Your search keyword '"conservation tillage"' showing total 5,957 results

1. Evaluating the Efficacy of Best Management Practices in Mitigating Sediment Yield and Nutrient Losses in the Lower Sutlej River Basin, India.

Author

Sharma, Navneet, Yousuf, Abrar, and Kaushal, Arun

Subjects

WATER management, SUSTAINABLE agriculture, FERTILIZER application, CONSERVATION tillage, RIPARIAN areas, WATERSHEDS

Abstract

Soil erosion is one of the most serious environmental concerns as it threatens the sustainable agriculture and poses a grave threat to global food security. It is important to adopt the appropriate soil conservation measures to reduce the erosion hazard. In the present study, SWAT model has been applied to study the impact of various best management practices (BMPs) on sediment yield and nutrient losses from a Lower Sutlej River Basin, India. The impact of agricultural and structural BMPs was assessed both individually and in combinations to evaluate the best possible combination of BMPs. Three scenarios, viz., CT1-BMP-1 + CF-BMP-2 + CD-BMP-5 + Fertilizer level 1 (Scenario-1), CT1-BMP-1 + CF-BMP-2 + CB-BMP-3 + CD-BMP-5 + CT2-BMP-8 + Fertilizer level 2 (Scenario 2) and CT1-BMP-1 + CF-BMP-2 + CB-BMP-3 + BT-BMP-4 + CD-BMP-5 + GSS-BMP-6 + SBSS-BMP-7 + CT2-BMP-8 + Fertilizer level 3 (Scenario 3) were developed to study their impact on sediment yield and nutrient losses. The average annual sediment yield from watersheds ranges from 3.08 to 21.63 ton/ha/yr for the base scenario (without BMPs), 1.97 to 13.94 ton/ha/yr in scenario 1, 1.66 to 10.77 ton/ha/yr in scenario 2, and 1.04 to 7.78 ton/ha/yr in scenario 3. At the watershed level, the greatest decrease in sediment yield was obtained from check dam (28.72%), followed by bench terracing (25.62%), grade stabilization structures (22.74%), contour bunding (20.88%), stream bank stabilization structures (10.02%), contour trenching (8.99%), conservation tillage (6.66%) and contour farming (4.54%). The use of structural BMPs at the watershed level reduced sediment yields more effectively than agricultural BMPs. The implementation of all the potential BMPs in Scenario 3 minimized sediment yields to the extent of 66.25%. Model simulation demonstrated that a 30% reduction in fertilizer application under fertilizer scenario 3 resulted in the highest reduction in total nitrogen (24.04%), nitrate nitrogen (8.97%), and total phosphorus (11.75%). The study findings may be useful for promoting sustainable land and water resource management at the river basin level. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of Lime Source, Fineness and Granulation on Soil Permeation with Contrasting Textures under Simulated Mediterranean Climate Rainfall Conditions.

Author

du Toit, Dawid J.J., Swanepoel, Pieter A., and Hardie, Ailsa G.

Subjects

*LIMING of soils, *MEDITERRANEAN climate, *SOIL acidity, *CONSERVATION tillage, *SOIL permeability, *LIME (Minerals)

Abstract

Granulated micro-fine limes have recently been introduced as liming materials which are purportedly more effective than conventional agricultural limes in terms of rapidly correcting subsoil acidity in no-tillage systems. Hydrated limes are known to react more quickly in soils than calcitic limes, yet their soil permeability has not been evaluated under Mediterranean climate growing conditions. Therefore, the aim of this controlled study was to compare soil permeation and pH neutralization of different liming materials (hydrated lime, calcitic agricultural lime, micro-fine lime and molasses-granulated micro-fine lime) in two contrasting (sand and sandy loam) acid (pHKCl < 4.1) topsoils under simulated Mediterranean climate conditions. Limes were surface applied to 40 cm soil columns and then rainfall (350 mm) was simulated. Subsequently, soil chemical properties (pH, exchangeable cations, available P) were measured in 5 cm increments. Application of all liming materials increased soil pH 1–2 pH units above target pHKCl of 5.5 in the top 5 cm of both soils. Only hydrated lime was able to increase soil pHKCl (5.7–6.8) below 5 cm up to a depth of 15 cm on the sand soil. Hydrated lime, however, resulted in substantial over-liming (pHKCl 7.3–8.7) of the top 5 cm of soil compared to the other materials. Granulated micro-fine lime reacted more slowly than the agricultural limes and is therefore not a suitable quick-fix for subsoil acidity in rain-fed no-till systems under Mediterranean climate rainfall conditions. Whereas hydrated lime showed potential in ameliorating subsoil acidity in the sand soil within one season of rainfall. [ABSTRACT FROM AUTHOR]

Published

2024

3. Managing climate change impacts on crops: The influence of soil tillage on a triticale crop under water stress conditions.

Author

Madejón, Paula, Fernández‐Boy, Elena, Madejón, Engracia, Morales‐Salmerón, Laura, and Domínguez, María Teresa

Subjects

*AGRICULTURAL conservation, *AGRICULTURE, *FUNGAL colonies, *VESICULAR-arbuscular mycorrhizas, *PLANT ecophysiology, *CONSERVATION tillage

Abstract

Water limitations for agriculture will likely become crucial in the next decades in some regions such as the Mediterranean basin with the current climate change projections. In this context, recent evidence suggests that the application of conservation agriculture, which reduces the frequency and intensity of soil tillage, could confer a higher stability of agricultural systems against climate variability. However, not many experiments have addressed the interaction between tillage type and the resistance to drought in rainfed crops. In this work, we evaluated the resistance to drought of triticale (Triticale hexaploide L.) crops managed with different tillage systems: traditional tillage (TT), reduced tillage (RT) and no tillage (NT). A rainfall exclusion experiment was carried out in a typical wheat/legume Mediterranean rotation in SW Spain, in a long‐term experiment established in 2008 comparing the three tillage systems. Grain yield and different variables related to plant ecophysiology, root development, biomass allocation and colonisation by arbuscular mycorrhizal fungi (AMF) were evaluated over one crop cycle. Tillage type had a significant influence on soil water storage (SWS), such that soils under NT had, on average, a 16% greater SWS than soils under RT or TT. Grain yield was significantly reduced by rainfall exclusion, in particular in the TT, where drought reduced grain yield by 31%. Gas exchange data also showed that plants in the TT system were more sensitive to drought, such that maximum photosynthesis rates were reduced by 25% because of rainfall exclusion in this tillage system. Drought had a negative impact on root biomass across the three tillage systems, especially in the RT, where a reduction in the root:shoot ratio was observed. The effect of tillage on mycorrhizal colonisation was more evident than the effect of drought; in general, conservation tillage systems (RT and NT) tended to have higher values for all AMF traits compared to the TT. In summary, the NT system tended to exhibit more favourable performance in terms of soil water retention, grain yield stability under drought conditions and mycorrhizal symbiosis, which suggests enhanced resource use efficiency in this system. [ABSTRACT FROM AUTHOR]

Published

2024

4. Optimization of Operating Parameters for Straw Returning Machine Based on Vibration Characteristic Analysis.

Author

Gao, Yuanyuan, Hu, Yongyue, Yang, Yifei, Feng, Kangyao, Han, Xing, Li, Peiying, Zhu, Yongyun, and Song, Qi

Subjects

*VIBRATION (Mechanics), *WHEAT straw, *FIELD research, *SURFACE analysis, *STRAW

Abstract

For the mechanized technical mode of total wheat straw returning to field, there are problems such as large vibration during the operation of the straw returning machine that, in turn, affect the effect of stubble breaking. This study took the Tongtian 1-JHY-220 straw returning machine as the research object to conduct field experiments, with wheat stubble height, forward velocity, and PTO speed as experimental parameters. And the vibration characteristics at different positions of the machine and the final stubble breaking rate were used as evaluation indicators. Combined with the orthogonal experiment and response surface analysis method, this article analyzes and discusses the influence of various parameters on vibration characteristics and operational effectiveness. The results show that PTO speed and wheat stubble height were the main factors affecting the vibration and operation quality of the straw returning machine. Low PTO speed and high stubble height can improve the stubble breaking rate of the straw returning machine and reduce its operation vibration. Furthermore, the multi-objective optimization results show that when the forward velocity in the range of 8.5–9 km/h, the PTO speed is 540 r/min, and the stubble height is in the range of 200–250 mm, the stubble breaking rate of the straw returning machine is greater than 86%. At this time, the total vibration of the straw returning machine and tractor rear axle is relatively small. This study can lay a foundation for further studying the impact of the vibration of the straw returning machine on the stubble breaking effect and provide a reference for the preparation of high-quality seedbed under conservation tillage. [ABSTRACT FROM AUTHOR]

Published

2024

5. Long-Term Effects of Nitrogen and Tillage on Yields and Nitrogen Use Efficiency in Irrigated Corn.

Author

Delgado, Jorge A., D'Adamo, Robert E., Villacis, Alexis H., Halvorson, Ardell D., Stewart, Catherine E., Floyd, Bradley A., Del Grosso, Stephen J., Manter, Daniel K., and Alwang, Jeffrey

Subjects

*CROP management, *CONSERVATION tillage, *CROP yields, *CORN, *CROPPING systems, *NO-tillage, *TILLAGE

Abstract

By tonnage, corn (Zea mays L.) is the #1 crop produced globally, and recent research has suggested that no-till (NT) systems can lead to reduced yields of this important crop. Additionally, there is a lack of long-term data about the effects of tillage and N management on cropping systems. Corn is the most nitrogen (N)-fertilized crop in the USA, and N losses to the environment contribute to significant impacts on air and water quality. We conducted long-term studies on conventional tillage (CT) and conservation tillage systems, such as strip tillage (ST) and NT, under different N rates. We found that immediately after conversion to NT, yields from NT were significantly lower than yields from CT (p < 0.1), but after five years of NT, the NT yields were 1.5% higher than the CT yields (p < 0.1). Initially, the NT yields were lower than the ST (p < 0.01), but after seven years of NT, the NT yields were comparable to ST grain yields. Although the total aboveground N uptake with NT immediately after conversion to NT was lower than with CT and ST, these differences were not significant in the long run. The nitrogen use efficiency (NUE) with NT increased over time. The present work highlights the importance of long-term research for determining the cumulative impacts of best management practices such as NT. We found that NT becomes a more viable practice after five or seven years of implementation, demonstrating the high importance of long-term research. [ABSTRACT FROM AUTHOR]

Published

2024

6. Soil Health and Crop Management in Conservation Agriculture.

Author

Thapa, Sushil, Shah, Ghulam Abbas, and Xue, Qingwu

Subjects

*AGRICULTURAL conservation, *SUSTAINABILITY, *SUSTAINABLE agriculture, *ARABLE land, *CLIMATE change adaptation, *COVER crops, *TILLAGE, *CONSERVATION tillage

Abstract

The document "Soil Health and Crop Management in Conservation Agriculture" discusses the importance of conservation agriculture in addressing global food production challenges while maintaining soil health. Conservation practices like minimum tillage and crop diversification have shown to enhance soil aggregation, biological activity, water retention, and nutrient cycling. Various studies highlighted in the document demonstrate the positive impact of practices such as biochar application, cover crops, and advanced tillage methods on soil fertility, crop yield, and environmental sustainability. Overall, the research emphasizes the potential of conservation agriculture to create resilient and productive farming systems for a sustainable food future. [Extracted from the article]

Published

2024

7. Straw Return or No Tillage? Comprehensive Meta-Analysis Based on Soil Organic Carbon Contents, Carbon Emissions, and Crop Yields in China.

Author

Yan, Yanfei, Li, Haoyu, Zhang, Min, Liu, Xiwei, Zhang, Lingxin, Wang, Yaokuo, Yang, Min, and Cai, Ruiguo

Subjects

*CARBON in soils, *CROP yields, *CARBON emissions, *TILLAGE, *LOW temperatures, *CONSERVATION tillage

Abstract

Conservation tillage methods, including straw return (SR) and no tillage (NT), are widely used to improve the soil organic carbon (SOC) content and crop yield. However, applying SR or NT separately has become a common practice for farmers producing different crops or those in different regions. Evaluating the effects of SR or NT on the SOC content, carbon emissions, and crop yield are important for guiding the correct application of conservation tillage and promoting sustainable agricultural development. Therefore, we conducted a meta-analysis based on 1014 sets of data obtained in China to assess the effects of SR and NT on the SOC content, carbon emissions, and crop yield. Compared with no straw return, SR increased the SOC content and crop yield by 10% and 8.6%, respectively, but with no significant impact on carbon emissions. Compared with conventional tillage, NT increased the SOC content by 2.9% and reduced the carbon emissions and crop yield by 18% and 3.9%, respectively. We also found that SR combined with NT had an additive effect, where the combination improved SOC more than applying SR or NT alone. If applying SR or NT alone, the specific climatic conditions, soil characteristics, and field management strategies need to be considered to maximize SOC. In particular, SR should be used in limited hydrothermal conditions (low temperature or low precipitation) and areas where rice–wheat rotation is implemented. NT can be used under any climate conditions, but it can effectively increase the SOC content in continuous wheat cropping areas. [ABSTRACT FROM AUTHOR]

Published

2024

8. Impact of Conservation Tillage on Growth, Symbiosis, Productivity, Quality, Profitability, and Soil Properties in Soybean: A Review.

Author

Virk, Harpreet Kaur, Singh, Guriqbal, and Kaur, Gurleen

Subjects

*AGRICULTURAL technology, *NITROGEN fixation, *CROP residues, *NO-tillage, *AGRICULTURAL productivity, *CONSERVATION tillage, *TILLAGE

Abstract

Conventional tillage over the long term in more intensive-cropping systems is not sustainable as it enhances soil degradation, soil moisture loss, soil erosion, and cost of cultivation and disturbs beneficial micro-organisms. Retaining crop residues as mulch has been recognized as a desirable management practice for conserving soil moisture and lowering soil temperature, which ultimately helps in improving seed emergence. However, no-tillage or reduced tillage with crop residue produced better or non-significant differences in the growth and yield attributes and crop yield than that obtained under conventional tillage. However, zero or reduced tillage combined with crop residue improves biological nitrogen fixation, nitrogenase activity, symbiotic parameters and the uptake of nitrogen, phosphorus, and potassium. Continuous adoption of conservation tillage will have a positive effect on soil's physical, chemical, and biological properties and may also be better for the sustainability of crop production. The novelty of the study is that it examines the integrated effect of conservation tillage and residue retention through mulching on the crop emergence, symbiosis and quality of soybean along with growth, productivity, and profitability of soybean, nutrient uptake by the crop and soil properties together as sustainable agricultural technology. [ABSTRACT FROM AUTHOR]

Published

2024

9. 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

10. Soil Organic Carbon Research and Hotspot Analysis Based on Web of Science: A Bibliometric Analysis in CiteSpace.

Author

Fan, Manman, Yang, Wenyan, Wu, Jingtao, Zhang, Huan, Ye, Zhengwei, and Shaukat, Muhammad

Subjects

CARBON in soils, BIBLIOMETRICS, CONSERVATION tillage, CARBON sequestration, SUSTAINABLE agriculture

Abstract

Soil carbon sequestration is an important process of the terrestrial carbon cycle, and even slight changes in soil carbon will trigger drastic variations in the global carbon pool. In this study, we used the CiteSpace software to analyze the development of research on soil organic carbon (SOC) and its current status from various perspectives, with the goal of revealing research hotspots and trends of SOC. A total of 3909 studies published between 2014 and 2023 were included in the analysis. Results show that China and the USA lead with a significant number of publications on SOC, which underscores their considerable interest in the subject. France and the USA exhibit a very high international influence in this field, with their intermediary centrality reaching up to 0.3 and 0.21, respectively. Among institutions, the Chinese Academy of Sciences is the largest contributor in terms of the number of publications, with a high centrality of 0.09, indicating this institution has built close collaboration and significant influence in this field. Kuzyakov Yakov achieved the highest publication record, with Lal Rattan sharing the second position. The hotspots in SOC can be summarized into the following aspects: conservation tillage, carbon sequestration, microbial biomass, and driving forces. The research focus has gradually shifted from macroscopic trends to explanations based on micro-level biological dynamics. Driving forces such as soil type, land use, and environmental conditions have a significant impact on the quantity, turnover, and spatiotemporal distribution of SOC. We highlighted that more attention should be paid to the mechanism of SOC transformation and stabilization, which is essential for developing more precise models of carbon cycling in the soil and for formulating effective strategies to maintain sustainable agriculture and mitigate climate change. [ABSTRACT FROM AUTHOR]

Published

2024

11. Review of Root-Stubble Characteristics and Root-Stubble Crushing and Clearing Technologies for Conservation Tillage.

Author

Feng, Xin, Yao, Jiayue, Gao, Yunpeng, Zeng, Longchi, Wang, Lijun, Wang, Bo, and Yang, Zhilei

Abstract

Conservation tillage (CT) is an agricultural technology for sustainable soil use, and clearing the root-stubble remaining in the seedbed and nursery bed is a core aspect of CT. In this paper, the characteristics and the testing methods of root-stubble and their growth environments were reviewed, which could provide a reference for the setting of parameters in numerical simulations and the design of stubble treatment devices. The methods for the restoration of the environment in CT are described. Moreover, the root-stubble crushing and clearing technologies and the methods for the evaluation of device performance are summarized. Furthermore, the prospects for the physical properties of the root-stubble soil, the reduction of soil adhesion when a cutter crushes the roots, the tracking of the long-term effects of different methods on soil, intelligent devices for the crushing of root-stubble, and challenges and strategies regarding the application of new root-stubble crushing and clearing technologies are discussed. This paper provides a reference for the development of devices for the crushing of root-stubble from the perspective of CT. [ABSTRACT FROM AUTHOR]

Published

2024

12. Analyzing the Trade-Offs between Soil Health Enhancement, Carbon Sequestration, and Productivity in Central India's Black Soil through Conservation Agriculture.

Author

Kumbhar, Chetna, Kharche, Vilas, Ramteke, Pratik, Jadhao, Shyam, Bhoyar, Sanjay, Konde, Nitin, Mali, Dnyaneshwar, Sonune, Bhagwan, El-Hendawy, Salah, and Mattar, Mohamed A.

Abstract

The impact of conservation tillage (CST) practices on soil properties, carbon sequestration and yield sustainability over short, medium, and long durations remain insufficiently understood, especially in semiarid Central India. Therefore, our objective was to investigate the effects and optimal duration of CST adoption for enhancing soil properties, carbon sequestration, and sustainable yields. We conducted a study in farmers' fields in the Akola district of Central India, where CST had been practised for 4 to 15 years, within a soybean + pigeon pea–chickpea cropping sequence. Our findings revealed significant (p < 0.05) improvements in soil physical properties with short-term CST practices (4 to 6 years), alongside increasing availability of nitrogen and phosphorus, with longer durations of CST implementation (10 to 15 years). The lowest soil organic carbon (SOC) was observed in conventional tillage (CT_y), while all CST practices increased SOC content over CT_y, ranging from 22.2 to 38.4%. Further, experimental soil dominated passive C pools (Cfrac3 + Cfrac4). Consequently, long-term CST practices facilitated positive C sequestration rates, contrasting with negative or minimal sequestration observed in CT_y and short-term CST treatments. However, compared to CST, CT_y demonstrated higher soybean equivalent yields and comparable chickpea equivalent yields mainly due to delayed germinations induced by lower soil temperatures in CST plots. We conclude that integrating site-specific characteristics, management practices, and regional climate conditions into conservation agriculture frameworks maximizes efficacy and ensures sustainable productivity. These findings help optimize agricultural practices considering potential yield losses or minimal changes despite implementing CST. [ABSTRACT FROM AUTHOR]

Published

2024

13. Monitoring the Spatial Distribution of Cover Crops and Tillage Practices Using Machine Learning and Environmental Drivers across Eastern South Dakota.

Author

Jain, Khushboo, John, Ranjeet, Torbick, Nathan, Kolluru, Venkatesh, Saraf, Sakshi, Chandel, Abhinav, Henebry, Geoffrey M., and Jarchow, Meghann

Subjects

AGRICULTURAL conservation, ENVIRONMENTAL indicators, CONSERVATION tillage, AGRICULTURE, SOYBEAN, COVER crops

Abstract

The adoption of conservation agriculture methods, such as conservation tillage and cover cropping, is a viable alternative to conventional farming practices for improving soil health and reducing soil carbon losses. Despite their significance in mitigating climate change, there are very few studies that have assessed the overall spatial distribution of cover crops and tillage practices based on the farm's pedoclimatic and topographic characteristics. Hence, the primary objective of this study was to use multiple satellite-derived indices and environmental drivers to infer the level of tillage intensity and identify the presence of cover crops in eastern South Dakota (SD). We used a machine learning classifier trained with in situ field samples and environmental drivers acquired from different remote sensing datasets for 2022 and 2023 to map the conservation agriculture practices. Our classification accuracies (>80%) indicate that the employed satellite spectral indices and environmental variables could successfully detect the presence of cover crops and the tillage intensity in the study region. Our analysis revealed that 4% of the corn (Zea mays) and soybean (Glycine max) fields in eastern SD had a cover crop during either the fall of 2022 or the spring of 2023. We also found that environmental factors, specifically seasonal precipitation, growing degree days, and surface texture, significantly impacted the use of conservation practices. The methods developed through this research may provide a viable means for tracking and documenting farmers' agricultural management techniques. Our study contributes to developing a measurement, reporting, and verification (MRV) solution that could help used to monitor various climate-smart agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

14. Conservation Agricultural Practices Increase Soil Fungal Diversity and Network Complexity in a 13-Year-Duration Conservation Agriculture System in the Loess Plateau of China.

Author

Wang, Yajie, Zheng, Rongchun, Dong, Wanqing, Gao, Ping, and Duan, Tingyu

Subjects

AGRICULTURAL conservation, CONSERVATION tillage, AGRICULTURE, NUCLEOTIDE sequencing, SOIL fungi, FUNGAL communities

Abstract

Agricultural practices can affect the diversity and community structure of soil fungi. This study investigates the impact of long-term agricultural practices on soil fungal diversity in the Loess Plateau of northwestern China. Different tillage practices have been implemented for 13 years, and their impact on soil fungi is assessed using high-throughput Illumina Sequencing. This study found a total of 2071 fungal Amplicon Sequence Variants (ASVs), and these were assigned to 25 different phyla, 372 families, and 496 genera. The fungal communities were dominated by Ascomycota (52.1%), followed by Zygomycota (14.3%) and Basidiomycota (9.0%). In general, the soil exhibited higher fungal community abundance, richness, and diversity in winter than in summer. Notably, no-tillage or stubble retention resulted in greater diversity than conventional tillage, with no-tillage combined with stubble retention resulting in the highest fungal richness, diversity, and network complexity in both summer and winter. These findings indicate that no-tillage with stubble retention is beneficial for biological soil components, which favors the establishment of abundant and diverse soil fungal communities in the Loess Plateau of China. The present study expands the knowledge of fungal communities in agro-ecosystems and the long-term ecosystem benefits of tillage practices. [ABSTRACT FROM AUTHOR]

Published

2024

15. The Quantification of the Ecosystem Services of Forming Ridges in No-Tillage Farming in the Purple Soil Region of China: A Meta-Analysis.

Author

Jia, Lizhi

Subjects

SOIL moisture, CONSERVATION tillage, RAPESEED, AGRICULTURE, ECOSYSTEM services, TILLAGE, SWEET potatoes

Abstract

Forming ridges in no-tillage farming (FRNF) is an important conservation tillage practice in the purple soil region of China. Whether FRNF will enhance ecosystem services remains unclear. There is a lack of a systematic quantitative research about the effect of FRNF on ecosystem services. We collected 611 data entries from 21 previous publications to quantitatively evaluate the effects of FRNF on runoff and sediment loss, soil physicochemical properties and biomass. The results showed that compared with conventional tillage, (1) FRNF reduced runoff and sediment loss by 49% and 73%, respectively, due to the blocking effect of the ridge-ditch structure; (2) FRNF increased the concentrations of soil organic carbon, total nitrogen, available nitrogen, available phosphorus and available potassium by 15%, 14%, 30%, 58% and 17%, respectively; (3) FRNF decreased soil bulk density on the ridges by 11% and increased soil moisture content in the furrows by 28%, while it had insignificant effects on soil bulk density in the furrows and soil moisture content on the ridges; and (4) FRNF increased aboveground and belowground biomass (maize, oilseed rape, potato, sweet potato and wheat) by 23% and 63%, respectively. Overall, these results highlighted the importance of FRNF in regulating soil erosion, physicochemical properties and biomasses in the purple soil region of China. The implementation of FRNF in this region could significantly improve the ecosystem services in agro-ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

16. Critical assessment of furrow openers and operational parameters for optimum performance under conservation tillage.

Author

Madhusudan, B. S., Kushwaha, H. L., Kumar, Adarsh, Parray, Roaf Ahmad, Swain, Sidhartha Sekhar, Chowdhury, Manojit, Nag, Ramineni Harsha, Asha, K. R., Rathod, Sunil Kumar, Kumar, Pradeep, Anand, Rohit, Al-Ansari, Nadhir, Dewidar, Ahmed Z., and Mattar, Mohamed A.

Subjects

*AGRICULTURAL conservation, *SUSTAINABLE agriculture, *CONSERVATION tillage, *FIELD crops, *STRAW

Abstract

Conservation Agriculture (CA) is an innovative approach that promotes sustainable farming while enhancing soil health. However, residue management challenges often hinder its adoption, causing farmers to burn crop leftovers in fields. This study aimed to evaluate the effectiveness of various furrow openers under simulated soil bin conditions. Three types of furrow openers were examined: single disk (SD), Inverted T-type furrow opener with a plain rolling coulter (ITRC), and double disc (DD) furrow opener. Tests were conducted at different forward speeds (1.5, 2, and 2.5 km h−1) and with three straw densities (1, 2, and 3 t ha−1) at a consistent working depth of 5 cm. Draft measurements were obtained using load cells connected to an Arduino-based data-logging system. Results indicated that draft requirements increased with forward speed and straw density, while straw-cutting efficiency decreased with these factors. Average draft values for SD, ITRC, and DD were 290.3 N, 420 N, and 368.5 N, respectively, and straw-cutting efficiencies were 53.62%, 59.47%, and 74.89%, respectively. The DD furrow opener showed the highest straw-cutting efficiency (81.36%) at a working speed of 1.5 km h−1 and a straw density of 1 t ha−1, demonstrating optimal performance compared to other furrow openers. [ABSTRACT FROM AUTHOR]

Published

2024

17. Impact of Crop Residue, Nutrients, and Soil Moisture on Methane Emissions from Soil under Long-Term Conservation Tillage.

Author

Choudhary, Rajesh, Lenka, Sangeeta, Yadav, Dinesh Kumar, Lenka, Narendra Kumar, Kanwar, Rameshwar S., Sarkar, Abhijit, Saha, Madhumonti, Singh, Dharmendra, and Adhikari, Tapan

Subjects

*GREENHOUSE gases, *GREENHOUSE gas mitigation, *CROP residues, *SOIL moisture, *AGRICULTURAL productivity, *CONSERVATION tillage

Abstract

Greenhouse gas emissions from agricultural production systems are a major area of concern in mitigating climate change. Therefore, a study was conducted to investigate the effects of crop residue, nutrient management, and soil moisture on methane (CH4) emissions from maize, rice, soybean, and wheat production systems. In this study, incubation experiments were conducted with four residue types (maize, rice, soybean, wheat), seven nutrient management treatments {N0P0K0 (no nutrients), N0PK, N100PK, N150PK, N100PK + manure@ 5 Mg ha−1, N100PK + biochar@ 5 Mg ha−1, N150PK+ biochar@ 5 Mg ha−1}, and two soil moisture levels (80% FC, and 60% FC). The results of this study indicated that interactive effects of residue type, nutrient management, and soil moisture significantly affected methane (CH4) fluxes. After 87 days of incubation, the treatment receiving rice residue with N100PK at 60% FC had the highest cumulative CH4 mitigation of −19.4 µg C kg−1 soil, and the highest emission of CH4 was observed in wheat residue application with N0PK at 80% FC (+12.93 µg C kg−1 soil). Nutrient management had mixed effects on CH4 emissions across residue and soil moisture levels in the following order: N150PK > N0PK > N150PK + biochar > N0P0K0 > N100PK + manure > N100PK + biochar > N100PK. Decreasing soil moisture from 80% FC to 60% FC reduced methane emissions across all residue types and nutrient treatments. Wheat and maize residues exhibited the highest carbon mineralization rates, followed by rice and soybean residues. Nutrient inputs generally decreased residue carbon mineralization. The regression analysis indicated that soil moisture and residue C mineralization were the two dominant predictor variables that estimated 31% of soil methane fluxes in Vertisols. The results of this study show the complexity of methane dynamics and emphasize the importance of integrated crop, nutrient, and soil moisture (irrigation) management strategies that need to be developed to minimize methane emissions from agricultural production systems to mitigate climate change. [ABSTRACT FROM AUTHOR]

Published

2024

18. Coastal Salinity Management and Cropping System Intensification through Conservation Agriculture in the Ganges Delta.

Author

Sarangi, Sukanta Kumar, Mainuddin, Mohammed, Raut, Shishir, Mandal, Uttam Kumar, and Mahanta, Kshirendra Kumar

Subjects

*AGRICULTURAL conservation, *DOUBLE cropping, *CROPPING systems, *SOIL salinity, *CROP rotation, *CONSERVATION tillage, *TILLAGE

Abstract

Soil salinity is the major constraint for cropping system intensification in the coastal region of the Ganges Delta. Salts build up on the soil surface, as well as in the crop root zone, due to the capillary rise in underground brackish water, hampering the growth and development of crops and resulting in mortality and low yields. We studied, for three years (2020–2021 to 2022–2023), the effect of conservation agricultural practices (zero tillage planting, crop residue recycling, and crop rotations) on the major soil properties (soil salinity and organic carbon status), crop performance (yield and economics), and water footprint. Conservation agricultural practices significantly reduce soil salinity, build soil organic carbon, reduce water footprint, and increase the profitability of cropping systems compared to tillage-intensive conventional practices. Under conventional agriculture, the sole cropping of rice is more profitable than double and triple cropping systems. [ABSTRACT FROM AUTHOR]

Published

2024

19. Spatio-Temporal Dynamics of Soil Penetration Resistance Depending on Different Conservation Tillage Systems.

Author

Jug, Danijel, Jug, Irena, Radočaj, Dorijan, Wilczewski, Edward, Đurđević, Boris, Jurišić, Mladen, Zsembeli, Jozsef, and Brozović, Bojana

Subjects

*SOIL physics, *CONSERVATION tillage, *SOIL compaction, *SUSTAINABILITY, *SOIL classification

Abstract

As conservation tillage becomes one of the foundations of sustainable crop production, important questions arise about its value, which needs to be defined and evaluated. One of the most important indicators of soil compaction is penetration resistance (PR), which comes as a short-term response to the state of soil physics. The objective of this work is to compare different tillage treatments (TT) on soil compaction on silty clay loam Stagnosol and silt Gleysol in the continental part of Croatia. The research included three tillage treatments: ST—conventional tillage, CTD—deep conservation tillage, and CTS—shallow conservation tillage. PR was determined on each soil depth of 5 cm up to 80 cm, and measuring was provided on two measuring dates. The obtained results showed a higher influence of the year factor than TT. In the upper layers (up to 35 cm), PR values between TT were with significant differences, but in most cases below root-limiting critical values, while in deeper soil layers (35–80 cm), we found that penetration values on each tillage treatment begin to stabilize and smooth out in most cases, with similar dynamics on both soil types and measurement dates. In most of the cases, the highest PR was measured for conservation treatments in wetter soil conditions. [ABSTRACT FROM AUTHOR]

Published

2024

20. Shaping Soil Properties and Yield of Cereals Using Cover Crops under Conservation Soil Tillage.

Author

Wilczewski, Edward, Jug, Irena, Szpunar-Krok, Ewa, Staniak, Mariola, and Jug, Danijel

Subjects

*SOIL conservation, *CARBON in soils, *CONSERVATION tillage, *PLANT biomass, *SOIL enzymology, *COVER crops, *TILLAGE

Abstract

The aim of this review was to collect current results on the effect of different plants grown as winter and summer cover crops (CC) on the physical, chemical, and biological properties of soil and on the yield of cereal crops grown in a site with CC, using conservation soil tillage. The analyzed studies indicate that CC usually have a positive impact on the physical and biological properties of the soil. Regardless of the plant species used as CC, we can expect an increase in the number of soil microorganisms and an improvement in the activity of soil enzymes. This effect is particularly beneficial in the case of reduced tillage systems. Mixing CC biomass with the topsoil loosens compacted soils and, in the case of light, sandy soils, increasing the capacity of the sorption complex. The size and composition of CC biomass and weather conditions during the vegetation period and during the covering of the soil with plant biomass are of great importance for improving the chemical properties of the soil. A beneficial effect of CC, especially legumes, on the content of the mineral nitrogen in the topsoil is usually observed. Sometimes, an increase in the content of available forms of potassium (K) and/or phosphorus (P) is also achieved. The effect of CC on the content of soil organic carbon (C), total nitrogen (N), or soil pH is less common. CC used in reduced tillage systems can significantly improve the yield and quality of cereal grain, especially when legumes are used as CC in low-fertility soil conditions and at low fertilization levels. However, non-legumes can also play a very positive role in shaping soil properties and improving cereal yield. [ABSTRACT FROM AUTHOR]

Published

2024

21. Soil health influenced more by conservation tillage and cropping practice than irrigation level in a sandy semiarid cotton system.

Author

Petermann, Billi Jean, Lewis, Katie, Acosta-Martinez, Veronica, Laza, Haydee E., Steffan, Joshua J., and Slaughter, Lindsey C.

Subjects

*FATTY acid methyl esters, *CROPPING systems, *CROP management, *VESICULAR-arbuscular mycorrhizas, *SOIL depth, *CONSERVATION tillage, *TILLAGE

Abstract

Cropping systems in semiarid regions have frequently relied on continuous tillage and irrigation, but declining groundwater resources have prompted a greater focus on conservation practices to improve soil health and water storage. We compared soil health responses from cotton production systems in semiarid, coarse-textured soils with different crop management strategies under high or low irrigation levels. Management systems included continuous cotton with conventional tillage (CCCT) compared to no-till cotton with a rye cover crop (NTCR) and no-till cotton with a wheat-fallow rotation (NTCW), including high or low irrigation zones within each system. Samples were collected annually from two bulk soil depths (0–10 cm and 10–20 cm) and root-associated soils 7 years after systems were established and continued for 2 years. We found that cropping system, but not irrigation level, altered soil microbial communities and other soil health indicators. Despite variation between study years and sampling zones, the conservation systems had greater soil microbial community size via ester-linked fatty acid methyl ester (EL-FAME or FAME) analysis, extracellular enzyme activities, and soil organic matter than the CCCT system. The NTCW system also had greater arbuscular mycorrhizal fungi FAME abundance. Our study suggests that no-till and conservation strategies such as cover cropping and rotation can improve biological soil health indicators in these sandy semiarid soils even with limited irrigation. [ABSTRACT FROM AUTHOR]

Published

2024

22. Contrasting soil management systems had limited effects on soil health and crop yields in a North Central US Mollisol.

Author

Crespo, Cecilia, O’Brien, Peter L., Nunes, Márcio R., Ruis, Sabrina J., Emmett, Bryan D., Rogovska, Natalia, Malone, Rob W., Cambardella, Cindy, and Kovar, John L.

Subjects

*CROPPING systems, *SOIL management, *CROP yields, *COVER crops, *CONSERVATION tillage, *NO-tillage

Abstract

Management practices such as relay cropping, cover crops, and no-tillage may promote soil health in the North Central United States. However, soil health indicators in corn (Zea mays L.)–soybean [Glycine max (L.) Merr.] systems involving multiple management practices are not well documented. The objective of this study was to determine the sensitivity of soil health metrics and the Soil Management Assessment Framework (SMAF) to contrasting management systems with different tillage, crops, and fertilization in a North Central US Mollisol. Different management systems, including conservation tillage and nitrogen fertilization strategies, cover cropping, and camelina [Camelina sativa (L.) Crantz] relay intercropping, were compared to a conventional corn–soybean system. Different systems did not affect most soil health indicators compared to the conventional system. Aggregate stability was the only indicator to change due to management, where no-till with cover crops increased aggregate stability by 38% compared with camelina relay cropping. The SMAF scores for all the soil quality indices were unaffected by treatments but displayed high values of over 90%. Overall, crop yields were more closely related to weather conditions and management systems than to soil health indicators. Soybean yields were decreased (between 1 and 2 Mg ha−1 ) in the camelina relay cropping system, while corn yields were lower (up to 70%) in the treatment that received no N fertilization. Ultimately, these findings suggest that soil health indicators are resilient to change due to management in these highly productive Mollisols and may not be closely associated with crop yields. [ABSTRACT FROM AUTHOR]

Published

2024

23. Wheat cover crop has minimal effect on physical soil properties in the North Carolina Piedmont.

Author

Roper, Wayne R., Osmond, Deanna L., and Heitman, Joshua L.

Subjects

AGRICULTURAL conservation, CROP management, ENERGY crops, CONSERVATION tillage, AGRICULTURAL productivity, NO-tillage, COVER crops

Abstract

Environmental awareness about soil and water conservation in agroecosystems has shifted behaviors toward favoring conservation practices in agricultural management. Interest in conservation tillage and cover cropping has increased, but some regions encounter major challenges with adjusting management to accommodate these practices while optimizing crop production. In an Ultisol in the North Carolina Piedmont, a long-term corn (Zea mays) and soybean (Glycine max) rotation with tillage intensities ranging from no-till to moldboard plowing in a randomized complete block design was used to assess changes in physical soil properties after introducing wheat (Triticum aestivum) as a winter cover crop. Cover crop biomass was measured along with volumetric water content (VWC) and bulk density (BD) at 0–15 cm, water retention (WR), water-stable aggregation (WSA), and soil organic carbon (SOC) at 0–7.5 cm, and penetration resistance (PR) at 0–45 cm. No differences in VWC or WR could be solely attributed to cover cropping, but no-till with cover cropping had the highest macroporosity where there was no vehicle traffic. Vehicle traffic had a stronger effect on soil compaction (BD and PR) than cover cropping regardless of tillage. Conservation tillage increased WSA and SOC when compared to plow tillage, but three seasons of a wheat cover crop did not significantly change these properties, possibly because wheat produced low biomass each year (750–1900 kg ha−1). Wheat had minimal effect on physical soil properties in the short term, and potential for improvement with long-term optimal cover crop management in this region requires further assessment. [ABSTRACT FROM AUTHOR]

Published

2024

24. Long-Term Minimum Tillage and Straw Retention Promote Macroaggregate Formation, Carbon and Nitrogen Sequestration under Wheat-Maize Rotation in Northern China.

Author

Ren, Zhijie, Han, Xiaojie, Han, Zhidong, Tian, Wenzhong, Li, Junhong, Lv, Junjie, Shen, Yuanxin, Xie, Yingxin, Ma, Geng, Li, Gezi, Zhao, Yanan, and Wang, Chenyang

Subjects

CONSERVATION tillage, CARBON sequestration, SOIL structure, SOIL sampling, MULCHING, TILLAGE, NO-tillage

Abstract

Conservation tillage is believed to promote soil aggregate stability, carbon (C) and nitrogen (N) sequestration, but the underlying mechanisms remain unclear. In this study, soil samples from an 18-year experiment including conventional tillage with straw removal (CT), deep scarification with straw mulching (DS), and no-tillage with straw mulching (NT) were used to obtain different fractions based on a comprehensive wet-sieving method of aggregate and particle size. The results showed that NT and DS increased soil organic carbon (SOC) and N by 9.3–16.4% and 10.8–25.8%, respectively, in addition to increasing the weight proportion of macroaggregates and the contribution of macroaggregate-associated C and N to total SOC and N. The C change in the total POM accounted for 77.4% and 79.9% of the total SOC increase by NT and DS, while the MAOM only accounted for 29.2% and 25.2%, respectively. Meanwhile, microaggregates-within-macroaggregates accounted for 96.9% and 90.5% of the SOC increase by NT and DS, respectively. The total SOC and N were positively correlated with the C and N of the macroaggregates and subfractions. In conclusion, the formation of macroaggregates drives soil C and N sequestration under conservation tillage, and POM and mM were important functional pools in this process. [ABSTRACT FROM AUTHOR]

Published

2024

25. Landscape‐scale predictions of future grassland conversion to cropland or development.

Author

Barnes, Kevin W., Niemuth, Neal D., and Iovanna, Rich

Subjects

*GRASSLAND conservation, *STANDARD deviations, *CONSERVATION tillage, *CROP development, *GRASSLANDS

Abstract

Grassland conservation planning often focuses on high‐risk landscapes, but many grassland conversion models are not designed to optimize conservation planning because they lack multidimensional risk assessments and are misaligned with ecological and conservation delivery scales. To aid grassland conservation planning, we developed landscape‐scale models at relevant scales that predict future (2021–2031) total and proportional loss of unprotected grassland to cropland or development. We developed models for 20 ecoregions across the contiguous United States by relating past conversion (2011–2021) to a suite of covariates in random forest regression models and applying the models to contemporary covariates to predict future loss. Overall, grassland loss models performed well, and explanatory power varied spatially across ecoregions (total loss model: weighted group mean R2 = 0.89 [range: 0.83–0.96], root mean squared error [RMSE] = 9.29 ha [range: 2.83–22.77 ha]; proportional loss model: weighted group mean R2 = 0.74 [range: 0.64–0.87], RMSE = 0.03 [range: 0.02–0.06]). Amount of crop in the landscape and distance to cities, ethanol plants, and concentrated animal feeding operations had high variable importance in both models. Total grass loss was greater when there were moderate amounts of grass, crop, or development (∼50%) in the landscape. Proportional grass loss was greater when there was less grass (∼<30%) and more crop or development (∼>50%). Some variables had a large effect on only a subset of ecoregions, for example, grass loss was greater when ∼>70% of the landscape was enrolled in the Conservation Reserve Program. Our methods provide a simple and flexible approach for developing risk layers well suited for conservation that can be extended globally. Our conversion models can support conservation planning by enabling prioritization as a function of risk that can be further optimized by incorporating biological value and cost. [ABSTRACT FROM AUTHOR]

Published

2024

26. Effects of autumn tillage with straw return on soil physical characteristics of corn fields in the eastern loess plateau.

Author

Yuchen Fan, Yaqi Yuan, Tao Li, Wen Lin, Xiwang Tang, Gaimei Liang, and Nana Li

Subjects

AUTUMN, PLATEAUS, TILLAGE, SOILS, PLOWING (Tillage), STRAW

Abstract

The implementation of unsuitable tillage practices has the potential to disrupt the structure integrity of the ploughed layer, as well as to influence the physical parameters of the soil. The application of a reasonable tillage method has been demonstrated to result in an improvement in the physical quality of the soil. Three autumn tillage practices have been implemented at the Dongyang Experimental Station of Shanxi Agricultural University since 2016: no-tillage with straw mulch (NTS), autumn rotary tillage with straw incorporation (RTS), and autumn plough tillage with straw incorporation (PTS). The impact of autumn tillage practices on soil physical quality in the 0-30 cm profile of spring corn fields was evaluated following the corn harvest in 2018 and 2019. The results showed that compared to the NTS treatment, the application of RTS was found to have decreased significantly by 9.6%-24.2% in soil bulk density, while it increased significantly by 12.8%-34.0% in total porosity and by 43.5%-146.4% in macroporosity at a depth of 5-10 cm. In comparison to the NTS treatment, the adoption of PTS was found to decrease significantly by 10.7%-30.5% soil bulk density, while it increased significantly by 9.9%-42.7% the total porosity and 23.1%-202.8% the macroporosity at a depth of 0-10 cm. Furthermore, the soil microporosity significantly increase of 7.5%-11.1% under the RTS treatment at the 0-5 cm soil depth and 7.7%-11.2% under the PTS treatment at the 10-20 cm soil depth. Soil physical quality index (SQI) significantly increase under the RTS and PTS treatments, with a 41.26% and 57.57% improvement, respectively, in comparison to the NTS treatment. In summary, the adoption of autumn tillage with straw return (RTS and PTS) demonstrated a reduction in soil bulk density, an increase in soil porosity, macroporosity, and a promotion of capillary porosity, and promoted the improvement of soil physical quality on the Eastern Loess Plateau when compared to no-tillage with straw mulch (NTS). [ABSTRACT FROM AUTHOR]

Published

2024

27. Enhancing Soil Conditions and Maize Yield Efficiency through Rational Conservation Tillage in Aeolian Semi-Arid Regions: A TOPSIS Analysis.

Author

Cong, Zijian, Gu, Jian, Li, Chunqian, Li, Fei, and Li, Fengming

Subjects

SUSTAINABLE agriculture, WIND erosion, WATER efficiency, ARID regions, ECOLOGICAL regions, CONSERVATION tillage, NO-tillage

Abstract

Conservation tillage technology possesses substantial potential to enhance agricultural production efficiency and tackle issues such as wind erosion and land degradation in semi-arid regions. The integration of no-tillage and straw mulching technologies in the conventional aeolian semi-arid agricultural zones of western Liaoning, China, has led to notable improvements in crop yield and soil quality. However, a comprehensive assessment of the mechanisms and kinetics involved in soil nutrient variations is yet to be conducted. During a two-year study period, we assessed four tillage systems in the aeolian semi-arid regions of Northern China: no-tillage with full straw mulching (NTFS), no-tillage with half straw mulching (NTHS), no-tillage without straw mulching (NT), and conventional tillage (CT). The investigation focused on examining nutrient conditions, enhancing photosynthetic activity, and increasing maize yield while improving water use efficiency (WUE). Our findings emphasize the beneficial impact of combining no-tillage and straw mulching on enhancing soil water retention, resulting in a notable rise in soil moisture levels during the crucial growth phases of maize. This approach also positively influenced soil nutrient levels, particularly in the 0–20 cm layer, fostering an environment conducive to maize cultivation. In terms of ecological benefits, no-tillage with straw mulching curtailed soil sediment transport and wind erosion, notably at 30–40 cm heights, aiding in the ecological protection of the region. The yield and WUE were substantially higher under NTFS and NTHS than under CT, with NTHS demonstrating the most significant gains in yield (14.5% to 16.6%) and WUE (18.3% to 21.7%) throughout the study period. A TOPSIS (Technique for Order Preference by Similarity to Ideal Solution) analysis confirmed NTHS as the optimal treatment, achieving the highest scores for soil water, nutrient availability, wind erosion control, maize photosynthesis, yield, and WUE, thus emerging as the most effective conservation tillage strategy for sustainable agriculture in aeolian semi-arid regions. [ABSTRACT FROM AUTHOR]

Published

2024

28. Design and experiment of high-speed straw cleaning unit with double air springs.

Author

Xiaomeng Xia, Honggang Li, Shuyan Liu, Ruiqiang Ran, Yongjian Cong, Yuhan Jin, and Dongyan Huang

Subjects

*STANDARD deviations, *PLANT residues, *CONSERVATION tillage, *FIELD research, *NO-tillage

Abstract

No-tillage planters need to be equipped with row cleaners to remove post-harvest plant residue from the seedbed. The two-disc row cleaners cannot effectively remove the plant residue at high speed because the working depth is unstable, which leads to poor seeding quality of the seeder. A straw cleaning unit with double air springs was designed to achieve better straw cleaning performance at high speeds. The analysis of the mechanical characteristics of the double air spring system showed that it enabled separate adjustment of force and stiffness. A dynamic model of the straw cleaning unit was established, and the effectiveness of the double air spring system with adjustable stiffness in stabilizing the working depth of the row cleaners was analyzed. Field experiments were conducted to evaluate the straw cleaning performance and consistency of downforce against the ground of the straw cleaning unit with double air springs at different high speeds. The results showed that the stiffness of the double air spring system for better straw cleaning performance of the straw cleaning unit was different at different working speed, and the required stiffness increased as the working speed increased; When the working speed was 8- 12 km/h, the coefficient of variation of cleaned strip width was 6.9%-12.1%, the straw cleaning rate was 81.6%-92.2% and the root mean square error of downforce was 19.93-28.63 N; the coefficient of variation of cleaned strip width was moderately positively correlated with the root mean square error of downforce, and the cleaned strip width consistency was better when the root mean square error of downforce was lower than 25.00 N. [ABSTRACT FROM AUTHOR]

Published

2024

29. Assessing the Impact of Tillage Methods on Soil Moisture Content and Crop Yield in Hungary.

Author

Modiba, Maimela Maxwell, Ocansey, Caleb Melenya, Ibrahim, Hanaa Tharwat Mohamed, Birkás, Márta, Dekemati, Igor, and Simon, Barbara

Subjects

*SUSTAINABLE agriculture, *SUSTAINABILITY, *AGRICULTURAL development, *SOIL moisture, *AGRICULTURE, *PLOWING (Tillage), *TILLAGE

Abstract

A decline in rainfall as a source of agricultural water has affected and will continue to affect sustainable crop production globally including in Hungary. Conservation of the greatest water reservoir is important for the sustainable development of agriculture in Hungary. The objective of this study was to evaluate the effects of the different tillage methods on soil moisture content, grain yield, and root weight of wheat (Triticum aestivum) and sunflower (Helianthus annuus) under rainfed conditions. A field study was conducted at the Józsefmajor Experimental and Training Farm (JM) of the Hungarian University of Agriculture and Life Sciences near Hatvan. The experiment consisted of six tillage treatments: disking (D, 16 cm), shallow cultivation (SC, 20 cm), no-till (NT), deep cultivation (DC, 25 cm), loosening (L, 45 cm), and plowing (P, 30 cm). Soil moisture content (SMC) was measured monthly, and grain yield and root weight were measured at the end of the cropping period. Our results showed no significant difference in SMC between conservation and conventional tillage methods in 2018. However, in 2021, greater SMC was significantly conserved under NT compared to P. Regarding the sampling date, a significant increase in moisture with time was observed. A significantly lower SMC was observed on 3 June 2019 between L and D. while on the 9 September 2020, SMC significantly differed between P and all the other treatments (D, SC, NT, DC, and L). Interestingly in 2018, SMC was significantly lower at 10–20 cm depth between L and D. Notably the effect of depth on SMC was observed as moisture significantly increased with increasing depth in all tillage treatments. Root weight was greatest at DC (1.54 t ha−1) in 2018 and under L (3.89 t ha−1) in 2021. Similarly, wheat grain yield was greatest at DC (2.48 t ha−1) in 2018, while sunflower yield in 2021 was greatest at L (3.86 t ha−1). It is comprehensible that conservation tillage methods such as L and NT can increase SMC and grain yield. [ABSTRACT FROM AUTHOR]

Published

2024

30. Effect of Conventional and Conservation Agriculture Practices on Dissipation of Metribuzin and Clodinafop-Propargyl, Soil Enzymatic and Microbial Activities in Wheat in a Rice-Wheat System.

Author

Kaur, Pervinder, Jain, Deepali, and Singh Bhullar, Makhan

Subjects

*SUSTAINABLE agriculture, *METRIBUZIN, *CONSERVATION tillage, *AGRICULTURAL conservation, *HERBICIDE application, *NO-tillage, *MICROBIAL enzymes

Abstract

Soil enzymes and microbial activity are an indicator of soil quality for assessing the sustainability of agricultural ecosystems. The present study determined the persistence of metribuzin and clodinafop-propargyl and response of soil quality indicators to (1) conservation agriculture (continuous zero tillage and surface residue retention) and conventional agriculture (continuous tillage and removal/incorporation of residues) practices and (2) weed management practices in a wheat field under rice-wheat system. The shift from conventional to conservation agriculture practices increased the dissipation of metribuzin and clodinafop propargyl and significantly enhanced soil dehydrogenase (DHA) and urease activity. The residues of metribuzin and clodinafop in grain and straw samples from all treatment were below maximum residue limits (<0.01 µg g−1). Post-emergence application of clodinafop-propargyl plus metribuzin caused significant inhibition in DHA and urease activity at 7 days after treatment (DAT) compared to unsprayed control. However, from 31 DAT till crop harvest (115 DAT), herbicide treated plots had higher enzymatic activity than unsprayed plots. Intervention of one hoeing following herbicide application had greater stimulation in enzyme activity than sole herbicide. Conservation agriculture practices had higher colony development (CD) and ecophysiological (EP) indices than conventional agriculture practices for heterotrophic bacteria, fungi and actinomycetes. All tillage, residue and weed management practices had non-significant effect on alkaline phosphatase activity and phosphate solubilizers, in soil. Adoption of conservation agriculture practices along with integrated weed management seems to be the best way of sustaining the soil biological parameters and cycling of various important soil nutrients which may potentially alter vital soil processes resulting in increased agricultural sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

31. Conservation tillage as an economic and ecological farming option for Summer Maize in the oasis region of Northwest China.

Author

Xue, Yunyin, Zhou, Juanjuan, Ran, Linling, Wu, Haoyang, Wei, Wei, Hu, Xinkun, Xia, Fei, and Wang, Junqiang

Subjects

*CORPORATE profits, *CONSERVATION tillage, *AGRICULTURE, *SOIL temperature, *AGRICULTURAL research, *TILLAGE

Abstract

Aims: Balancing yield and soil CO2 emissions in cropping systems has become a focus of agricultural research. To explore effective ways to achieve the balance, three years (2016–2018) of field experiments were conducted in the oasis zone of Northwest China. Methods: Three replications of the four tillage systems (NT, no-tillage; MT, minimal-tillage; ST, sub-tillage; FT, fold-tillage) were used in a randomized complete block design. Results: It was found that tillage practice had no significant effect on soil carbon pools. However, FT exhibited a significantly higher soil carbon emission intensity (SCEI) and net ecosystem primary productivity (NPP). Still, poorly in terms of net ecosystem productivity (NEP) than those of the NT, MT, and ST treatments, MT performed the highest NEP and maize yield (P < 0.05). The total cumulative CO2 emissions of the FT were 23.3%-37.6% higher than those of the other tillage practices. Furthermore, we identified that soil CO2 emission was mainly influenced by soil temperature and soil moisture. NT increased farmers' net income and output/input ratio by 20.2% and 41.3% respectively compared with FT and demonstrated better economic benefits and net ecosystem productivity. Conclusions: The results suggest that conservation tillage (especially NT and MT) is advantageous to local economic and ecological benefits in the short term. However, the years of continuous tillage are critical for increasing crop yields and reducing CO2 emissions, so the feedback response of long-term tillage on farmland still needs to be observed and studied. [ABSTRACT FROM AUTHOR]

Published

2024

32. Impact of long-term tillage on the soil organic carbon storage and its composition in black soil.

Author

TIAN Sheng-tao, LUO Yang, SUI Pengxiang, WANG Hao, REN Ying, ZHOU Siqi, LIU Haifeng, and ZHENG Jinyu

Abstract

Soil organic carbon ( SOC) is essential for maintaining soil fertility and promoting sustainable agricultural development. We investigated the impact of long-term tillage practices on soil organic carbon storage ( SOCS) and its components in dryland farming areas of the black soil region, based on a 39-year tillage practice experiment. We compared the effects of different tillage practices ( conventional rotary and ridge tillage, CT; no-tillage, NT; subsoiling tillage, ST; moldboard plowing, MP) on SOCS, active organic carbon components, and microbial nec-romass carbon (MNC) content in the 0-40 cm soil layer. The results showed that, compared to CT, NT significantly increased the contents of SOCS, SOC, dissolved organic carbon ( DOC), microbial biomass carbon ( MBC), easily oxidizable organic carbon (EOC), and MNC in the 0-20 cm soil layer. Both ST and MP significantly improved the contents of SOCS, SOC, and EOC in 0-20 and 20-40 cm soil layers compared to CT and increased MBC content in the 20 - 40 cm soil layer. Additionally, MP treatment significantly improved the contents of DOC, particulate organic carbon, and MNC in the 20-40 cm soil layer compared to other treatments. ST and MP significantly reduced the contribution rate of MNC to SOC in both soil layers compared to CT and NT treatments. Results of structural equation modeling showed that enhancing the mean weight diameter of soil aggregates, field capacity, and total phosphorus content, along with increasing the activities of P-glucosidase, amylase, and lignin peroxidase, could promote MNC accumulation. MP treatment facilitated the uniform distribution of SOC, active organic carbon, and MNC in the 0-40 cm soil layer, which was more conducive to the fixation of SOC in farmland in the black soil region. [ABSTRACT FROM AUTHOR]

Published

2024

33. 季节性冻融期不同秸秆还田方式下黑土温度特征.

Author

李 爽, 郭美莲, 范昊明, 贾燕锋, and 马仁明

Subjects

SOIL temperature, BLACK cotton soil, SOIL profiles, SOIL freezing, CONSERVATION tillage

Abstract

Copyright of Journal of Soil & Water Conservation (1009-2242) is the property of Institute of Soil & Water Conservation 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

34. Combining No-Tillage with Hairy Vetch Return Improves Production and Nitrogen Utilization in Silage Maize.

Author

Li, Zhou, Sun, Xingrong, Pan, Jie, Wang, Tao, Li, Yuan, Li, Xiuting, and Hou, Shuai

Subjects

CONSERVATION tillage, CROP yields, SOIL enzymology, FARM manure, MULCHING, NO-tillage, TILLAGE

Abstract

The combination of no-till farming and green manure is key to nourishing the soil and increasing crop yields. However, it remains unclear how to enhance the efficiency of green manure under no-till conditions. We conducted a two-factor field trial of silage maize rotated with hairy vetch to test the effects of tillage methods and returning. Factor 1 is the type of tillage, which is divided into conventional ploughing and no-tillage; factor 2 is the different ways of returning hairy vetch as green manure, which were also compared: no return (NM), stubble return (H), mulching (HM), turnover (HR, for CT only), and live coverage (LM, for NT only). Our findings indicate that different methods of returning hairy vetch to the field will improve maize yield and quality. The best results were obtained in CT and NT in HM and LM, respectively. Specifically, HM resulted in the highest dry matter quality and yield, with improvements of 35.4% and 31.9% over NM under CT, respectively. It also demonstrated the best economic and net energy performance. However, other treatments had no significant effect on the beneficial utilization and return of nutrients. The LM improved yields under NT by boosting soil enzyme activity, promoting nitrogen transformation and accumulation, and increasing nitrogen use efficiency for better kernel development. Overall, NTLM is best at utilizing and distributing soil nutrients and increasing silage maize yield. This finding supports the eco-efficient cultivation approach in silage maize production in the region. [ABSTRACT FROM AUTHOR]

Published

2024

35. تأثیر روشهای خاک ورزی حفاظتی در مقایسه با خاک ورزی مرسوم بر ظرفیت نگهداری آب و مقدار ماده آلی خاک (مطالعه موردی یزد).

Author

غلامحسن رنجبر, حسین بیرامی, سید علی طباطبائی, مهدی شیران تفتی, and هادی پیراسته انو

Subjects

CROPPING systems, AGRICULTURAL conservation, SOIL density, SOIL moisture, GRAIN yields, CONSERVATION tillage, TILLAGE

Abstract

Background and Objective: This research was conducted in order to compare conservation tillage methods compared to conventional tillage on the moisture retention, organic matter and bulk density of the soil. Materials and Methods: Experiments were conducted on permanent raised bed (PRB), no-till with SFOGGIA (NT) and Jab Planter (JP) equipments, in a wheat- rapeseed-corn cropping system, during 2018-2020, as a randomized complete block design with three replicates in Yazd. Barzegar and Neptune cultivars and SC704 hybrid were used for wheat, rapeseed and corn, respectively. The examined characteristics included levels of soil moisture, bulk density and amount of soil organic matter. Results: Average of organic matter in 0-30 cm soil depth was increased from 0.23% at the beginning of experiment to 0.53%, 0.67% and 0.48% at the end of experiment in PRB, NT and JP treatments, respectively. The amount of soil organic matter in CT treatment was about 0.49% at the end of the experiment. The highest amount of available water was observed in PRB (0.207 %), CT (0.193 %) and JP (0.163 %) treatments, respectively. The lowest value of this parameter was observed in NT treatment (0.143%). The lowest value of the average bulk density of soil was observed in the CT treatment (1.47 g.cm³ ) and the highest value was observed in the NT treatment (1.60 g.cm³ ). Results showed significant differences among different tillage treatments in terms of wheat grain yield. Wheat grain yield in PRB treatment was significantly higher than the other treatments. The lowest wheat grain yield was obtained at NTs and NTj treatments. Wheat grain yield in CT, PRB and NTs and NTj treatments, were 4422, 5186,3762 and3547 kg.ha-1, respectively. The highest grain yield for rapeseed was obtained at CT and PRB treatments with no significant differences. The lowest grain yield was also observed for NTj treatment. The highest fresh weight of corn forage (71021 kg.ha-1 ) was observed in PRB treatment which was not statistically different from fresh weight in NTs and NTj treatments. The fresh weight of corn forage in CT treatment was 29% lower than fresh weight in PRB treatment. Conclusion: The use of conservation tillage methods and preservation of residues in the field can help to improve soil organic matter. Also, the average bulk density, water holding capacity, saturated moisture and field capacity moisture of the soil are strongly affected by the application of tillage methods and also the type of equipment used in tillage operation. [ABSTRACT FROM AUTHOR]

Published

2024

36. تأثیر سامانه های مختلف خاک ورزی بر ویژگیهای فیزیکی خاک و صفات کمی ارقام مختلف گندم در اراضی دیم منطقه دالاهو.

Author

ويكتوريا رمضاني, حمیدرضا چقازردی, علی بهشتی آل آقا, دانیال کهریزی, and رضا حق پرست

Subjects

CONSERVATION tillage, PLANT residues, SOIL temperature, SOIL moisture, GRAIN yields, TILLAGE

Abstract

Background and Objective: Considering the extensive cultivation of wheat in the drylands of Kermanshah province and farmers' lack of proper management of plant residues, it is necessary to think of a solution for the appropriate management of residues and wheat cultivation. For this purpose, an experiment was conducted to investigate the effect of different tillage systems on soil physical characteristics and quantitative traits of varying wheat cultivars in the drylands of the Dalahoo region. Materials and Methods: A split-plot experiment was conducted using a randomized complete block design with three replications. Tillage systems (conventional, reduced, and no-tillage) were investigated as main plots, and 26 wheat genotypes were analyzed as secondary plots. Soil physical characteristics and wheat yield and yield components were also investigated. Results: The results showed significant changes in the physical characteristics of the soil, the change of soil organic matter, and the yield and yield components of wheat. They were affected by tillage systems, genotype, and the interaction effect of tillage in genotype. The results showed that with increasing depth, soil temperature decreased, and soil moisture increased. Conclusion: In no-till cultivation, the change of soil organic matter was less than in other tillage systems. The highest wheat grain yield (6658 kg.ha-1 ) was under the interaction effect of the Mirzabey (Durum) genotype (genotype 24) in the no-tillage system. Conservation tillage proves the importance of residues on the soil surface in maintaining moisture in drylands, and probably in Dalahoo areas, conservation tillage methods are better for improving yield. [ABSTRACT FROM AUTHOR]

Published

2024

37. Potential Reduction of Spatiotemporal Patterns of Water and Wind Erosion with Conservation Tillage in Northeast China.

Author

Jiang, Fahui, Peng, Xinhua, Li, Qinglin, Qian, Yongqi, and Zhang, Zhongbin

Subjects

WIND erosion, UNIVERSAL soil loss equation, SOIL erosion, SOIL conservation, CONSERVATION tillage

Abstract

Conservational tillage (NT) is widely recognized globally for its efficacy in mitigating soil loss due to wind and water erosion. However, a systematic large-scale estimate of NT's impact on soil loss reduction in Northeast, China's primary granary, remains absent. This study aimed to investigate the spatial and temporal variability of soil erosion under NT compared to conventional tillage (CT) in the black soil region and to analyze the underlying mechanisms driving these erosions. The Revised Universal Soil Loss Equation (RUSLE) and the Revised Wind Erosion Equation (RWEQ) models were employed, incorporating previously published plot/watershed data to estimate the potential reduction of water and wind erosion by NT in this region. Results indicated that under CT practices, water- and wind-induced soil losses were widely distributed in the arable land of Northeast China, with intensities of 2603 t km−2 a−1 and 34 t km−2 a−1, respectively. Furthermore, the erosive processes of water and wind erosion were significantly reduced by 56.4% and 91.8%, respectively, under NT practices compared to CT. The highest efficiency in soil conservation using NT was observed in the mountainous regions such as the Changbai Mountains and Greater Khingan Mountains, where water erosion was primarily driven by cropland slopes and wind erosion was driven by the wind speed. Conversely, the largest areas of severe erosion were observed in the Songnen Plain, primarily due to the significant proportion of arable land in this region. In the plain regions, water-induced soil loss was primarily influenced by precipitation, with light and higher levels of erosion occurring more frequently on long gentle slopes (0–3°) than on higher slope areas (3–5°). In the temporal dimension, soil loss induced by water and wind erosion ceased during the winter under both tillage systems due to snow cover and water freezing in the soil combined with the extremely cold climate. Substantial reductions were observed under NT from spring to autumn compared to CT. Ultimately, the temporal and spatial variations of soil loss under CT and NT practices were established from 2010 to 2018 and then projected onto a cropland map of Northeast China. Based on this analysis, NT is recommended as most suitable practice in the southern regions of Northeast China for maintaining soil health and crop yield production, while its suitability decreases in the northern and eastern regions. [ABSTRACT FROM AUTHOR]

Published

2024

38. Effects of Conservation Tillage on Agricultural Green Total Factor Productivity in Black Soil Region: Evidence from Heilongjiang Province, China.

Author

Zhang, Mei, Zhang, Hanye, Deng, Yun, and Yi, Chuanqi

Subjects

CONSERVATION tillage, AGRICULTURAL conservation, BLACK cotton soil, INDUSTRIAL productivity, SOIL conservation

Abstract

The implementation of conservation tillage is crucial for the preservation and utilization of black soil. This study examined 297 new agricultural management entities in five pilot counties in the black soil region of northeast China. Using the SBM-Undesirable model, this study measured and evaluated the agricultural green total factor productivity (AGTFP) of these entities. We further employed the Tobit model to explore the impact of conservation tillage on the AGTFP. The findings revealed that the average AGTFP value of the sample entities was 0.4364, indicating a generally low degree of AGTFP that exhibited significant variation. Improvement in input indicators (such as machinery) and undesirable output indicators (such as net carbon emissions) was particularly needed. Additionally, conservation tillage had a significant positive impact on AGTFP, with a higher number of applied technologies correlating with increased productivity. Material subsidies for conservation tillage offered greater direct cost relief and had a stronger positive effect on AGTFP in comparison with cash subsidies. Furthermore, apart from policy factors, key production and operation characteristics—such as access to agricultural materials—also significantly influenced AGTFP. The results of this study offer a valuable decision-making framework and scientific reference for countries in black soil regions worldwide, enabling them to enhance the conservation and sustainable utilization of this vital resource. [ABSTRACT FROM AUTHOR]

Published

2024

39. Drought effects on trait space of winter wheat are independent of land management.

Author

Sun, Qing, Gilgen, Anna K., Wittwer, Raphaël, von Arx, Georg, van der Heijden, Marcel G. A., Klaus, Valentin H., and Buchmann, Nina

Subjects

*DROUGHT management, *WINTER wheat, *TILLAGE, *LAND management, *CLIMATE change adaptation, *DROUGHTS, *CONSERVATION tillage, *ORGANIC farming, *WHEAT

Abstract

Summary: Investigating plant responses to climate change is key to develop suitable adaptation strategies. However, whether changes in land management can alleviate increasing drought threats to crops in the future is still unclear.We conducted a management × drought experiment with winter wheat (Triticum aestivum L.) to study plant water and vegetative traits in response to drought and management (conventional vs organic farming, with intensive vs conservation tillage). Water traits (root water uptake pattern, stem metaxylem area, leaf water potential, stomatal conductance) and vegetative traits (plant height, leaf area, leaf Chl content) were considered simultaneously to characterise the variability of multiple traits in a trait space, using principal component analysis.Management could not alleviate the drought impacts on plant water traits as it mainly affected vegetative traits, with yields ultimately being affected by both management and drought. Trait spaces were clearly separated between organic and conventional management as well as between drought and control conditions. Moreover, changes in trait space triggered by management and drought were independent from each other.Neither organic management nor conservation tillage eased drought impacts on winter wheat. Thus, our study raised concerns about the effectiveness of these management options as adaptation strategies to climate change. [ABSTRACT FROM AUTHOR]

Published

2024

40. EVALUACIÓN DEL RENDIMIENTO DE ARROZ (Oryza sativa L.) COMPARANDO DOS MÉTODOS DE PREPARACIÓN DEL SUELO.

Author

Castillo Coronado, Jordan Alexis, Polanía Montiel, Diana Carolina, and Ardila Marín, Juan Gonzalo

Subjects

*SUSTAINABLE agriculture, *SUSTAINABILITY, *CROP yields, *INDUSTRIAL costs, *RICE, *TILLAGE

Abstract

Contextualization: The cultivation of rice (Oryza sativa L.) throughout its vegetative process generates an increase in bulk density and penetration resistance of soil. Rice crop production costs are distributed in soil preparation and adaptation (20%), planting (10%), cultural work, including irrigation and application of inputs such as fertilizers and pesticides (50%), and harvesting (20%). Preparation is a representative component on which it is possible to have an impact to reduce it. Knowledge gap: As it is a high economic yield crop and not very technified in the department of Huila (Colombia), it is sought to implement conservation plows that provide economic and environmental benefits to the community. Purpose: Aiming to promote more sustainable production and agriculture and to improve mechanized tillage techniques in the municipality of Palermo, it was proposed to evaluate the physical properties of the soil and the yield of the rice crop, modifying conventional harrow preparation with the use of tiller. Methodology: The experimental area of one hectare was divided into experimental plots, T1: One pass of vibratory tiller, and T2: Two passes of conventional plowing (harrow). The physical properties of the soil were evaluated (True density, bulk density, porosity, and texture) and the phenological monitoring of the crop development was carried out (germination, maximum tillering, maximum panicle formation, maturity, and harvest). Soil tests were conducted before and after tillage between 15 and 20 cm depth. The statistical analysis was performed using the Analysis of Variance (ANOVA) and the techno-economic analysis was carried out based on production and operating costs between the two types of tillage. Results and conclusions: The results showed that after soil preparation, bulk density decreased by 5.0% for T1 and 13.5% for T2; these effects also led to an increase in porosity of 13.6% and 29.34%, respectively, and production costs of USD1159.9 for T1 and USD1222.2 for T2. At the end of the study, it was concluded that, when evaluating yield at harvest, there were no significant differences in production because of mechanized tillage. However, a statistical difference was observed between the cost of conventional and reduced tillage, the latter being 148.9% more economical and less aggressive for the soil. [ABSTRACT FROM AUTHOR]

Published

2024

41. Reduced tillage intensity does not increase arbuscular mycorrhizal fungal diversity in European long‐term experiments.

Author

Vahter, Tanel, Taylor, Astrid R., Landa, Blanca B., Linsler, Deborah, Rodriguez, Engracia Maria Madejon, Moreno, Francisco Giron, Pérès, Guénola, Engell, Ilka, Hiiesalu, Inga, Bengtsson, Jan, Oja, Jane, Torppa, Kaisa A., Arias‐Giraldo, Luis F., Guzmán, Gema, Potthoff, Martin, Vasar, Martti, Sandor, Mignon, Sepp, Siim‐Kaarel, Stoian, Vlad, and Öpik, Maarja

Subjects

*SUSTAINABLE agriculture, *SOIL biology, *SOIL biodiversity, *CROPS, *ARABLE land

Abstract

Mechanical soil disturbance is one among the key factors influencing soil biodiversity in agriculture. Although many soil organisms are sensitive to soil disturbance, fungi could be highly impacted due to their sessile lifestyle, relatively slow growth and filamentous body structure. Arbuscular mycorrhizal (AM) fungi are of particular interest in arable lands, providing crop plants with numerous vital services such as nutrient acquisition and protection against abiotic and biotic stressors. Considering this, tillage practices that aim to reduce soil disturbance are often seen as a fungal‐friendly alternative to conventional inversion tillage. Although local studies exist on the impacts of minimal tillage practices on AM fungi, the universality of this approach has been debated. Our objective was to assess the effects of reduced tillage intensity on AM fungi in comparison with conventional tillage. Using high‐throughput sequencing techniques in long‐term field experiments in five European countries, we show that the effects of reduced tillage intensity may not necessarily be positive on soil AM fungal diversity. Plots which were tilled using reduced tillage techniques had lower AM fungal richness in three countries, whereas in one of them, no significant differences were found. We also observed a shift in AM fungal communities where prevalence of taxa preferring root colonisation rather than soil exploration increased under reduced tillage regimes. Here, we argue that more detailed and long‐term studies are needed to understand the factors that could make the reduction of soil disturbance more beneficial to AM fungi if agricultural sustainability goals are to be met. [ABSTRACT FROM AUTHOR]

Published

2024

42. 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

43. Effects of Cascara Cherry and Other Coffee Litter Mulching on Soil Properties, Photosynthesis, and Water Use Efficiency of Coffea Canephora Pierre ex A. Froehner cv. Reyan No.1 Seedling.

Author

Zhang, Ang, Chen, Su-Sen, Lin, Xing-Jun, Yan, Lin, Huang, Yan-Li, Sun, Yan, Zhao, Qing-Yun, Zhao, Shao-Guan, Li, Li-Hua, Long, Yu-Zhou, and Dong, Yun-Ping

Subjects

*LEAF area index, *COFFEE waste, *AGRICULTURAL wastes, *CONSERVATION tillage, *FOREST litter, *POTASSIUM

Abstract

Mulching cultivation with agricultural wastes is the main production pattern of coffee at present, but the effect of mulching cultivation on photosynthetic physiological processes of coffee plants is still not clear. Therefore, a randomized block design was adopted to establish a field experiment by one-year-old Coffee Canephora seedlings in this study. There were four types of mulch treatments, including non-mulch coffee waste (C), mulching coffee litter (L), mulching coffee cascara (cherry pericarp, P), and mulching coffee litter and cascara (LP) in this field experiment. Soil properties and microenvironment (e.g., moisture, temperature, pH, bulk density, organic matter content, alkali-hydrolyzed nitrogen content, available potassium content, and available potassium content), agronomic traits (e.g., specific leaf area, leaf area index, plant height, and relative chlorophyll content), and photosynthetic indices (e.g., photosynthesis, transpiration, respiration, stomatal conductance, intercellular CO2 concentration, water use efficiency, and carbon use efficiency) were investigated to determine the effects of different coffee waste mulches on the photosynthetic physiology of coffee seedlings. The results show that coffee litter and cascara mulch significantly reduced soil temperature by 0.42 or 0.33 °C, respectively, and coffee litter rather than cascara mulch significantly increased the soil's available potassium content by 46.28%, although coffee waste mulch did not affect other soil properties or microenvironment indices; coffee cascara mulching significantly increased the specific leaf area and net and gross photosynthesis of coffee by 45.46%, 78.33%, and 91.72%, respectively, but the mulching treatments did not affect stomatal conductance, transpiration, or carbon use efficiency in this study. Additionally, coffee cascara mulching increased leaf respiration and net and gross water use efficiency by 109.34%, 80.54%, and 104.95%, respectively. The coffee cascara mulching alone had the most significant positive impact on the photosynthetic index, followed by a combination of litter and cascara, litter alone, and the control treatment. The observed variations in the coffee photosynthetic index may be attributed to the reduction of soil temperature caused by mulching treatments rather than the increase in soil nutrients content. These results indicate that coffee cascara mulching could effectively promote photosynthesis and the growth of coffee seedlings by improving the soil microenvironment. [ABSTRACT FROM AUTHOR]

Published

2024

44. Spatio-temporal variation of surface soil hydraulic properties under different tillage and maize-based crop sequences in a Mediterranean area.

Author

Talukder, Rasendra, Plaza-Bonilla, Daniel, Cantero-Martínez, Carlos, Di Prima, Simone, and Lampurlanés, Jorge

Subjects

*SPATIO-temporal variation, *CROP rotation, *SOIL permeability, *AGRICULTURAL conservation, *CORN, *CONSERVATION tillage, *TILLAGE, *COVER crops, *NO-tillage

Abstract

Aims: The surface crust formed by the drop impact of rainfall and/or irrigation is a prevalent characteristic in many Mediterranean soils. However, the temporal variation of soil hydraulic properties induced by surface crust during the high-frequency irrigation has rarely been investigated. Methods: Beerkan infiltration tests in conjunction with the BEST method were used to investigate the effects of surface crusting on the spatio-temporal variation of saturated soil hydraulic conductivity (Ks, mm s−1), sorptivity (S, mm s−0.5), mean pore size (r, mm), number of effective pores per unit area (N, m−2) in Agramunt, NE Spain. Results: In response to autumn tillage, intensive tillage (IT) increased Ks and S due to higher r and N, but both declined after 60 days. Reduced tillage (RT), maintained comparable Ks and S values, despite having a lower N value. After the spring tillage, both IT and RT developed crusted layers, resulting in decreased Ks, S and N. Long-term no-tillage (NT) showed an increasing trend of Ks and S over time, except for the last sampling. Spatial variation (i.e., between the rows, B-row vs. within the row of crops, W-row) of Ks and S was found, and non-crusted soils (W-row) had consistently higher Ks and S than crusted soils (B-row). Conclusions: Conservation tillage i.e., RT and NT improve the surface soil structure and reduce the risk of crust development. Surface cover by crops may help to prevent crust formation within the row of crops, improving soil hydraulic conductivity. [ABSTRACT FROM AUTHOR]

Published

2024

45. Impact of Adopting Strategies to Cope with Climate Change on the Technical Efficiency of Wheat Farmers in Sistan Region-Iran.

Author

Naruei, H., Borazjani, M. Ahmadpour, Salarpour, M., Keikha, A., and Kenari, R. Esfanjari

Subjects

CLIMATE change adaptation, WHEAT farmers, PRINCIPAL components analysis, AGRICULTURE, CONSERVATION tillage

Abstract

The negative and destructive impact of climate change on the efficiency and productivity of agricultural inputs has been demonstrated in many regions of the world, particularly in arid and semi-arid areas. In this context, the adoption of innovative strategies to increase farmers' flexibility and adaptability to climate change has increased. Hence, understanding the impact of climate adaptation strategies on agricultural efficiency and yields is crucial. This study examined the effects of climate change adaptation strategies, input utilization, and external factors beyond farmers' control on technical efficiency using the Endogenous Modified Stochastic Frontier (EMSF) model. Data were collected from 265 questionnaires distributed among wheat farmers during the 2022-2023 cultivation period, using a stratified random sampling approach. The climate adaptation strategy index was formulated using the Principal Component Analysis (PCA) technique. The PCA revealed that changes in farm size (0.812), adaptation of conservation tillage (0.797), and adjustments in planting dates (0.619) were the most influential factors. Conversely, rainwater harvesting (0.219) and biofertilizer application (0.327) emerged as the adaptation strategies with the lowest factor loadings among farmers. In this study, the average technical efficiency of wheat farmers was calculated to be 82%. The model estimation results showed that labor input, chemical pesticides, chemical fertilizers, water, and machinery significantly and positively contribute to wheat production efficiency. Additionally, the implementation of climate adaptation strategies by farmers reduces technical inefficiency. Variables such as education level, farming experience, access to climate information, and access to credit also effectively reduce technical inefficiency. [ABSTRACT FROM AUTHOR]

Published

2024

46. Diversified Cover Crops and No-Till Enhanced Soil Total Nitrogen and Arbuscular Mycorrhizal Fungi Diversity: A Case Study from the Karst Area of Southwest China.

Author

Tian, Lihua, Wang, Tao, Cui, Song, Li, Yuan, Gui, Weiyang, Yang, Feng, Chen, Jihui, Dong, Rui, Gu, Xinyao, Zhao, Xuechun, Zhang, Mingjun, Chen, Chao, and Li, Zhou

Subjects

SOIL chemistry, VESICULAR-arbuscular mycorrhizas, MICROORGANISM populations, CONSERVATION tillage, ACID phosphatase, COVER crops, MONOCULTURE agriculture

Abstract

The deteriorating soil health under continuous monoculture is commonly found across various cropping systems. This study evaluated the effects of different tillage practices (conventional tillage and no till) and species mixtures (legumes and grasses) on arbuscular mycorrhizal fungi (AMF) community properties, soil nutrients, and enzyme activity in a 3-year experiment. Compared with traditional tillage, the number of AMF species under no-till conditions was increased, with the Glomus group being dominant. Under different tillage conditions, TN (total N) and AN (available N) contents under no till were significantly higher than those under conventional tillage, while no significant differences among other nutrients were found. The activities of soil acid phosphatase (S-ACP), soil dehydrogenase (S-DHA), and soil sucrose (S-SC) under conventional tillage were significantly higher than those under no till, and the cover crop mixtures also had an exclusive advantage in yield. Soil organic matter (SOM) indicated a significant negative correlation with glomalin-related soil protein (GRSP). The increase in diversity associated with the AMF species community was strongly correlated with the increase in three enzyme activities, and AN was negatively correlated with all species. Tillage did not significantly change soil chemistry, except for AN, and the high concentration of AN led to a decrease in AMF species. The results of this study showed that no till was an effective measure for enriching soil micro-organism population. Additionally, soil AMF diversity was improved by cover crop mixtures, and microbial diversity was higher than that under monoculture cover crops. Different AMF groups responded differently to tillage and cover crop mixtures. Across all mixtures, the combination of hairy vetch (Vicia villosa R.) and ryegrass (Lolium perenne L.) performed the best. [ABSTRACT FROM AUTHOR]

Published

2024

47. Comparative Analysis of Drought Effects on the Soil Moisture Level and Penetration Resistance in Conventional and Non-Conventional Tillage Systems in Maize Production.

Author

Sojnóczki, István, Nagy, János, Illés, Árpád, Kecskés, István, and Bojtor, Csaba

Subjects

EXTREME weather, CONSERVATION tillage, SOIL moisture, AGRICULTURE, WEATHER, TILLAGE

Abstract

The period of extreme weather anomalies in recent years has challenged farmers, and this has encouraged greater adaptability in farming practices. In the last decade, conventional tillage systems have been complemented by more biologically based cropping systems. The research evaluated the impact of drought on soil physical parameters in maize production by testing different conventional and non-conventional tillage systems to ensure optimal soil physical parameters. In the analysis of the prevailing weather conditions, rainfall values were divided into two parts, the pre-growing season and the growing season. We studied different climatic seasons. In 2021, the soil moisture content in the upper shallow 15 cm soil layer during the sowing period in April in the case of conventional tillage was significantly lower than in reduced tillage, conservation tillage and strip tillage. The most significant difference was measured between conventional and conservation tillage, with a difference of 11.25 v/v%. The 2022 crop year was extremely dry. In June, the highest moisture value in the soil was measured in the case of strip tillage with a value of 21.64 v/v%, which was more than 60% higher than in the case of conventional and conservation tillage. In conventional tillage, a very pronounced compacted layer was observed in the lower part of the ploughed layer. This zone reached a compaction of 6.9 MPa between 28 and 34 cm, which is agronomically harmful. No compacted soil layer was found in the experiment site under conservation tillage. In the severe drought year of 2022, only the strip-till system provided the proper water management conditions for the maize stand. [ABSTRACT FROM AUTHOR]

Published

2024

48. Carbon footprint research and mitigation strategies for rice-cropping systems in China: a review.

Author

Yalan Ji, Yongjin Zhou, Zhong Li, Kaixuan Feng, Xueyuan Sun, Youzun Xu, Wenge Wu, and Huawen Zou

Subjects

ECOLOGICAL impact, NITROGEN fertilizers, DROUGHTS, CONSERVATION tillage, CARBON sequestration, CARBON offsetting

Abstract

Reducing greenhouse gas (GHG) emissions and quantifying the carbon footprint (CF) of rice-cropping systems in the context of food security is an important step toward the sustainability of rice production. Exploring the key factors affecting emission reduction in rice production is important to properly evaluate the impact of China's rice-cropping systems on global climate change. This review provides an overview of the direct and indirect CF in rice-cropping systems; analyzes the influencing factors in terms of rice-based cropping systems, varieties and agronomic practices; and proposes mitigation strategies. Different studies have shown that direct and indirect GHG emissions in rice-based cropping systems accounted for 38.3 to 95.5% and 4.5 to 61.7% of total emissions, respectively. And the CFs of ratoon rice, rice-wheat, rice-maize, rice-rapeseed, and rice-fish systems ranged from 316,9 kg CO2-eq kg-1 to 258,47 kg CO2-eq kg-1, which are lower than that in a double-rice planting system. High-yielding rice, drought-resistant rice, and other hybrids can mitigate GHG emissions from paddy fields by 3.7 ~ 21.5%. Furthermore, organic matter, water, tillage, straw incorporation, conservation tillage, reduced nitrogen fertilizer use, and added biochar and methane inhibitors could reduce emissions. Therefore, through reasonable agronomic measures, variety selection and optimal layout of rice-based rotation systems, the carbon neutral rate of rice production can be improved to help the national carbon sequestration and emission reduction target. [ABSTRACT FROM AUTHOR]

Published

2024

49. Conservation tillage: a way to improve yield and soil properties and decrease global warming potential in spring wheat agroecosystems.

Author

Sadiq, Mahran, Rahim, Nasir, Tahir, Majid Mahmood, Alasmari, Abdulrahman, Alqahtani, Mesfer M., Albogami, Abdulaziz, Ghanem, Kholoud Z., Abdein, Mohamed A., Ali, Mohammed, Mehmood, Nasir, JianyuYuan, Shaheen, Aqila, Shehzad, Muhammad, El-Sayed, Mohamed H., Guoxiang Chen, and Guang Li

Subjects

CONSERVATION tillage, TILLAGE, GLOBAL warming, WHEAT, SOIL conservation, AGRICULTURE, WATER conservation, POTASSIUM

Abstract

Climate change is one of the main challenges, and it poses a tough challenge to the agriculture industry globally. Additionally, greenhouse gas (GHG) emissions are the main contributor to climate change; however, croplands are a prominent source of GHG emissions. Yet this complex challenge can be mitigated through climate-smart agricultural practices. Conservation tillage is commonly known to preserve soil and mitigate environmental change by reducing GHG emissions. Nonetheless, there is still a paucity of information on the influences of conservation tillage on wheat yield, soil properties, and GHG flux, particularly in the semi-arid Dingxi belt. Hence, in order to fill this gap, different tillage systems, namely conventional tillage (CT) control, straw incorporation with conventional tillage (CTS), no-tillage (NT), and stubble return with no-tillage (NTS), were laid at Dingxi, Gansu province of China, under a randomized complete block design with three replications to examine their impacts on yield, soil properties, and GHG fluxes. Results depicted that different conservative tillage systems (CTS, NTS, and NT) significantly (p < 0.05) increased the plant height, number of spikes per plant, seed number per meter square, root yield, aboveground biomass yield, thousand-grain weight, grain yield, and dry matter yield compared with CT. Moreover, these conservation tillage systems notably improved the soil properties (soil gravimetric water content, water-filled pore space, water storage, porosity, aggregates, saturated hydraulic conductivity, organic carbon, light fraction organic carbon, carbon storage, microbial biomass carbon, total nitrogen, available nitrogen storage, microbial biomass nitrogen, total phosphorous, available phosphorous, total potassium, available potassium, microbial counts, urease, alkaline phosphatase, invertase, cellulase, and catalase) while decreasing the soil temperature and bulk density over CT. However, CTS, NTS, and NT had non-significant effects on ECe, pH, and stoichiometric properties (C:N ratio, C:P ratio, and N:P ratio). Additionally, conservation-based tillage regimes NTS, NT, and CTS significantly (p < 0.05) reduced the emission and net global warming potential of greenhouse gases (carbon dioxide, methane, and nitrous oxide) by 23.44, 19.57, and 16.54%, respectively, and decreased the greenhouse gas intensity by 23.20, 29.96, and 18.72%, respectively, over CT. We conclude that NTS is the best approach to increasing yield, soil and water conservation, resilience, and mitigation of agroecosystem capacity. [ABSTRACT FROM AUTHOR]

Published

2024

50. Conservation tillage facilitates the accumulation of soil organic carbon fractions by affecting the microbial community in an eolian sandy soil.

Author

Yu-mei Li, Yu-ming Wang, Guang-wei Qiu, Hong-jiu Yu, Feng-man Liu, Gen-lin Wang, and Yan Duan

Subjects

CONSERVATION tillage, AGRICULTURAL conservation, SANDY soils, MICROBIAL communities, CARBON in soils, TILLAGE, CROP yields, PREDATION

Abstract

Conservation tillage (CT) is an important agronomic measure that facilitates soil organic carbon (SOC) accumulation by reducing soil disturbance and plant residue mulching, thus increasing crop yields, improving soil fertility and achieving C neutrality. However, our understanding of the microbial mechanism underlying SOC fraction accumulation under different tillage practices is still lacking. Here, a 6-year in situ field experiment was carried out to explore the effects of CT and traditional tillage (CK) practices on SOC fractions in an eolian sandy soil. Compared with CK, CT increased the particulate OC (POC) content in the 0-30 cm soil layer and the mineral-associated OC (MAOC) content in the 0-20 cm soil layer. Moreover, tillage type and soil depth had significant influences on the bacterial, fungal and protistan community compositions and structures. The co-occurrence network was divided into 4 ecological modules, and module 1 exhibited significant correlations with the POC and MOC contents. After determining their topological roles, we identified the keystone taxa in the network. The results indicated that the most common bacterial taxa may result in SOC loss due to low C use efficiency, while specific fungal (Cephalotrichum) and protistan (Cercozoa) species could facilitate SOC fraction accumulation by promoting macroaggregate formation and predation. Therefore, the increase in keystone fungi and protists, as well as the reduction in bacteria, drove module 1 community function, which in turn promoted SOC sequestration under CT. These results strengthen our understanding of microbial functions in the accrual of SOC fractions, which contributes to the development of conservation agriculture on the Northeast China Plain. [ABSTRACT FROM AUTHOR]

Published

2024