SOIL management, ENVIRONMENTAL soil science, SOIL classification, AGRICULTURE, NO-tillage, ORCHARDS, TILLAGE

Abstract

Soil microorganisms play a crucial role in maintaining soil fertility sensu lato. Sustainable soil management aims to make the soil environment more hospitable increasing microorganism diversity and complexity by means of the minimal disturbance of soil and inputs of organic material. This results in the effective functioning of agricultural systems, better crop productivity, and a reduction in environmental impacts. A study was carried out to evaluate the effects of the long-term application (more than 15 years) of sustainable practices versus conventional ones on soil microbial biomass activity and its functional diversity within different Mediterranean commercial fruit orchards located in Southern Italy. A preliminary survey—performed using the electromagnetic induction technique (EMI)—guided the collection of representative soil samples by reducing the spatial heterogeneity of soil microorganisms. Soil management practices, based on no tillage and the recycling of organic materials of different origins and quality produced within the orchard, increased soil organic carbon, telluric microorganisms activity and their functional diversity compared to 'non-conservative' management methods such as continuous tillage. In addition, the rational use of the orchard-inside organic matter (natural/seeded grass cover and pruning material) allowed it to virtuously transform from useless waste into precious resources, eliminating the logistical and economic constraints for their disposal. The simultaneous use of different types of soil management strategies aimed at soil conservation reinforced the positive effects on the microbiological indicators of soil quality rather than the application of a single strategy. This study provides the opportunity to represent what could be the possible evolution of tilled orchards towards more balanced soil conditions when subjected to conservative practices, offering a reference model for fruit growers and technicians who want to improve the stability and the resiliency of their agrosystems. [ABSTRACT FROM AUTHOR]

Published

2024

11. No tillage and leguminous cover crop improve soil quality in a typical rainfed Mediterranean system.

Author

Farina, Roberta, Piccini, Chiara, Di Bene, Claudia, Fornasier, Flavio, Francaviglia, Rosa, Pennelli, Bruno, Vanino, Silvia, Russo, Mario, Cerasuolo, Marianna, and Troccoli, Antonio

Subjects

COVER crops, SOIL quality, TILLAGE, SOIL management, CROP management, DURUM wheat

Abstract

Soil and crop management influence soil organic carbon (SOC), chemical composition, and overall soil quality. In a Mediterranean region, a study initiated in 1994 examined the long-term effects of conventional tillage (CT) versus no-tillage (NT) practices. Initially focusing on continuous durum wheat cultivation until 2009, the experiment later introduced a 2-year rotation of durum wheat and Vicia faba L. cover crops in half of the CT and NT fields. SOC was monitored from 2008 to 2018, while microbial biomass (as dsDNA), soluble nitrogen (N), and enzyme activities (EAs) were monitored from 2011 to 2014 to evaluate the rotation's impact. Between 2009 and 2018, CT yields were on average 15% higher than NT, especially during high rainfall years. NT significantly increased SOC content in the 0–30 cm soil layer, along with higher levels of soluble N, dsDNA, and EAs at 0–10 cm depth. NT led to a 23% and 10% increase in SOC stock and SOC stock per equivalent soil mass compared to CT. EAs increased by over 50% under NT, indicating enhanced biological activity. The SOC increase due to NT was limited to the top 10 cm, with a decrease at deeper depths (up to 50 cm). Introducing cover crops over 4 years did not yield significant impacts, suggesting the need for a longer period to observe noticeable effects. Overall, adopting NT practices resulted in higher SOC concentration, enhanced soil biological activity, and improved biogeochemical cycles, emphasizing the positive impact of NT on soil health and sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

12. The effect of four tillage systems on agronomic properties and soil health indicators in southern Manitoba.

Author

Crittenden, Stephen, Cavers, Curtis, and Xing, Zisheng

Subjects

SOIL ripping, SOIL management, SOILS, SOYBEAN, RAPESEED, TILLAGE, NO-tillage

Abstract

Soil health encompasses the collective functioning of chemical, physical, and biological properties in soil. The extent to which soil management affects soil health and the links with agronomic outcomes remain unclear. This project aimed to understand the interrelations of tillage systems, soil health, and agronomic properties in Portage la Prairie, MB, Canada. Tillage systems were cultivation, deep tillage, raised beds, and vertical tillage. Soybean (Glycine max (L.) Merr), corn (Zea mays L.), and canola (Brassica napus L.) were all grown in 2020, 2021, and 2022. Crop yield, seed protein content, and seed oil content were measured each year. Soil samples were taken in spring 2021, fall 2021, and fall 2022 and analyzed for nitrate-N, ammonium-N, total N, ACE protein, water extractable organic N, water extractable total N, water extractable ammonium N, soil organic matter, soil organic carbon, calcium carbonate equivalent, CO2 burst, permanganate oxidizable carbon, water extractable organic C, pH, salts, Olsen P, K, S, sand, silt, and clay. Tillage system had a significant impact on agronomic properties in seven crop by sampling combinations. Tillage system effected soil nitrate-N concentration at five crop by sampling combinations, three more than any other soil property. Soybean agronomic properties correlated with soil health indicators more frequently than for corn and canola. This suggests that the utility of soil health indicators may be crop specific. Further research is needed to understand the mechanisms underpinning the ability of soil health indicators to predict agronomic outcomes and to benchmark soil health indicator values with time. [ABSTRACT FROM AUTHOR]

Published

2024

13. Impact of Agricultural Activities on Climate Change: A Review of Greenhouse Gas Emission Patterns in Field Crop Systems.

Author

Xing, Yingying and Wang, Xiukang

Subjects

SUSTAINABLE agriculture, GREENHOUSE gases, SUSTAINABILITY, CROP management, NITROGEN fertilizers, AGROFORESTRY, TILLAGE

Abstract

This review paper synthesizes the current understanding of greenhouse gas (GHG) emissions from field cropping systems. It examines the key factors influencing GHG emissions, including crop type, management practices, and soil conditions. The review highlights the variability in GHG emissions across different cropping systems. Conventional tillage systems generally emit higher levels of carbon dioxide (CO2) and nitrous oxide (N2O) than no-till or reduced tillage systems. Crop rotation, cover cropping, and residue management can significantly reduce GHG emissions by improving soil carbon sequestration and reducing nitrogen fertilizer requirements. The paper also discusses the challenges and opportunities for mitigating GHG emissions in field cropping systems. Precision agriculture techniques, such as variable rate application of fertilizers and water, can optimize crop production while minimizing environmental impacts. Agroforestry systems, which integrate trees and crops, offer the potential for carbon sequestration and reducing N2O emissions. This review provides insights into the latest research on GHG emissions from field cropping systems and identifies areas for further study. It emphasizes the importance of adopting sustainable management practices to reduce GHG emissions and enhance the environmental sustainability of agricultural systems. [ABSTRACT FROM AUTHOR]

Published

2024

14. Improving the Soil Physical and Hydraulic Properties by Irrigation with Wastewater under Different Soil Tillage Management.

Author

Yerli, Caner, Sahin, Ustun, and Kiziloglu, Fatih Mehmet

Subjects

*WATER levels, *TILLAGE, *SOIL management, *IRRIGATION, *SEWAGE

Abstract

Irrigation with recycled wastewater increases the organic substance of the soil. Thus, the effect of the increased organic substance on the physical and hydraulic properties of the soil can be developed with different irrigation water quantities and soil tillage treatments. In this study, the effect of increased organic matter was determined after a two-year study carried out on a silage maize field irrigated at varying irrigation water levels of recycled wastewater (RWW) (100%, 67%, and 33% irrigation levels with RWW) and freshwater (FW) (100% irrigation level with FW) under direct sowing (DS) and conventional tillage (CT). RWW is compared to FW, the bulk density at 100% irrigation level was 1.5% lower, while porosity, aggregate stability, field capacity, wilting point, and available water were significantly higher by 1.9%, 12.0%, 2.8%, 2.2%, and 3.6%, respectively. Bulk density, aggregate stability, field capacity, wilting point, and available water were 1.5%, 4.3%, 3.3%, 2.2%, and 4.2% were significantly higher in DS according to CT, respectively, while porosity was 1.5% lower. These effects can be attributed to the RWW irrigation under DS due to the organic matter content in DS which was 1.1% higher than with CT, while RWW increased the organic matter content by 17% according to FW between full irrigations. As a result of the study, it was concluded that 100% irrigation levels using RWW directly within the scope of DS may be a practical approach to improve the physical and hydraulic properties of the silage maize field. [ABSTRACT FROM AUTHOR]

Published

2024

15. Tillage Practices Effect on Root Distribution and Variation of Soil CO 2 Emission under Different Cropping Strategies.

Author

Buivydienė, Agnė, Deveikytė, Irena, Veršulienė, Agnė, and Feiza, Virginijus

Subjects

*CATCH crops, *SOIL conservation, *CARBON emissions, *SOIL management, *WHEAT

Abstract

Conservation soil management strategies, particularly no-tillage and cropping strategies, have become an effective and widely adopted practice that has a direct influence on root parameters and mitigation of greenhouse gasses. However, the effect of different tillage and cropping strategies on root growth in field conditions is rarely studied. The study aimed to quantify and characterise the relationship between root network development and CO2 emission and how these parameters are affected by different cropping and tillage strategies. Five different crop rotations were tested, with or without the inclusion of catch crops (CC), by growing them in the soil where different tillage practices were applied. Selected cropping strategies differed among themselves in terms of the frequency of CC grown per rotation. The data revealed that in NT treatments, the CO2 emission (both autotrophic and heterotrophic simultaneously) was 25% higher than in CT. The cropping strategies were identified as an important factor influencing CO2 emissions. An increase in CO2 emission varied between 30 and 35% depending on the share of legume and CC inclusion. The frequency of CC grown per rotation has had an effect on the rate of CO2 emission. The cropping strategy when CC was grown every year showed the lowest amount of CO2 (by 26%), while in other cropping strategies, when CC was grown once or twice per rotation, significantly higher CO2 emissions were observed. Root growth and their development were significantly affected (p < 0.05) by soil depth and cropping strategies concerning root length and root volume changes. The inclusion of CC into the rotations led towards a decrease in root volume (by 21%). Root length (R2 = 0.45; p < 0.05) and root volume (R2 = 0.82; p < 0.05) had a significant impact on soil CO2 emissions. The results collected from 2021 to 2023 experiments indicated that cropping strategies and CC management areas are important tools not only for the improvement of root parameters but also for understanding how they affect CO2 emissions. The main message for stakeholders is that the cropping strategies diversification with the inclusion of CC every year in a winter oil-seed rape, spring wheat and pea crop rotation (R/W/P + CC) had demonstrated the possibilities to reduce CO2 emission and improve the root network parameters as compared to the monoculture strategy. [ABSTRACT FROM AUTHOR]

Published

2024

16. Chapter Two - No-till farming and climate change mitigation: Lessons learnt from long-term no-till experiments and future perspectives.

Author

Jayaraman, Somasundaram, Naorem, Anandkumar, Dalal, Ram C., Sinha, Nishant K., Rao, Ch. Srinivasa, Lal, Rattan, Kundu, S., Prasad, J. V. N. S., and Singh, A. K.

Subjects

*CLIMATE change mitigation, *AGRICULTURE, *TILLAGE, *NO-tillage, *SUSTAINABILITY, *SOIL degradation, *SOIL management

Abstract

Rapid population increase, urbanization, soil degradation and inappropriate management practices have put tremendous pressure on natural resources, particularly on soil, water, and vegetation. Soil resource is vital for farming to provide food and nutritional security performing ecosystem functions and services and achieving Sustainable Developmental Goals (SDGs). Worldwide, ~33% soil resource has been adversely degraded by diverse processes. To protect soil resource from further degradation, there is a strong need of sustainable soil management practices for enhancing soil organic carbon (SOC), soil health, and crop production in a sustainable manner. "No-till farming (NT)/conservation agriculture (CA)" has been widely practiced worldwide on about 210 million ha. The long-term NT experiments play a significant role in improving soil health, SOC sequestration, and in-depth understanding of greenhouse gas (GHG) emission, climate change mitigation and optimizing resource use efficiency, to cater for the needs of the present- and future-generations. According to FAO, NT/CA is a farming system that promotes minimum soil disturbance (i.e., no tillage), maintenance of a permanent soil cover, and diversification of plant species. This system increases biodiversity and natural biological processes in above- and below-ground surface, which helps in enhanced water- and nutrient use-efficiency and sustained crop production. From the literature, it is evident that shift from traditional/conventional tillage (CT) with residue burning/removal to NT/CA farming has been recognized as an important soil management practice/strategy for sustaining soil health, reducing soil erosion and reversing soil degradation. This chapter deliberates the effect of NT/CA on soil health, nutrient stratification, SOC dynamics through modeling, SOC sequestration, GHG emissions, socio-economic condition in adoption and also suggesting the future perspectives on NT and CA. [ABSTRACT FROM AUTHOR]

Published

2024

17. Long‐term effects of management practices on soil water, yield and water use of dryland wheat: A global meta‐analysis.

Author

Adil, Muhammad, Lv, Fenglin, Li, Tingting, Chen, Yi, Gul, Isma, Lu, Heli, Lu, Siqi, and Qiu, Lin

Subjects

*AGRICULTURAL conservation, *ARID regions agriculture, *SOIL conservation, *MULCHING, *SOIL management, *CONSERVATION tillage, *TILLAGE

Abstract

Soil water conservation in dryland agriculture mainly depends on precipitation. We chose 35 long‐term experiments and analysed the data by using meta‐analysis to check how fallow management methods affect soil water storage of dryland winter wheat planting (SWS), precipitation storage efficiency (PSE), crop yield and water use efficiency (WUE). No‐tillage (NT), compared to conventional tillage (CT) in the fallow period, increased PSE, SWS, grain yield and WUE by 32.9%, 27.1%, 30.5% and 22.6%, respectively. Reduced tillage (RT) and subsoil tillage (ST) increased PSE by 15.2% and 11.7%, SWS by 17.4% and 15.0% and grain yield by 15.5 and 13.8%, respectively, but these had a non‐significant effect on WUE. The conservation tillage methods interacted significantly with the residue management and fallow mulching practices. Compared to CT, the conservation tillage methods with fallow mulching increased PSE, SWS, grain yield and WUE, but the growing of cover crops (designated as biological mulching) decreased PSE, SWS and grain yield by 17.3%, 13.0% and 32.0%, and had a non‐significant impact on WUE. Under the condition of straw mulching, NT increased PSE, SWS, grain yield and WUE by 43.7%, 38.1%, 40.6% and 42.9%, respectively, compared to CT. NT and RT increased the PSE, SWS and WUE, under normal mean annual precipitation (MAP), however, ST increased these observations under wet MAP, compared to CT. The effects of tillage methods varied with soil texture, and they were highly interrelated with water conservation, wheat yield and water use. We conclude that compared to conventional tillage, the conservation tillage methods increased soil water conservation during the fallow period, which increased wheat yield and water use. Moreover, NT with or without residue retention increased the fallow water conservation and wheat yield. Crop residues should be retained while applying RT and ST to grow winter wheat in dryland regions. [ABSTRACT FROM AUTHOR]

Published

2024

18. Chapter Three - Impact of agronomic management on the soil microbiome: A southern Australian dryland broadacre perspective.

Author

Shi, Andong, Cavagnaro, Timothy R., Sumby, Krista M., McDonald, Glenn, Denton, Matthew D., Roy, Stuart J., and Schilling, Rhiannon K.

Subjects

*SOIL management, *SUSTAINABLE agriculture, *DRY farming, *AGRICULTURAL technology, *CLIMATE extremes, *TILLAGE

Abstract

To maintain sustainable broadacre farming in the future, a better understanding of soil microbiome functions and processes associated with adapting agronomic management practices will be key. This is primarily due to the irreplaceable roles of the soil microbiome in soil and plant interactions, human health and ecosystem functions and stability. We approached this challenge by reviewing how different land management practices influence soil microbial communities. The important role that the soil microbiome plays in cropping systems is analyzed in the context of an overview of changes in land management over the past two decades using southern Australian dryland farming as a case study. Many major changes in management have occurred in this system during this time, including (i) reduction in tillage, with a corresponding increase in direct drilling and stubble retention; (ii) inclusion of oilseeds and pulses in cereal-dominated rotation systems; (iii) decrease in the pasture-dominated grain production systems; (iv) increased use of agrochemicals; (v) different soil amelioration applications and (vi) development of innovative agricultural technology. We review the overarching role of climate extremes in impacting agronomic management practices in southern Australian farming systems. In all, we demonstrate the complex interplay between land management changes and the activity, diversity and functions of the soil microbiome, with reference to changes in agronomic management practices. [ABSTRACT FROM AUTHOR]

Published

2024

19. ASSESSMENT OF SOIL AGGREGATE STABILITY METHODOLOGIES IN CALCAREOUS SILT LOAMS.

Author

Yost, Jenifer L., Kruger, Kevin, Bjorneberg, David L., Dungan, Robert S., Leytem, April B., Moore, Amber D., and Schott, Linda R.

Subjects

*SOIL management, *SOIL structure, *CALCAREOUS soils, *IRRIGATION water, *AGRICULTURE, *TILLAGE, *SOIL erosion

Abstract

Idaho's Magic Valley is a highly productive agricultural region in the United States due to irrigation. The soils in this region are prone to crusting, have low organic matter, and are high in calcium carbonates, making them susceptible to erosion and water runoff. Soils need to be better managed to enhance aggregate stability to enable increased infiltration of irrigation water and decreased soil erosion in nearby waterways. However, to make management recommendations, the identification of appropriate measurements of aggregate stability needs to be identified, and few relevant studies exist. Thus, the overall goal of this project was to identify appropriate methods for the assessment of soil aggregate stability in the study region. The study sites were located in Southern Idaho and set up using common cropping rotations and agricultural management practices for the region using a variety of nutrient sources, tillage types, and cover cropping. Three methods were used to measure soil aggregate stability: wet sieving, simulated rainfall using a Cornell Sprinkle Infiltrometer (sprinkler height: 30, 90, and 150 cm), and the SLAKES mobile application. No differences in soil aggregate stability were found when the wet sieving or SLAKES methods were used at the three study sites, either due to the method or a general lack of differences between treatments. When using the Cornell Sprinkle Infiltrometer, no treatment differences were found at LT-Manure or GRACEnet; however, differences were observed between treatments at the Cover Crop study site at sprinkler heights of 30 and 90 cm. At a sprinkler height of 30 cm, the average mean weight diameter was the highest when winter forage crops (WFC) and solid dairy manure (SDM) were applied (3.73 mm) and the lowest in the control (3.12 mm). At a sprinkler height of 90 cm, the average mean weight diameter was the highest when WFC and SDM were applied (3.54 mm) and the lowest in the WFC Only treatment (2.46 mm). These results not only have implications for which methods are best for assessing progress but also for what management practices can be utilized to decrease soil erosion from irrigated cropland. This study highlighted that under these soils and management practices, simply increasing soil carbon does not increase aggregate stability, especially when root crops are included in the crop rotation with intensive tillage. In arid and semi-arid regions, the Cornell Sprinkle Infiltrometer may be a more sensitive method of measuring soil aggregate stability compared to traditional wet sieving. [ABSTRACT FROM AUTHOR]

Published

2024

20. 粉垄深松深耕改善南疆重度盐碱土理化性质和棉花产量及其后效.

Author

刘洪光, 李智杰, 李　玲, 徐　强, 白振涛, and 王潭刚

Subjects

*SOIL management, *SOIL salinity, *CASH crops, *SOIL density, *SOIL structure, *PLOWING (Tillage), *TILLAGE

Abstract

Cotton is an important cash crop in Xinjiang, accounting for 90.2% of China's total production in 2022. However, natural factors such as drought, high soil salinity, and the constraints of perennial shallow tillage soil management practices limit the yield and efficiency of cotton production and sustainable agricultural development. Deep vertical rotary tillage facilitates the breaking up of soil solidification and promotes the salt leached by irrigation water. In order to investigate the improvement effect of deep vertical rotary tillage on heavily saline cotton fields in Southern Xinjiang of China, this study conducted a 2 a (2021-2022) field experiment with three deep vertical rotary tillage depths (DT20: deep vertical rotary tillage 20 cm, DT40: deep vertical rotary tillage 40 cm, DT60: deep vertical rotary tillage 60 cm), and alternate with conventional tillage (five-share plowing 20 cm CT20), and CT20 was set to be the two consecutive years of conventional tillage. Original soil samples from 0-60 cm were collected to determine the water-stable aggregates. Soil moisture, salinity, organic carbon, total nitrogen, total phosphorus and total potassium were defermined by samples under the drip irrigation tapes, wide rows and narrow rows of each treatment on the 3rd day after each irrigation. Cotton root samples were collected at 105 days after sowing in 2021 and at 103 days in 2022. The effects of different depths of deep vertical rotary tillage on soil physical properties, soil nutrient content, cotton root length density, boll weight, dry matter mass accumulation and seed cotton yield were investigated, and the effect of crop yield was quantified by structural equation modeling. The results showed that: 1) deep vertical rotary tillage was able to loosen the soil in the tillage layer to optimize the soil structure. DT60 treatment was able to significantly reduce the soil bulk density, the content of coarse aggregates (>2 mm), and silt and clay particle (<0.053 mm) in the tillage depth layer compared with DT20 and CT20 treatment, which led to a significant reduction in mean weight diameter and mean geometric diameter, and increased total soil porosity and the content of micro-aggregates (<0.25～ 0.053 mm), while DT60 treatment was unable to further improve the soil structure in the deep soil layer compared with DT40 treatment. 2) DT40 and DT60 treatments were able to significantly increase soil moisture from 0-40 cm soil layer and reduce soil salinity and pH value, whereas DT20 treatment was only able to reduce soil salinity from 0-20 cm soil layer, whereas DT60 treatment was able to significantly reduce soil salinity and pH value from 0-60 cm soil layer compared with DT40 treatment. The reduction of soil salinity promoted the accumulation of soil organic carbon in the 0-40 cm soil layer and soil total nitrogen in the 0-60 cm soil layer, but DT60 treatment was unable to significantly increase soil organic carbon and soil total nitrogen in the 0-20 cm soil layer compared with the DT40 treatment. 3) The analysis of the structural equation modeling showed that soil salinity was an indirect factor affecting the seed cotton yield, and the accumulation of cotton’s dry matter and the weight of cotton bolls were the direct factored. The reduction of soil salinity favors soil nutrient accumulation and cotton root growth, promoted nutrient transport and accumulation to the plant organ, and increased cotton dry matter accumulation and seed cotton yield. Therefore, DT60 treatment had the best effect of soil salinity reduction, and thus the effect of yield increase. Comprehensive analysis showed that the depth of 60 cm on deep vertical rotary tillage with conventional tillage alternating can realize the synergy of improving and increasing the yield and efficiency of the severe saline cotton fields in the Southern Xinjiang of China. [ABSTRACT FROM AUTHOR]

Published

2024

21. Impact of Soil Management Practices on Soil Culturable Bacteriota and Species Diversity in Central European a Productive Vineyard under Warm and Dry Conditions.

Author

Šimanský, Vladimír, Kačániová, Miroslava, Juriga, Martin, Čmiková, Natália, Borotová, Petra, Aydın, Elena, and Wójcik-Gront, Elzbieta

Subjects

SOIL management, BACILLUS megaterium, BACILLUS cereus, BACILLUS thuringiensis, SUSTAINABILITY

Abstract

Sustainable management practices are crucial for the longevity of a monoculture vineyard, especially in the context of a changing climate. Therefore, soil management practices in a vineyard (T: tillage, T+FYM: tillage + farmyard manure, G: grass strips, G+NPK1: grass strips + rational rates of NPK, and G+NPK2: grass strips + higher rates of NPK) were tested in a temperate climate of Slovakia (Central Europe) under specific soil conditions (Rendzic Leptosol). We investigated the influence of continuous cropping on soil chemical properties and microbial communities during the dry and warm year of 2022. The results showed that the soil pH was higher by 19%, 21%, 24% and 13% in T, T+FYM, G and G+NPK1, respectively, compared to G+NPK2. The lowest soil organic matter (SOM) content was found in T, and it increased in the following order: T < T+FYM < G+NPK2 < G+NPK1 < G. Similarly, the lowest abundance of soil culturable bacteriota was found in T and it increased in the following order: T < T+FYM = G+NPK2 < G+NPK1< G. Culturable bacteriota was identified using mass spectrometry (MALDI-TOF MS Biotyper). The most numerous species group was Bacillus, followed by Lactobacillus > Staphylococcus > Pseudomonas. The most frequently isolated species were Bacillus megaterium (16.55%), Bacillus cereus (5.80%), Bacillus thuringiensis (4.87%), and Bacillus simplex (4.37%). Positive relationships between SOM and soil culturable bacteriota were found in the G and G+NPK1 treatments. Temperature also affected soil culturable bacteriota in all soil management practices, most significantly in G+NPK1. Overall, the best scenario for the sustainable management of a productive vineyard is the use of grass strips. [ABSTRACT FROM AUTHOR]

Published

2024

22. Microbial Activity and Diversity in Soil Sown with Zea mays and Triticosecale.

Author

Komorek, Dominika, Wyszkowska, Jadwiga, Borowik, Agata, and Zaborowska, Magdalena

Subjects

TILLAGE, SOIL management, CORN, ACID phosphatase, SOIL profiles

Abstract

The ongoing scientific debate on the selection of the best bioindicators to reflect the quality of arable soils indicates both their microbiome and biochemical parameters. Consideration has also been given to the fact that Zea mays has achieved the status of a crop used in the feed industry and for energy purposes, and Triticosecale is attracting increasing interest in this area. Therefore, the aim of this study was to determine the wide range of effects of Zea mays and Triticosecale cultivation on soil microbial and biochemical activity. The assessment of these parameters was based on the determination of microbial abundance, colony development index (CD), ecophysiological index of microbial diversity (EP), soil enzyme activities (dehydrogenases, catalase, urease, acid phosphatase, alkaline phosphatase, β-glucosidase, and arylsulfatase) as well as soil physicochemical properties. The innovative nature of the research was achieved by extending the pool of analyses to include both microbial biodiversity and analysis of soil samples at three depths: 0–20 cm; 21–40 cm; and 41–60 cm. It was found that the highest activities of soil enzymes and the abundance of organotrophic bacteria and fungi, as well as their colony development indices (CD), occurred within the rhizosphere and that their values decreased with increasing depth of the soil profile layers. Two phyla, Actinobacteria and Proteobacteria, representing the microbiome of arable soils, were identified independently of soil management practices. Unique bacterial genera in the soil under Triticosecale cultivation were Pseudonocardia, whereas Rhodoplanes, Nocardioides, and Rhodanobacter were found under Zea mays cultivation. The activity of all enzymes, especially urease and arylsulfatase, was significantly higher in the soil under Triticosecale. This was influenced by the more favorable physicochemical properties of the soil. [ABSTRACT FROM AUTHOR]

Published

2024

23. Impact of varied tillage practices and phosphorus fertilization regimes on wheat yield and grain quality parameters in a five-year corn-wheat rotation system.

Author

Ahmadi, Hadi, Mirseyed Hosseini, Hossein, Moshiri, Farhad, Alikhani, Hossein Ali, and Etesami, Hassan

Subjects

*AGRICULTURAL conservation, *TILLAGE, *WHEAT straw, *PHOSPHATE fertilizers, *GRAIN yields, *SOIL management, *WHEAT, *FERTILIZER application

Abstract

Choosing appropriate tillage methods and applying the right amount of chemical fertilizers are pivotal for optimizing wheat management and enhancing wheat quality. This study investigated the influence of conservation agriculture and phosphorus levels on nutrient content, yield components, and quality traits of wheat in a corn-wheat rotation. Conducted over five years in field conditions, the study employed a randomized complete block design with tillage treatments (conventional tillage, CT; minimum tillage, MT; and no tillage, NT) and phosphorus levels (no fertilizer use, P0; and 100% fertilizer recommendation, PR) as factors. Soil samples were collected during the fourth year (2021–2022). Results revealed significant impacts of tillage methods and phosphorus levels on wheat straw and grain nutrient composition, yield components, and quality traits. Conventional tillage yielded the highest values for protein content (12%), Zeleny sedimentation volume (20.33 mL), hardness index (45), water absorption (64.12%), and wet gluten content (25.83%). Additionally, phosphorus fertilizer application positively influenced protein percentage, gluten weight, and gluten index. The study highlights the potential of strategic soil management, particularly conventional tillage combined with phosphorus fertilization, to enhance wheat quality and yield. By elucidating these relationships, the findings contribute to optimizing wheat cultivation practices and advancing the development of superior wheat cultivars for baking applications. [ABSTRACT FROM AUTHOR]

Published

2024

24. Research on Soil Management and Conservation.

Author

Suzuki, Luis Eduardo Akiyoshi Sanches

Subjects

*SOIL management, *TILLAGE, *SOIL conservation, *AGRICULTURAL conservation, *COVER crops, *CUCUMBERS, *SOIL classification, *MACHINE learning

Abstract

The article discusses the importance of soil management and conservation for sustainable agriculture. It highlights the negative impacts of inadequate soil management on the environment, crop development, and human and animal health. The article presents various research findings on topics such as soil tillage, erosion control, the influence of plants on soil structure, and practices for soil conservation. It also emphasizes the need for further research on topics such as carbon sequestration, soil health assessment, and the effects of metal and microplastic contamination on soil and plant health. The article concludes by discussing the contributions of the research to sustainable development goals related to hunger, clean water, climate action, and life on land. [Extracted from the article]

Published

2024

25. Controlled Traffic Farm: Fuel Demand and Carbon Emissions in Soybean Sowing.

Author

Martins, Murilo Battistuzzi, Marques Filho, Aldir Carpes, Seron, Cássio de Castro, Guimarães Júnnyor, Wellingthon da Silva, Vendruscolo, Eduardo Pradi, Bortolheiro, Fernanda Pacheco de Almeida Prado, Blanco Bertolo, Diego Miguel, Lopes, Arthur Gabriel Caldas, and Santana, Lucas Santos

Subjects

*SUSTAINABLE agriculture, *SOYBEAN sowing, *TILLAGE, *GREENHOUSE gases, *CARBON emissions, *NO-tillage, *SOIL management, *SOYBEAN

Abstract

Soil compaction between crop rows can increase a machine's performance by reducing rolling resistance and fuel demand. Controlled Traffic Farm (CTF) stands out among modern techniques for increasing agricultural sustainability because the machines continuously travel along the same path in the field, reducing plant crush and compacting the soil in the traffic line. This study evaluated fuel consumption and CO2 emissions at different CTF intensities in different soil management strategies for soybean crop. The experimental design involved randomized blocks in a split-plot scheme with four replications. The plots constituted the three types of soil management: conventional tillage, no-tillage with straw millet cover, and no-tillage with brachiária straw cover. The subplots constituted for agricultural tractors were passed over in traffic lines (2, 4, and 8 times). We evaluated agricultural tractor fuel consumption, CO2 emissions, and soybean productivity. The straw cover and tractor-pass significantly affected the fuel consumption and greenhouse gas emissions of the soybean cultivation. Fuel consumption and CO2 emissions were reduced due to the machine-pass increase, regardless of soil management. Thus, a CTF reduces rolling resistance and increases crop environmental efficiency. Bare-soil areas increased by 20.8% and 27.9% with respect to fuel consumption, compared to straw-cover systems. Brachiária straw and millet reduce CO2 emissions per hectare by 20% and 28% compared to bare soil. Lower traffic intensities (two passes) showed (13.72%) higher soybean yields (of 4.04 Mg ha−1). Investigating these effects in other types of soil and mechanized operations then becomes essential. [ABSTRACT FROM AUTHOR]

Published

2024

26. Soil Microbial Functions Linked Fragrant Rice 2-Acetyl-1-Pyrroline with Soil Active Carbon Pool: Evidence from Soil Metagenomic Sequencing of Tillage Practices.

Author

Huang, Xiangwen, Lin, Jiajun, Xie, Qihuan, Shi, Jingdan, Du, Xiaoxu, Pan, Shenggang, Tang, Xiangru, and Qi, Jianying

Subjects

*TILLAGE, *LEUCINE, *CARBON in soils, *SOIL management, *AMINO acid metabolism, *METAGENOMICS, *HEMICELLULOSE

Abstract

Improved tillage management in fragrant rice cropping systems can enhance soil organic carbon (SOC) and the content of 2-Acetyl-1-Pyrroline (2-AP), a crucial volatile compound contributing to the aroma of fragrant rice. Despite this, the interplay between 2-AP content in fragrant rice and SOC metabolism, alongside the influences exerted by soil microbial functions, remains poorly understood. This study introduces a comprehensive 6-year field experiment which aims to correlate SOC with rice grain 2-AP content by analyzing soil microbial KEGG functions, such as carbon and amino acid metabolism, using metagenomic sequencing. The experiment assessed three tillage practices, conventional tillage (CT), reduced tillage (RT), and no tillage (NT), with soil samples collected on three dates in 2022. The results indicated that NT significantly (p < 0.05) enhanced SOC content and modified carbon metabolism by upregulating the Calvin cycle (K01601) and reducing hemicellulose degradation (K01710). Additionally, NT notably increased the soil levels of alkaline amino acids, such as histidine and ornithine, which were 165.17% and 1218.42% higher, respectively, than those in CT, possibly linked to an increase in soil pH. Furthermore, the 2-AP content in fragrant rice under NT was significantly higher by 52.02% and 13.90% compared to under RT and CT, respectively. NT also upregulated K00250 (alanine, aspartate, and glutamate metabolism) and K00290 (valine, leucine, and isoleucine biosynthesis), leading to significantly higher levels of 2-AP biosynthesis-related amino acids proline and glutamate in fragrant rice grain. This study links SOC and 2-AP biosynthesis via soil microbial functions, presenting a novel strategy for improving the quality of fragrant rice through soil management practices. [ABSTRACT FROM AUTHOR]

Published

2024

27. PREPARO CONVENCIONAL CONVERTIDO PARA SEMEADURA DIRETA: EFEITOS NOS ATRIBUTOS QUÍMICOS DO SOLO E NO MILHO.

Author

Natal Dal Piva, Ben-Hur, Bertol, Ildegardis, Ney Santos, Davi, Pinto dos Santos, Venesa, Luiz Mumbach, Gilmar, Kauling, Artur, and Frühauf de Oliveira, Marco

Subjects

*CORN farming, *GRAIN yields, *SOIL conservation, *SOIL management, *CORN, *TILLAGE

Abstract

This research aimed to evaluate the changes in the soil chemical attributes and their effects on the agronomic attributes of corn, after conversion from conventional tillage (PC) to no-tillage (SD), in a Inceptisol soil (Cambissolo Húmico alumínico léptico). In an experiment where PC and SD effects had been studied for 20 yr, main plots under PC were converted to SD and referred to as implemented SD (SDi) while plots under SD remained unaltered and were referred to as consolidated NT (SDc). The pH in water, exchangeable aluminum, potassium, calcium, and magnesium, extractable phosphorus, and total organic carbon (COT), were determined at the beginning of the experiment and after a 30-month period. The agronomic attributes of corn grown under SDi and SDc were also evaluated. At the end of the experiment, plots under SDi evidenced an increase in exchangeable aluminum and potassium and COT, and a decrease in pH and exchangeable calcium. Corn biomass accumulation in shoots and roots increased and higher grain yields were observed under SDc compared to SDi. [ABSTRACT FROM AUTHOR]

Published

2024

28. Soil health cycle.

Author

Maharjan, Bijesh, Das, Saurav, Thapa, Vesh R., and Sharma Acharya, Bharat

Subjects

SUSTAINABLE agriculture, TILLAGE, SOILS, CROP rotation, SCIENCE databases, SOIL management

Abstract

Soil health is pivotal to agricultural sustainability. Promoting and sustaining soil health management is challenging since it involves many interdependent components and steps and is an iterative process. Herein, the soil health cycle (SHC) is proposed as a soil health management cycle encompassing human dimensions, management practices, and their effects on soil health indicators (SHIs), leading to subsequent impacts on soil functions. The SHC provides a structure for an iterative testing of changes to improve soil health. A systematic review of research publications was also conducted using the Web of Science database supplemented by Elicit AI and Scopus API searches to determine the status of research reports connecting SHIs to soil function outcomes, a critical component in the SHC. The review focused on publications from 2000 to 2022 and highlighted that most soil health studies separately report the potential roles of soil health practices such as cover cropping, no‐tillage or reduced tillage, crop rotation, and crop–livestock integration in improving SHIs or soil function outcomes such as productivity and sustainability. The confidence in the causality of improved SHIs due to practices can be increased by demonstrably linking them to soil function outcomes such as productivity, environmental quality, and profitability. Presenting such evidence might allow us to tease confounding factors apart and present and contextually recommend soil health practices. It will also affect the human dimension in the SHC through informed and beneficial policies and incentives. Core Ideas: A very few studies reports soil health indicators and soil function benefits of practices simultaneously. Soil health cycle is a feedback cycle to achieve iterative soil health improvement.Soil health cycle integrates human dimension, practices, and their impacts on soil health and functions. [ABSTRACT FROM AUTHOR]

Published

2024

29. Perceptions and sociocultural factors underlying adoption of conservation agriculture in the Mediterranean.

Author

Topp, Emmeline, El Azhari, Mohamed, Cicek, Harun, Cheikh M'Hamed, Hatem, Dhraief, Mohamed Zied, El Gharras, Oussama, Puig Roca, Jordi, Quintas-Soriano, Cristina, Rueda Iáñez, Laura, Sakouili, Abderrahmane, Oueslati Zlaoui, Meriem, and Plieninger, Tobias

Subjects

AGRICULTURAL conservation, SOCIOCULTURAL factors, SUSTAINABLE agriculture, TILLAGE, SOIL conservation, SOIL management

Abstract

The Mediterranean region is facing major challenges for soil conservation and sustainable agriculture. Conservation agriculture (CA), including reduced soil disturbance, can help conserve soils and improve soil fertility, but its adoption in the Mediterranean region is limited. Examining farmers' perceptions of soil and underlying sociocultural factors can help shed light on adoption of soil management practices. In this paper, we conducted a survey with 590 farmers across Morocco, Spain and Tunisia to explore concepts that are cognitively associated with soil and perceptions of tillage. We also evaluated differences in perceptions of innovation, community, adaptive capacity, and responsibility for soil. We found that farmers' cognitive associations with soil show awareness of soil as a living resource, go beyond agriculture and livelihoods to reveal cultural ties, and link to multiple levels of human needs. Beliefs about the benefits of tillage for water availability and yield persist among the surveyed farmers. We found that openness towards innovation, perceived adaptive capacity and responsibility for soil were associated with minimum tillage, whereas community integration was not. Education, age and farm lifestyle were also associated with differences in these perceptions. CA promotion in the Mediterranean should emphasize the multiple values of soil, should demonstrate how sufficient yields may be achieved alongside resilience to drought, and be tailored to differing levels of environmental awareness and economic needs across north and south. [ABSTRACT FROM AUTHOR]

Published

2024

30. Trade‐offs and synergies of soil carbon sequestration: Addressing knowledge gaps related to soil management strategies.

Author

Maenhout, Peter, Di Bene, Claudia, Cayuela, Maria Luz, Diaz‐Pines, Eugenio, Govednik, Anton, Keuper, Frida, Mavsar, Sara, Mihelic, Rok, O'Toole, Adam, Schwarzmann, Ana, Suhadolc, Marjetka, Syp, Alina, and Valkama, Elena

Subjects

*SOIL management, *CARBON sequestration, *CARBON in soils, *CLIMATE change mitigation, *AGRICULTURAL conservation, *NO-tillage, *CONSERVATION tillage

Abstract

Soil organic carbon (SOC) sequestration in agricultural soils is an important tool for climate change mitigation within the EU soil strategy for 2030 and can be achieved via the adoption of soil management strategies (SMS). These strategies may induce synergistic effects by simultaneously reducing greenhouse gas (GHG) emissions and/or nitrogen (N) leaching. In contrast, other SMS may stimulate emissions of GHG such as nitrous oxide (N2O) or methane (CH4), offsetting the climate change mitigation gained via SOC sequestration. Despite the importance of understanding trade‐offs and synergies for selecting sustainable SMS for European agriculture, knowledge on these effects remains limited. This review synthesizes existing knowledge, identifies knowledge gaps and provides research recommendations on trade‐offs and synergies between SOC sequestration or SOC accrual, non‐CO2 GHG emissions and N leaching related to selected SMS. We investigated 87 peer‐reviewed articles that address SMS and categorized them under tillage management, cropping systems, water management and fertilization and organic matter (OM) inputs. SMS, such as conservation tillage, adapted crop rotations, adapted water management, OM inputs by cover crops (CC), organic amendments (OA) and biochar, contribute to increase SOC stocks and reduce N leaching. Adoption of leguminous CC or specific cropping systems and adapted water management tend to create trade‐offs by stimulating N2O emissions, while specific cropping systems or application of biochar can mitigate N2O emissions. The effect of crop residues on N2O emissions depends strongly on their C/N ratio. Organic agriculture and agroforestry clearly mitigate CH4 emissions but the impact of other SMS requires additional study. More experimental research is needed to study the impact of both the pedoclimatic conditions and the long‐term dynamics of trade‐offs and synergies. Researchers should simultaneously assess the impact of (multiple) agricultural SMS on SOC stocks, GHG emissions and N leaching. This review provides guidance to policymakers as well as a framework to design field experiments and model simulations, which can address knowledge gaps and non‐intentional effects of applying agricultural SMS meant to increase SOC sequestration. [ABSTRACT FROM AUTHOR]

Published

2024

31. Inversion Tillage Combined with Organic Fertilizer Application Increased Maize Yield via Improving Soil Pore Structure and Enzymatic Activity in Haplic Chernozem.

Author

Liu, Chunzhu, Han, Xiaozeng, Chen, Xu, Yan, Jun, Lu, Xinchun, Song, Bo, Wang, Wei, Zou, Wenxiu, and Ma, Xianfa

Subjects

*ORGANIC fertilizers, *FERTILIZER application, *SOIL structure, *POROSITY, *TILLAGE, *SOIL management

Abstract

Inversion tillage and organic fertilizer application can break the plow pan and improve soil quality. However, the effects of combining these practices on the soil microbial resource limitation and maize yield in Haplic Chernozem are unclear. In this research, a field experiment was established in 2018, and soil samples were collected in 2021 in Longjiang County in Northeast China, which is a Haplic Chernozem region. Four treatments comprising conventional tillage (T15), conventional tillage with organic fertilizer (T15+M), inversion tillage (T35), and inversion tillage with organic fertilizer (T35+M) were randomly arranged with four replications. Compared with T15 and T15+M treatments, soil bulk density significantly decreased by 11.1–16.3% in the 15–35 cm layer under T35 and T35+M treatments, accompanied by the improvement in soil pore structure (e.g., soil porosity, circularity, and Euler number). T15+M treatment significantly increased soil organic carbon and soil nutrient contents by 11.1–16.3% and 3.9–24.5% in the 0–15 cm layer compared with other treatments. However, soil organic carbon, total nitrogen, available phosphorus content, microbial biomass, and enzymatic activities reached the maximum values in the 0–35 cm layer under T35+M treatment. In addition, T35+M treatment had the highest maize yield and sustainable yield index. Extracellular enzymatic stoichiometry suggested that soil microorganisms are generally co-limited by carbon and phosphorus in Haplic Chernozem. However, T35+M treatment significantly reduced soil microbial resource limitation, which was one important factor impacting maize yield and sustainability. Random-forest and partial least-squares path modeling showed that T35+M treatment could reduce soil microbial resource limitation and increase the stability and sustainability of the maize yield by improving soil available nutrients, microbial biomass, and pore structure. Therefore, the incorporation of inversion tillage and organic fertilizer is a suitable soil management practice in view of increasing soil quality and crop yields in a Haplic Chernozem region. [ABSTRACT FROM AUTHOR]

Published

2024

32. Soil carbon and aggregate stability are positively related and increased under combined soil amendment, tillage, and cover cropping practices.

Author

Thapa, Binita and Mowrer, Jake

Subjects

*SOIL amendments, *SOIL structure, *CARBON in soils, *TILLAGE, *SOIL management

Abstract

Agricultural practices alter the organic carbon dynamics in soil. An experiment was conducted to study the effect of carbon amendments, tillage, and cover cropping on permanganate oxidizable carbon (POXC), total organic carbon (TOC), and wet aggregate stability (WAS) in a 2‐year crop sequence (corn–cover crop–cotton–cover crop) at the Texas A&M Research Farm. Two carbon amendments (biochar and composted biosolid) were applied at the rate of 500 kg C ha−1, along with a control. Two tillage practices were evaluated: conventional tillage (CT) and no‐tillage (No‐Till). A cover crop (CC) mixture of oat, mustard, and pea and no cover crop (No‐CC) were also evaluated. Treatments were arranged in a split‐split plot design with four replications. Amending the soil with carbon as composted biosolid or biochar affected POXC at both the 0‐ to 5‐ and 5‐ to 15‐cm depths. The POXC was significantly higher for the biochar treated plots for corn and CC after corn but significantly lower POXC was observed after cotton with biochar‐treated plots. The POXC increased under No‐Till compared with CT and CC plots relative to No‐CC plots. The TOC was not sensitive to soil management practices. The POXC and TOC both decreased with depth. The WAS greater under No‐Till and CC plots. The POXC and WAS were influenced by soil management practices and can be useful indicators to assess short‐term soil health improvements. The POXC and WAS were positively related, suggesting that one may be used to predict the other. Core Ideas: Permanganate‐oxidizable carbon (POXC) was sensitive to management practices compared to total organic carbon.POXC was greater on no‐tillage compared to conventional tillage.POXC was higher on cover cropped than no cover cropped plots.Soil aggregate stability was positively correlated with POXC.Wet aggregate stability was greater under biochar amended, no‐tillage, and cover cropped plots. [ABSTRACT FROM AUTHOR]

Published

2024

33. MODELING TILLAGE EFFECTS ON PLANT-AVAILABLE WATER BY CONSIDERING CHANGES IN SOIL STRUCTURE.

Author

Samanta, Sayantan, Bagnall, Dianna, Ale, Srinivasulu, Morgan, Cristine L. S., and Molling, Christine C.

Subjects

*SOIL structure, *SOIL management, *SOIL infiltration, *TILLAGE, *NO-tillage, *SOIL moisture, *SOIL erosion

Abstract

Management practices such as no-tillage (NT) have the potential to provide many benefits, such as reduced runoff and soil erosion and increased infiltration and soil water holding capacity. Most hydrological models that are used to simulate the effects of soil management are built based on empirical relationships between management and hydrology outcomes, and they tend to ignore or oversimplify the effects of soil structure. However, soil structure is management dependent and is a driver of water movement and storage in soil. The goal of this study was to better understand the effects of differences in soil structure between NT and conventional tillage (CT) on field-scale hydrology and plant available water (PAW). This study employed in-field measurements of soil structure in NT and CT fields in the Texas Blackland Prairies and used the Precision Agricultural-Landscape Modeling System (PALMS), which can simulate the effects of differences in soil structure. Regression analysis was performed on simulated soil water to understand the relative contributions of variations in surface roughness and macropore properties due to tillage on PAW. Results from this study showed that NT accumulated 44.8, 20.4, and 5.7 cm more PAW than CT in the top 150 cm of the soil profile during the summer growing season in the years 2006, 2008, and 2011, respectively, all of which encountered considerable dry spells. It was also found that the changes of soil structure due to tillage had about 4.5 times more impact on PAW than surface roughness. This study highlights the benefits of adopting NT over CT and showcases the importance of considering soil structure in modeling the effects of soil management on PAW. [ABSTRACT FROM AUTHOR]

Published

2024

34. Using Beerkan Procedure to Estimate Hydraulic Soil Properties under Long Term Agroecosystems Experiments.

Author

Vergni, Lorenzo, Tosi, Grazia, Bertuzzi, Jennifer, Rossi, Giulia, Farneselli, Michela, Tosti, Giacomo, Tei, Francesco, Agnelli, Alberto, and Todisco, Francesca

Subjects

ORGANIC farming, CROP management, CROPPING systems, TILLAGE, COVER crops, CROP rotation, WINTER wheat

Abstract

The BEST (Beerkan Estimation of Soil Transfer parameters) method was used to compare the hydraulic properties of the soils in two Long-term Agroecosystem Experiments (LTAEs) located at the FIELDLAB experimental site of the University of Perugia (central Italy). The LTAE "NewSmoca" consists of a biennial maize-durum wheat crop rotation under integrated low-input cropping systems with (i) inversion soil tillage (INT) or (ii) no-tillage (INT+) and (iii) under an organic cropping system with inversion soil tillage (ORG). ORG and INT+ involve the use of autumn-sown cover crops (before the maize cycle). Pure stand durum wheat was grown in INT and INT+, while a faba bean–wheat temporary intercropping was implemented in ORG. The LTAE "Crop Rotation" consists of different crop rotations and residue management, a continuous soft winter wheat and biennial rotations of soft winter wheat with maize or faba bean. Each rotation is combined with two modes of crop residue management: removal or burial. For INT+, despite the high-bulk density (>1.50 g/cm3), we found that conductivity, sorptivity and available water are comparable to those of INT, probably due to a more structured and efficient micropore system. ORG soils show the highest conductivity, sorptivity and available water content values, probably due to the recent spring tillage occurring in the wheat inter-row with the faba bean incorporation into the soil. For LTAE Rotation, the residue burial seems to influence the capacity-based indicators positively. However, the differences in the removal treatment are minor, and this could be due to the inversion soil tillage, which limits the progressive accumulation of organic matter. [ABSTRACT FROM AUTHOR]

Published

2024

35. Study on the effect of hydrothermal charcoal source modifier on saline-alkaline soil improvement.

Author

Shengchen ZHAO, Bo YANG, Yunhui LI, Wei WANG, Jiawei XIONG, Haibo CHANG, Dapeng WANG, and Jingmin YANG

Subjects

*TILLAGE, *SOIL salinity, *SOIL management, *SOIL enzymology, *SOIL acidity

Abstract

Land salinization has become a global issue. To mitigate this issue, the modifiers and water-soluble fertilizers have emerged as a promising strategy to enhance soil nutrient content and promote crop production in saline soils. In this study, based on the hydrothermal method for preparing corn stalks derived biochar prepared modifiers and water-soluble fertilizers for using in soda saline-alkali soil. Through field microplot experiments, the separate and interactive effects of different concentrations of them were studied, as well as their influence on the growth of alfalfa and Leymus chinensis on saline-alkali soil. The combined application of modifiers and water-soluble fertilizers can effectively increase soil nutrient content and enzyme activity, significantly reducing soil pH and alkalinity. It was found that the optimal application rate of 20 g/kg of improver resulted in a 4.99% decrease in pH of soil and 11.23% decrease in alkalinity. Additionally, organic matter, available P2O5, NH4 +-N, and NO3 --N contents increased by 25.74%, 28.48%, 19.87%, and 32.90%, respectively. Soil enzyme activities generally peaked at 20 g/kg of modifiers and water-soluble fertilizers, with sucrase showing the most significant increases, with 31.14% for alfalfa and 25.52% for L. chinensis. Two-way ANOVA results demonstrated significant interaction effects between the modifiers and water-soluble fertilizer on pH, Ca2+ and Mg2+ content, quick-acting potassium content, soil sucrase and urease activity, biomass of soil and alfalfa leaf width. Moreover, planting alfalfa and L. chinensis indicated that combined use of modifies and fertilizer had a significant effect on promoting crop cultivation in saline-alkali soil. Our findings provided a robust theoretical groundwork for improving the management of saline soils and optimizing crop production in such challenging environments. [ABSTRACT FROM AUTHOR]

Published

2024

36. Tillage Long-Term Effects on Soil Organic Matter Humification and Humic Acids Structural Changes in Regosol Profiles Typical of an Arid Region.

Author

Ben Mahmoud, Imen, Mbarek, Hadda Ben, Sánchez-Bellón, Ángel, Medhioub, Mounir, Moussa, Mohamed, Rigane, Hafedh, and Gargouri, Kamel

Subjects

*HUMIFICATION, *HUMIC acid, *ARID regions, *TILLAGE, *ORGANIC compounds, *NO-tillage, *MOLECULAR structure, *FLUORESCENCE spectroscopy

Abstract

This study aims to assess soil organic matter (SOM) humification and changes in molecular structures of humic acids (HAs) induced by long term management practices over soil profile under arid climate in south-eastern Tunisia. Two experimental fields were studied: the first was cultivated with olive tree and tilled for long term (CT) while the second was uncultivated without any management practices and with native vegetation (NC). Soil samples were collected at different depths from (CT) and (NC) profiles to determine chemical properties. Humic acids were isolated and studied by measuring UV-visible ratios (E465/665, E280/664 and E472/664) and fluorescence spectroscopy analysis. Results showed that long-term tillage practices reduced the SOM amount, aromatic condensation, molecular size and humification degree in surface layer of CT confirmed by the decrease in the fluorescence emission areas and UV-visible ratios. Inversely, in deep layers, results showed a greatly humified organic matter and aromatic structures condensation in CT. Long-term tillage leads to a significant decrease in aromatic condensation and OM humification in surface layers. Unmanaged soils provided a favorable environment to maintain OM chemical structures and restore soil quality under long-term management practices. [ABSTRACT FROM AUTHOR]

Published

2024

37. Construcción participativa de sistema de evaluación para el manejo agroecológico en suelos de pequeños productores.

Author

Santander-Mendoza, Sol

Subjects

*FOOD sovereignty, *SOIL management, *FAMILY farms, *RESOURCE management, *SUSTAINABILITY

Abstract

Family and small-scale farming systems are increasingly important in achieving food sovereignty and sustainability. This makes necessary to characterize them and develop systems to evaluate their sustainability, which allow the monitoring of the management of various resources with a participatory approach. In this work, the application of the MESMIS methodological framework is presented for the design of a system of indicators related to the management of soil resources in the Organoponic Garden of the farm El Guayabal, which respond to the premises of simplicity, sensitivity and easy application. The methodological scheme used in the construction of the system of indicators and the results obtained in its evaluation are presented. [ABSTRACT FROM AUTHOR]

Published

2024

38. Impacts of the tillage systems on the production of green corn (Zea mays L.) in long‐term plots in Northeastern Brazil.

Author

Santos, Jusimara de Andrade, Pedrotti, Alceu, Holanda, Francisco Sandro Rodrigues, Santos, Luiz Diego Vidal, Andrade, Brisa Marina da Silva, de Araújo Filho, Renisson Neponuceno, Villwock, Ana Paula Schervinski, Filho, Raimundo Rodrigues Gomes, Conceição, Soenne França, and Carvalho, Larissa dos Santos

Subjects

COVER crops, NO-tillage, COWPEA, TILLAGE, CORN, SOIL compaction, SUSTAINABILITY, AGRICULTURAL productivity, NITROGEN fertilizers

Abstract

In the current global context of climate change and the increasing demand for sustainability, optimizing agricultural production is very important in order to meet the demands for food and to mitigate environmental impact. To achieve sustainable agricultural production, particularly in regions with tropical soil and climate conditions, is necessary to adopt conservation‐oriented techniques. This includes no‐tillage system, the use of soil‐cover crops, and the application of inoculants. The objective of this research was, at the end of the 22nd cropping season, to assess the influence of soil compaction in the production of green corn (Zea mays L.) in a long‐term field experiment. This study was conducted under different soil tillage systems in a Red‐Yellow Ultisol from the Coastal Tablelands of northeastern Brazil. Three soil tillage systems were applied: Conventional Tillage (CT), Minimum Tillage (MT), and No‐tillage (NT). These were combined with four previous crops: cowpea (Vigna unguiculata), crotalaria (Crotalaria juncacea), pigeon pea (Cajanus cajan), and millet (Pennisetum glaucum), as well as two levels of nitrogen fertilizer application: (1) 100% of the recommended N dose, and (2) 50% of the recommended N dose plus Azospirillum brasilense inoculant. The experimental design consisted of strip plots with subplots divided and randomized within each strip, with three replications. Soil compaction was assessed using parameters of soil density (SD) and soil mechanical resistance to penetration (MRP) in conjunction with moisture content (MC). The principal component analysis (PCA) highlighted that conservation‐oriented systems exhibited greater soil organic carbon (SOC) levels, leading to increased productivity of commercial green corn cobs. The synergistic effect of diversifying previous crops and adopting conservation tillage systems, especially in soils under long‐term tillage, resulted in heightened productivity of commercial green corn ears. [ABSTRACT FROM AUTHOR]

Published

2024

39. Soil tillage reduction as a climate change mitigation strategy in Mediterranean cereal‐based cropping systems.

Author

Fiorentini, Marco, Orsini, Roberto, Zenobi, Stefano, Francioni, Matteo, Rivosecchi, Chiara, Bianchini, Marco, di Tella, Biagio, D'Ottavio, Paride, Ledda, Luigi, Santilocchi, Rodolfo, and Deligios, Paola

Subjects

CLIMATE change mitigation, TILLAGE, DURUM wheat, CROPPING systems, SOIL management, EMMER wheat, AGRICULTURAL policy

Abstract

According to climate change projections, global temperatures would increase by 2°C by 2070, and agriculture is expected to be among the most affected sectors, particularly intensive field crops like cereals. Therefore, researchers need to investigate the most cost‐effective agricultural strategies that can prevent production losses and ensure global food security. This study aimed to identify the limiting factors of durum wheat (Triticum turgidum L. subsp. Durum (Desf.) Husn.) yield production under Mediterranean conditions. Durum wheat yield data of over 5 years (2017–2022), from a 30‐year rainfed long‐term experiment conducted in the 'Pasquale Rosati' experimental farm of the Polytechnic University of Marche in Agugliano, Italy (43°32' N, 13°22′ E, 100 a.s.l.) on Calcaric Gleyic Cambisols with a silt‐clay texture, were analysed and compared with the recorded thermo‐pluviometric trend. The field trial included two soil managements (no tillage vs. conventional tillage) and three Nitrogen (N) fertilization levels (0, 90, and 180 kg N ha−1). The most important driver for durum wheat production was N fertilization. However, in the absence of N fertilization, no tillage showed a higher yield (+1.2 t ha−1) than conventional tillage due to the accumulation of organic matter in the soil. When wheat was fertilized with 90 kg N ha−1, no tillage resulted in 25% yield more than conventional tillage (+1.2 t ha−1), but this occurred only when the increase in temperatures was constant from January until harvest (this happened in 3 of 5 years of monitoring). The non‐constant increase in temperature from January to wheat harvest may hamper crop phenological development and reduce the potential yield. The highest fertilization rate (180 Kg N ha−1) resulted in the highest wheat yields regardless of soil management and thermo‐pluviometric trends (5.78 t ha−1). After N fertilization and soil management, the minimum and maximum temperature in February and the maximum temperature in April were crucial for durum wheat production under Mediterranean condition. When there is non‐constant increase in temperature from January to wheat harvest no‐tillage should be preferred over conventional tillage because wheat yields did not reduce under no tillage. Thus, agricultural policies that support the switch from conventional tillage to no‐tillage management should be promoted to enable food security in Mediterranean environments. [ABSTRACT FROM AUTHOR]

Published

2024

40. Effect of cover crops and tillage systems on soil quality and sugarcane yield.

Author

Carneiro, Marina Pedroso, de Souza, Zigomar Menezes, Farhate, Camila Viana Vieira, Cherubin, Maurício Roberto, and Panosso, Alan Rodrigo

Subjects

TILLAGE, COVER crops, SOIL quality, SUSTAINABILITY, SUGARCANE, SOIL management, POTASSIUM

Abstract

The management adopted in the establishment and replanting of sugarcane fields, with conventional tillage followed by fallow, is one of the main causes of soil quality degradation. In this context, the soil quality index (SQI) is an important tool to guide the use of more sustainable practices and management. This study aimed to monitor the effect of different cover crops in association with different tillage systems on sugarcane yield based on key indicators and an SQI developed using the Soil Management Assessment Framework (SMAF). The experiment was carried out on a sugarcane expansion area located in the municipality of Ibitinga, São Paulo, Brazil. The following soil physical and chemical attributes were analyzed: soil bulk density, macroaggregates, available phosphorus and potassium. Soil carbon content was also analyzed and used to calculate the SQI. Productivity over the 4 years of sugarcane cultivation was also analyzed. The use of subsoilers for soil tillage proved efficient in managing compaction by providing lower soil bulk density values in the first years of cultivation (1.59 and 1.63 g cm−3); however, these effects occurred in the short term with a 10% increase in later years. The use of millet in association with subsoiling showed the best results for soil quality (0.59), reflected in the maintenance of yields at 100 Mg ha−1 over time. Thus, our study reinforces the importance of using soil conservation systems in sugarcane replanting areas to achieve production longevity. [ABSTRACT FROM AUTHOR]

Published

2024

41. Short‐term effects of double‐layer ploughing reduced tillage on soil structure and crop yield.

Author

Pöhlitz, Julia, Schlüter, Steffen, and Rücknagel, Jan

Subjects

PLOWING (Tillage), TILLAGE, SOIL structure, CROP yields, COMPUTED tomography, SOIL management, CROP quality

Abstract

Soil tillage is widely acknowledged to affect soil characteristics and agricultural productivity. This research investigates the short‐term effects of various tillage methods on soil physical properties and crop yields at a Central German field site with a dry climate (mean temperature 9.5°C; annual precipitation 470 mm). Three tillage approaches were evaluated: conventional plough tillage (25 cm depth), cultivator tillage (18 cm depth), and double‐layer plough tillage (15 and 30 cm depth). We assessed soil physical properties through standard laboratory analyses, compression tests, soil pore structure via X‐ray computed tomography (X‐ray CT) and crop yields over 3 years. The results indicate that cultivator tillage approach increased soil bulk density relative to conventional tillage, especially in the second year, though this effect diminished over time. Double‐layer plough tillage emerged as a viable short‐term alternative to conventional tillage, achieving comparable soil bulk density. Saturated hydraulic conductivity values were generally higher for soils under conventional tillage or double‐layer plough tillage than for cultivator tillage, highlighting their soil loosening effect. Classical soil analysis methods combined with X‐ray computed tomography provided valuable insights into tillage induced changes to soil structure. Cultivator tillage resulted in a distinct pore structure with reduced macroporosity and pore connectivity. Despite notable soil property variations, crop yields remained consistent across the tillage methods. Overall, double‐layer plough tillage presents a sustainable option, moderately improving soil physical properties while maintaining crop yields. This study highlights the need to assess the short‐term effects of tillage on soils and contributes to the broader dialogue on optimizing tillage strategies for effective soil management and crop production. [ABSTRACT FROM AUTHOR]

Published

2024

42. Using GIS and Geostatistics to Monitoring Spatial Variability in Soil Chemical Properties Impacted by Cultivation Practices.

Author

Y. A., Sayed and Khalafalla, M. Y.

Subjects

GEOGRAPHIC information systems, CHEMICAL properties, SOIL salinity, TILLAGE, SOIL management, SOILS

Abstract

Copyright of Journal of Soil Sciences & Agricultural Engineering is the property of Egyptian National Agricultural Library (ENAL) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

43. Water Infiltration in Different Soil Covers and Management in the Cerrado–Amazon Ecotone, Brazil.

Author

Alves, Marco Aurélio Barbosa, Borella, Daniela Roberta, Paulista, Rhavel Salviano Dias, Almeida, Frederico Terra de, Souza, Adilson Pacheco de, and Carvalho, Daniel Fonseca de

Subjects

*SOIL infiltration, *SOIL management, *LAND cover, *HYDROLOGIC cycle, *TILLAGE, *SOIL moisture

Abstract

Soil water infiltration is an important component of the hydrological cycle, and it is best evaluated when the raindrop impacts the ground surface. For this reason, it is affected by changes in land use and land cover and by the characteristics and physical–hydric properties of the soil. This study aimed to evaluate soil water infiltration in areas occupied by annual crops (soybean and corn) and pastures in two watersheds of the Teles Pires River-MT, using simulated rainfall, physical models, and principal component analysis. Infiltration rates were evaluated based on simulated rainfall with an average intensity of 75 mm h−1, with four repetitions per region (upper, middle, and lower) of the hydrographic sub-basins of the Caiabi and Renato rivers, and soil use with cover, without cover, and disturbed. Soil tillage provided higher water infiltration rates into the soil, especially in pasture areas in the two hydrographic sub-basins. There were significant adjustments to the mathematical models based on the infiltration rate data for all land use and land cover conditions. The soil attributes that most interfered with the infiltration rate were microporosity, bulk density, and total porosity in the crop areas of the middle Caiabi and microporosity, clay content, total porosity, and silt content in the areas farming at the source of the Renato River. The Horton and Philip models presented the best adjustments in the hydrographic sub-basins of the Caiabi and Renato Rivers, which are recommended for estimating the water infiltration rate into the soil in different uses, coverages, and regions. [ABSTRACT FROM AUTHOR]

Published

2024

44. Temporal variations in soil aggregate re‐formation behaviors after disturbance by tillage.

Author

Ozlu, Ekrem and Arriaga, Francisco J.

Subjects

*SOIL structure, *TILLAGE, *SOIL permeability, *PORE size distribution, *SOIL management, *AQUATIC exercises

Abstract

Aggregate re‐formation after a disturbance is important for maintaining soil hydraulic status and carbon stabilization. A study investigating the re‐formation of aggregates after disturbance by spring tillage was conducted at a site located on a south‐facing (6%) slope with a silt‐loam soil at Arlington‐Wisconsin in 2018 and 2019. Treatments were conventional tillage (CT) and no‐tillage (NT) with winter application of solid manure (SM) and no manure in a complete randomized design. Soils under NT had a higher proportion of larger aggregates (>1 mm), whereas the proportion of smaller (<1 mm) aggregates was greater under CT. Soil organic carbon, total nitrogen, bulk density, soil water retention, and micropores of NT treatments were higher compared to CT systems at 0‐ to 5‐cm depth. However, the impacts of manure application on soil properties were not significant, except for those of soil organic carbon (SOC) and total nitrogen. Harvesting in 2018 decreased the relative proportion of aggregates smaller than 1 mm and hydraulic conductivity of saturated soil. These results indicate that the immediate effect of tillage is to decrease larger aggregates, SOC, and total porosity, whereas harvesting decreases the proportion of smaller aggregates. Comparatively, aggregates smaller than 1 mm were mainly influenced by the long‐term effects of the management operations. It appears that larger aggregates can recover on an annual basis, but aggregates smaller than 1 mm do not. In long‐term studies, there is a need to monitor aggregates, including their size distribution and pore structures, to identify aggregate turnover time and rate, which will augment our understanding of aggregate formation. Core Ideas: No‐till developed larger aggregates while conventional tillage lead formation of smaller aggregates.The greater proportion of larger aggregates was linked to higher soil organic carbon (SOC), nitrogen, and bulk density (ρb).Immediate effects of management reduced soil structure due to higher ρb and lower SOC.Note that 1‐ to 4‐mm aggregates were not maintained after tillage disruption.Aggregates <1 mm cannot re‐form annually since they are related to long‐term effect. [ABSTRACT FROM AUTHOR]

Published

2024

45. Degree of compaction, aeration, and soil water retention indices of a sugarcane field without soil disturbance after initial tillage.

Author

Awe, Gabriel Oladele, Fontanela, Eracilda, and Reichert, José Miguel

Subjects

SOIL moisture, SOIL management, TILLAGE, SOIL compaction, COMPACTING

Abstract

Soil compaction after initial soil tillage for crop establishment has been a major problem in crop fields because of its deleterious effects on soil functioning and crop performance. Therefore, the study aimed to determine the degree of compaction, soil air capacity, near-surface optimum ratios, and water retention characteristics in a sandy loam. Dystrophic Paleudalf initially under different tillage methods for sugarcane crop but without tillage for two seasons in southern Brazil. Initial soil tillage systems consisted of no-tillage (NT), compacted no-tillage (NTC), conventional tillage, and chiseling of no-tillage (Ch). Disturbed and undisturbed soil was sampled from 0 to 10, 10 to 20, 20 to 40, and 40 to 60 cm layers to determine degree of compaction, air capacity, near-surface optimum ratios, soil water retention characteristics, and soil physical quality index S. Initially, NT treatment had the significantly (p < 0.05) lowest degree of compaction (87%), highest soil air capacity (0.104 cm3 cm−3), air capacity/total porosity ratio (0.261), and better water retention characteristics in the surface layer. Over time, Ch had improved the structure of the subsurface soil layers with the lowest degree of compaction (≈88%) and highest air capacity (≈0.140 cm3 cm−3), while the measured indices were poor in NTC. Irrespective of tillage, the surface layer showed resilience during the years without soil disturbance with low degree of compaction, increased water retention, and air capacity. NT could be a good soil management option for sugarcane production, while mechanical chiseling is advocated for ameliorating compacted soils. [ABSTRACT FROM AUTHOR]

Published

2024

46. Soil tillage managements and planting systems to improve rice yield and vertisols properties in rainfed agroecosystem.

Author

Suriadi, Ahmad, Jauhari, Sodiq, Hadiawati, Lia, Nazam, Moh., and Sukmawati

Subjects

*SOIL management, *TILLAGE, *NO-tillage, *VERTISOLS, *RICE, *SOIL degradation, *IRRIGATION water

Abstract

Improper soil tillage management often leads to soil degradation that eventually decreases rice productivity. The aim of the research was to identify the best soil tillage management and planting systems to improve rice productivity and vertisol properties in a rainfed agroecosystem. The field experiment was laid out as a split plot design with two planting systems of direct seeding (DS) and transplanted seeding (TS) treatments as the main plot and three soil managements treatment, i.e., no tillage (NT), minimum tillage (MT), and conventional tillage (CT) as sub-plots and four replications. The results showed that vertisol properties such as bulk density, porosity, and permeability tend to be better in NT and MT than in CT, although these were not significantly different. However, rice plants were harvested about 10 days earlier in the DS treatment than in the TS treatment without significantly reducing yield. The DS technology has been able to streamline the planting time earlier than the usual method or the farmer's method (TS) with NT or MT soil management. The agronomic parameters of rice plants did not significantly differ either in combination treatments or in single treatment except for dry biomass weight. The highest dry biomass was obtained in the conventional tillage treatment and was significantly different from the treatment with no tillage but not significantly different from the minimum tillage. The cultivation of no tillage combined with direct seed planting was able to produce the same rice yield as transplanted seed with conventional tillage. The existence of earlier planting time will provide an opportunity to utilize irrigation water resources more efficiently for the next season of planting time. [ABSTRACT FROM AUTHOR]

Published

2024

47. Maintaining soil properties and increasing cabbage yields through minimal tillage and legume cover crops.

Author

Prathama, Mathias, Rosliani, Rini, Handayani, Tri, Yufdy, M. Prama, Sulastrini, Ineu, and Musaddad, Darkam

Subjects

*COVER crops, *LEGUME farming, *TILLAGE, *CABBAGE, *CROP management, *GREEN bean, *AGRICULTURE, *SOIL management

Abstract

Continuous cultivation of vegetable crops such as cabbage throughout the year causes a decrease in crop and soil productivity. There it is necessary to develop agricultural practices that can maintain sustainable production while reducing land degradation. The aim of this experiment was to study soil fertility and cabbage yields influenced by tillage methods and types of legumes as cover crops. The research was conducted in Pangalengan highlands, West Java, Indonesia. A split-plot design with four replications was applied. The main plot consisted of two tillage methods, namely minimum tillage (strip) and conventional tillage. The subplot consisted of legumes cultivated as cover crops on cabbage beds, namely string beans, red beans, peanuts, and plastic mulch as controls. The results indicated that the application of minimum tillage was not significantly different from conventional tillage in the chemical and physical properties of the soil, growth, and yield of cabbage. Therefore, minimal tillage can be used for the cultivation of cabbage in the highlands. Meanwhile, legume cover crops produced higher residual nutrients (organic C and soil P), soil microbial population, growth, and yield of cabbage compared to plastic mulch application, although the physical properties of the soil were not significantly different. This indicated that legumes planted among cabbage cultivations can increase soil fertility and cabbage yields. Then minimum tillage and cultivation of legumes as intercropping crops can be proposed as efficient methods of crop and soil management to maintain crop and land productivity in cabbage cultivation in the tropic highlands. [ABSTRACT FROM AUTHOR]

Published

2024

48. Tillage with Crop Residue Returning Management Increases Soil Microbial Biomass Turnover in the Double-Cropping Rice Fields of Southern China.

Author

Tang, Haiming, Li, Chao, Shi, Lihong, Wen, Li, Li, Weiyan, Cheng, Kaikai, and Xiao, Xiaoping

Subjects

*TILLAGE, *CROP residues, *DOUBLE cropping, *PADDY fields, *SOIL management, *BIOMASS

Abstract

The variety of soil microbial biomass carbon (SMBC), soil microbial biomass nitrogen (SMBN) content, and the flux turnover rate of SMBC and SMBN for 0–10 cm and 10–20 cm layers in a paddy field in southern China with different tillage practices were studied. The tillage experiment included conventional tillage and crop residue returning (CT), rotary tillage and crop residue returning (RT), no–tillage and crop residue returning (NT), and rotary tillage with all crop residues removed from the paddy field as a control (RTO). The result showed that the SMBC and SMBN contents at 0–10 cm and 10–20 cm layers in the paddy field with CT, RT, and NT treatments were significantly increased. This result indicates that the flux turnover rate of SMBC and SMBN for 0–10 cm and 10–20 cm layers in the paddy field with CT treatment were increased by 65.49%, 39.61%, and 114.91%, 119.35%, compared with the RTO treatment, respectively. SMBC and SMBN contents and the flux turnover rate of SMBC and SMBN for the 0–10 cm layer were higher than that of the 10–20 cm layer in paddy fields under the same tillage condition. Therefore, applying rotary tillage or conventional tillage and crop residue returning produced beneficial management for increasing soil microbial biomass content and its turnover under a double–cropping rice system in southern China. [ABSTRACT FROM AUTHOR]

Published

2024

49. Effects of different maize residue managements on soil organic nitrogen cycling in different soil layers in northeast China.

Author

Su, Hongzhi, Zhang, Yulan, Wu, Guohui, Chen, Zhenhua, Jiang, Nan, Qiu, Weiwen, and Chen, Lijun

Subjects

*SOIL management, *NITROGEN cycle, *SOIL depth, *PLOWING (Tillage), *NITROGEN in soils, *CORN, *TILLAGE

Abstract

A field experiment was conducted in northeast China to examine the response of nitrogen cycling enzymes, that is, protease, N‐acetyl‐β‐D‐glucosaminidase (NAG), amidase, urease, and peptidase, as well soil organic nitrogen (SON) fractions and their relationships to RT (no maize residue application), NT (no tillage with maize residues placed on the surface), TT (plow maize residues into the soil at 0–35 cm depth in the first year, 0–20 cm in the second year, and 0–15 cm in the third year), and PT (plow maize residues into soil at 0–35 cm depth). The results have shown that NT significantly enhanced the activities of protease and NAG at 0–10 cm soil depth in comparison with other treatments. NT and TT significantly enhanced the activities of protease compared to RT and PT at 10–20 cm soil depth. TT significantly enhanced the activities of NAG in comparison with RT at 10–20 cm soil depth. TT and PT significantly enhanced the activities of NAG and peptidase compared to RT and NT at 20–35 cm soil depth. PT significantly increased the activities of protease in comparison with RT at 20–35 cm soil depth. NT, TT, and PT significantly enhanced the activities of peptidase compared to RT at 10–20 cm soil depth. NT significantly increased the concentration of hydrolyzable NH4+‐N$$ {\mathrm{NH}}_4^{+}\hbox{-} \mathrm{N} $$ in comparison with other treatments at 0–10 cm soil depth. PT significantly enhanced the concentration of hydrolyzable NH4+‐N$$ {\mathrm{NH}}_4^{+}\hbox{-} \mathrm{N} $$ and amino acid N compared to other treatments at 20–35 cm soil depth. Redundancy analysis showed that protease played a crucial role in the cycling of SON under RT and NT, whereas peptidase and NAG played a significant role in the cycling of SON under TT and PT, respectively. This study provided a comprehensive understanding of crop residue return methods for regulating soil N cycling. [ABSTRACT FROM AUTHOR]

Published

2024

50. Responses of soil microbial metabolic limitations to erosion under contrasting soil types and management practices.

Author

Rong, Guohua, Zhu, Hansong, Jiao, Jintao, Gong, Lin, Ni, Erdong, Wu, Hongyu, Ni, Huaqian, Qiu, Quan, Wei, Xiaorong, and Li, Haiqiang

Subjects

*SOIL management, *SOIL classification, *EROSION, *SOILS, *MICROBIAL metabolism

Abstract

Soil microbial metabolism plays an important role in supporting soil services and functionalities but is usually restricted by the availability of soil nutrients. Although soil microbial metabolism limitation (SMML) has been widely addressed with regard to various driving factors, its response to erosion has not been examined but is urgently needed given the important influence of erosion on global environments. To understand how erosion affects SMML and whether erosion's effect varies with tillage practices and soil types, we conducted a simulated erosion experiment to compare eroded and noneroded plots with contrasting soil types (Mollisol vs. loess soils) and managements (conventional tillage versus no‐tillage in plots with crops versus without crops). We measured soil extracellular enzymatic activities and quantified SMML with extracellular enzymatic stoichiometry models. In both soils, the microbes were limited by carbon (C) and phosphorus (P), but not by nitrogen, and microbial C and P limitations were greater in Mollisol than loess soils. For the Mollisol, erosion significantly increased the relative C limitation, whereas the presence of crops eliminated this increase. For the loess soils, erosion enhanced the relative C limitation regardless of crop presence and tillage management. Erosion consistently increased microbial P limitation in plots with crops, with greater effects under no‐tillage (+2.9%) compared to conventional tillage (+0.7%) conditions regardless of soil type (p < 0.05). In plots without crops, microbial P limitation was increased by erosion under no‐tillage (+2.1%) but was decreased under conventional tillage (−5.6%) (p < 0.05). Additionally, conventional tillage exacerbated microbial C limitation but alleviated microbial P limitation. These results indicated that erosion shifted microbial C and P limitations depending on soil type, tillage practice and the presence of plants, highlighting the importance of considering all these factors when assessing soil microbial metabolic limitation at various spatial scales. [ABSTRACT FROM AUTHOR]

Published

2024