Your search keyword '"SOIL amendments"' showing total 12,286 results

1. Harvesting of Agricultural Nutrient Runoff with Algae, to Produce New Soil Amendments for Urban and Peri-urban Olive Tree Agroforestry Systems in Southern Europe

Author

Gassner, Vesela Tanaskovic, Symeonidis, Dimitris, Koukaras, Konstantinos, Stefanakis, Alexandros, Series Editor, Nikolaou, Ioannis, Series Editor, Kirchherr, Julian, Editorial Board Member, Komilis, Dimitrios, Editorial Board Member, Pan, Shu Yuan (Sean), Editorial Board Member, Salomone, Roberta, Editorial Board Member, Oral, Hasan Volkan, editor, Calheiros, Cristina, editor, and Carvalho, Pedro, editor

Published

2024

2. Agricultural Waste in Circular Economy: An Indian Scenario

Author

Baruah, Nijara, Bora, Abhijit, Gogoi, Nirmali, Srivastava, Neha, Series Editor, Mishra, P. K., Series Editor, and Singh, Pardeep, editor

Published

2024

3. Using soil amendments and mycorrhiza to improve chemical properties of degraded calcareous soil and yield of sorghum in dryland

Author

Rupa Matheus, Donatus Kantur, and Leta Rafael Levis

Subjects

calcareous soil, soil amendments, soil quality, sorghum yield, Environmental effects of industries and plants, TD194-195

Abstract

Optimized use of calcareous soil in dryland areas needs to begin with rehabilitation efforts using soil amendments, including organic fertilizer and biochar. This study sought to determine whether kinds of soil amendments and mycorrhizal biofertilizers may enhance the chemical quality of calcareous soils and increase the yield of sorghum on dry land. The study was conducted at the experimental garden of the Agricultural Extension Center located in Oelnasi Village from April to August of 2023. Two criteria included in the study were the kind of soil amendment and mycorrhizal biological fertilizer, both of which were arranged in a randomized block design. The parameters observed were soil chemical properties, plant N and P nutrient uptake, and sorghum yield. The research results showed that the application of three types of soil amendments (P1 = cow dung, P2 = rice straw compost, and P3 = corncob biochar) improved the chemical quality of calcareous soil. This application of corncob biochar could significantly reduce soil pH from 7.85 (slightly alkaline) to 7.19 (neutral) and increase soil organic C to 2.55% C, followed by treatment with cow dung and rice straw compost. Other soil chemical properties, i.e., N, P, K, and soil CEC, also improved, which differed from the control treatment. The mycorrhizal biofertilizer provided could also improve the chemical properties of calcareous soil. Providing mycorrhizal biofertilizer could increase the N and P nutrient uptake of sorghum plants by 3.79% dry weight-1 and 2.18% dry weight-1, respectively, as well as increased sorghum yields, respectively by 4.04 t ha-1, 3.97 t ha-1 and 3.87 t ha-1 dry beans, higher than the control which only achieved 2.32 t ha-1 dry beans.

Published

2024

4. Effects of Leonardite on Soil Properties and the Nutrients Concentrations of Tomato Plants.

Author

Sonmez, Sahriye and Öktüren Asri, Filiz

Subjects

*SOIL amendments, *TOMATOES, *SOILS, *COPPER, *ORGANIC fertilizers

Abstract

Leonardite is an important source of organic fertilizers and soil amendment. The objective of this study was to determine the effects of increased doses of leonardite (control (L0), 20 (L20), 40 (L40), 60 (L60), and 80 (L80) t ha−1) on soil properties at different incubation times (control (T0), 15 (T15), 30 (T30), 45 (T45), 60 (T60), and 90 (T90) days). Analysis results of soil samples taken during six different incubation periods. Results showed that application of leonardite significantly improved soil organic matter (SOM), total nitrogen (N), exchangeable calcium (Ca) and, available iron (Fe), manganese (Mn) and zinc (Zn), especially with L40 and L60. Prolonged incubation time was significantly increased N, P, K, Ca, Fe, Zn concentrations especially T60 and T90. The nutrient concentration of the tomato plants was not affected by increased doses of leonardite, except for total N, Fe and Cu. By the way, prolongation of the incubation period resulted in fluctuating nutrient concentrations of the plant. As a result, it was determined that leonardite improved the chemical properties of the soils but it was not sufficient in the feeding of the tomato plant. Therefore, leonardite must be used with chemical fertilizers for plant growing. [ABSTRACT FROM AUTHOR]

Published

2024

5. Short-term high-temperature pretreated compost increases its application value by altering key bacteria phenotypes.

Author

Han, Linpei, Li, Lei, Xu, Yun, Xu, Xinyi, Ye, Wenjie, Kang, Yuanji, Zhen, Feng, and Peng, Xuya

Subjects

*COMPOSTING, *SOIL amendments, *SULFUR cycle, *LOLIUM perenne, *NITROGEN fixation, *CATALASE

Abstract

[Display omitted] • The effects of organic amendments on saline-alkali soil improvement were compared. • The optimal blending ratio of organic amendments was 20%. • High-temperature pretreatment compost favored soil improvement and plant growth. • High-temperature pretreatment composting improved plant antioxidant capacity. • Plant growth was improved by altering soil-dominant microflora and composition. Short-term high-temperature pretreatment can effectively shorten the maturity period of organic waste composting and improve the fertilizer efficiency and humification degree of products. To investigate the effect and mechanism of the end products on the saline–alkali soil improvement and plant growth, the short-term high-temperature pretreatment composting (SHC) and traditional composting (STC) were separately blended with saline–alkali soil in a ratio of 0–40 % to establish a soil–fertilizer blended matrix for cultivating Lolium perenne L. The pot experiments combined with principal component analysis showed Lolium perenne L. planted in 20 % SHC-blended saline–alkali soil had the best growth effect, and its biomass, chlorophyll content, and plant height were 109–113 % higher than STC. The soil physicochemical property analysis showed that SHC and STC increased the soil nutrient content, humification degree, and enzyme activity at any blending ratio. The microbial analysis showed that 20 % SHC in the saline–alkali soil stimulated the growth of functional microorganisms and the addition of SHC promoted the sulfur cycle, nitrogen fixation, and carbon metabolism in the soil–plant system. The correlation analysis showed that pH; nutrient contents; and urease, catalase, sucrase, and phosphatase activities in the saline–alkali soil were significantly correlated with plant growth indexes (p < 0.05). Georgenia and norank_f__Fodinicurvataceae had a stronger correlation with four types of enzyme activities (p < 0.01). SHC improved the saline–alkali soil and promoted plant growth by adjusting soil pH, increasing soil nutrients, and influencing soil enzyme activity and dominant flora. This study provides a theoretical basis for applying SHC products in soil improvement. [ABSTRACT FROM AUTHOR]

Published

2024

6. Soil amendments with nanoparticles control cucumber wilt caused by Fusarium oxysporium.

Author

Li, Xuefei and Liu, Jinyu

Subjects

*SOIL amendments, *PLANT diseases, *WILT diseases, *CUCUMBERS, *FUSARIUM, *FOOD poisoning

Abstract

• ZnO nanoparticles (NPs) were active in inhibiting growth of Fusarium oxysporum. • Plants grown in NPs-amended soil showed improved growth. • NPs caused increased activity of plant defense-related enzymes. • Plants showed enhanced expression of defense-related genes after NPs application. Management of Fusarium wilt, a destructive plant disease, mainly relies on chemicals, but research on novel and eco-friendly methods is needed due to the hazardous effects of chemical pesticides. This study explored the soil application of zinc oxide nanoparticles (ZnONPs) to manage Fusarium wilt disease in cucumber plants. The antifungal activity of ZnONPs against in-vitro growth of Fusarium oxysporum was tested through food poisoning test on the potato dextrose agar medium. The in-vivo potential of NPs for managing Fusarium wilt was checked in pot experiment. In-vitro results confirmed the concentration-dependent in-vitro antifungal activity. The NPs application at 500 µg/ml and 600 µg/ml concentrations showed phytotoxicity and significantly inhibited seed germination and growth of cucumber plants. However, NPs at 300 µg/ml significantly suppressed the pathogenic effects of F. oxysporum on cucumber plants without any phytotoxic effect. The pathogen-inoculated cucumber plants grown in soil amended with NPs showed significantly enhanced growth, lower disease severity, and improved root physiology compared to untreated plants. The plants under NPs treatment showed higher chlorophyll and nitrogen content while decreased membrane permeability and malondialdehyde content. Along with direct antifungal activity, the application of NPs caused an increased expression of defense-related genes and higher activities of defense-related enzymes. These findings verified the efficiency of ZnONPs for suppressing Fusarium wilt disease in cucumber crops, thereby promoting a non-chemical and environmentally friendly approach to controlling Fusarium wilt disease. [ABSTRACT FROM AUTHOR]

Published

2024

7. The Use of Products from Leonardite to Improve Soil Quality in Condition of Climate Change.

Author

Pikuła, Dorota

Subjects

*SOIL conditioners, *SOIL quality, *HUMUS, *SOIL amendments, *HUMIC acid

Abstract

The principle of sustainable fertilisation in modern agriculture, which ensures that the soil is maintained in a fertile state requires the search for alternatives to manure fertilisation for products based on humic substances to increase the organic matter content of soils.The advantage of leonardite over conventional natural and organic fertilisers is mainly due to its high content of organic matter and humic substances (humic and fulvic acids). Leonardite, due to the presence of humic acids in it, can be suitable for soil amendment and yield of barley. In the conducted studies, the yield increase after adding Rosahumus fertilizer to the soil at a rate of 6 kg.ha−1 + NPK (Nitrogen, Phosphorus, Potasssium) was found to be 11% compared to the control (NPK).There were no changes in the Corg. content of the soil as a result of the application of Rosahumus fertilizer with NPK. The fertilizer only slightly modified the fractional composition of humus. In the future, we should expect an increase in the use of leonardite-derived humic substances in fertilizers and soil conditioners to stabilize soil organic matter. [ABSTRACT FROM AUTHOR]

Published

2024

8. Effect of Organic Amendment and Mineral Fertilizer on Soil Aggregate Stability and Maize Yield on the Loess Plateau of China.

Author

Minmin Qiang, Xingchen Zhang, Xiangting Zhuang, and Haochen Zhang

Subjects

*SOIL mineralogy, *SOIL structure, *PLATEAUS, *SOIL amendments, *ARID soils, *CORN

Abstract

Organic amendment has proven to improve soil quality and crop production, in addition to reduce resource waste. However, the effect of organic amendment on soil water-stable aggregates and soil organic carbon is unclear. A two-year field experiment with four organic amendment treatments, biochar, organic fertilizer, microbial agents and polyacrylamide (PAM), was conducted to investigate the effect of different soil organic amendments on Loess Plateau. The results revealed that organic amendments significantly influenced the mean weight diameter (MWD) and geometric mean diameter (GMD) of water-stable aggregates, particularly in the case of PAM treatment. The MWD and GMD values increased significantly by 33.7% and 29.8% in the PAM treatment. The proportion of macroaggregates (2-0.25 mm) showed a remarkable 52.9% increase compared to the control (CK) treatment in the PAM-treated soil. Biochar-amended treatments increased soil organic carbon (SOC) in all aggregate fractions compared to CK treatment. Soil organic amendments also decreased soil bulk density and increased total nitrogen (TN) and available phosphorus (AP). Compared to CK treatment, the maize yields in the organic fertilizer and biochar treated soil increased by 19.8 and 30.3%, respectively. These findings suggest that biochar and PAM amendments are particularly suitable for loessal soil in arid and semi-arid regions. [ABSTRACT FROM AUTHOR]

Published

2024

9. Effects of Different Rates of Sugarcane Biochar on Amelioration of Adverse Salinity Effects in Calcareous Clay Soil.

Author

Rassaei, Farzad

Subjects

*CLAY soils, *BIOCHAR, *CALCAREOUS soils, *SUSTAINABILITY, *SUGARCANE, *SUSTAINABLE agriculture, *SOIL amendments

Abstract

Soil salinity is a major challenge in agriculture, particularly in calcareous soils with high calcium carbonate levels. Biochar, produced from biomass pyrolysis, is being considered as a potential solution for mitigating salinity effects. A greenhouse pot experiment was conducted using calcareous soil from a saline field to investigate the effects of sugarcane biochar applied at different rates (0.0%, 2.0%, and 5.0%) on soil properties and wheat (Triticum aestivum L.) growth. Results showed that both Low Rate (2.0% biochar) and High Rate (5.0% biochar) treatments significantly improved soil pH, reduced electrical conductivity (EC), and increased soil organic matter (SOM) content. Plant growth indicators such as plant height, stem diameter, and leaf chlorophyll content also showed significant improvement with biochar application. High Rate had more pronounced effects compared to Low Rate. The analysis confirmed the significant effects of biochar on soil properties and plant growth, indicating its potential as a beneficial soil amendment. Sugarcane biochar has the potential to mitigate salinity stress and enhance crop productivity in calcareous soils. Further research is needed to explore the long-term effects of sugarcane biochar application and its interactions with other soil management practices in different crop systems. These findings highlight the promising role of biochar as a sustainable approach for mitigating salinity stress in agriculture and improving soil quality for crop production. The study's findings highlight the potential industrial applications of sugarcane biochar in addressing soil salinity issues prevalent in calcareous soils, particularly in agriculture. The research underscores the positive impact of biochar on soil attributes, plant growth, and nutrient availability. With its ability to improve soil pH, reduce salinity, increase soil organic matter, and enhance plant growth, sugarcane biochar emerges as a promising soil amendment for agricultural use. This presents an opportunity for industries involved in sustainable agriculture, soil management, and crop enhancement to explore the integration of biochar into their practices. Additionally, the study emphasizes the need for further research and field trials to optimize biochar application rates, assess economic feasibility, and ensure environmental sustainability. The insights gained from this study offer a pathway for industrial stakeholders to explore biochar's role in enhancing soil quality, promoting plant growth, and ensuring sustainable agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

10. Fuel Characteristics and Phytotoxicity Assay of Biochar Derived from Rose Pruning Waste.

Author

Stefanów, Julia, Sobieraj, Karolina, Hejna, Małgorzata, Pawęska, Katarzyna, and Świechowski, Kacper

Subjects

*BIOCHAR, *SOIL amendments, *PHYTOTOXICITY, *RAW materials, *ROSES, *GERMINATION

Abstract

The aim of this study was the characterization and evaluation of applicability as a soil amendment of biochar derived from rose pruning waste at different pyrolysis temperatures (200–500 °C) and process durations (20–60 min). The biochar properties were compared to the raw material. The biochars produced at 300 °C for 40 and 60 min demonstrated the best fuel properties. These variants showed high energy gain rates (77.6 ± 1.5% and 74.8 ± 1.5%, respectively), energy densification ratios (1.35 ± 0.00 and 1.37 ± 0.00, respectively), high heating values (24,720 ± 267 J × g−1 and 25,113 ± 731 J × g−1, respectively), and relative low ash contents (5.9 ± 0.5% and 7.1 ± 0.3%, respectively). Regarding fertilizer properties, such as pH value, ash content, heavy metal content, and pollutant elution, the biochars showed better qualities than the raw material. All tested biochar did not exceed the permissible values for heavy metals, including Cr, Cd, Ni, and Pb. The most optimal properties for soil amendments were noted for biochar variants of 400 °C for 40 min, 450 °C for 20 min, and 500 °C for 20 min. Generally, biochars produced at temperatures ≥400 °C did not inhibit root elongation, except for the material produced at 450 °C for 60 min (4.08 ± 23.34%). Biochars obtained at ≥300 °C showed a positive impact on seed germination (86.67 ± 18.48–100 ± 24.14%). [ABSTRACT FROM AUTHOR]

Published

2024

11. Effects of Different Soil Amendments on Growth, Yield and Nutrients Uptake of Stem Amaranth in Acidic Alluvial-and-Hill Soils in a Subtropical Area.

Author

Jahan, Israt, Hossain, Md. Shahadat, and Kashem, Md. Abul

Subjects

*ACID soils, *SOIL amendments, *NUTRIENT uptake, *AMARANTHS, *TILLAGE

Abstract

Sandy and acidic soil conditions are the major factors limiting the production of some vegetable crops in acidic soils. This study aims to examine the effect of various amendments on the growth, yield and mineral nutrients uptake of stem amaranth. Two pot experiments were conducted separately in two generic soils. Six treatments viz. T0 = control (without amendment), T1= lime, T2 = lime + wetland bottom sediment, T3 = lime + vermicompost, T4 = lime + rice straw biochar (RSB) and T5 = RSB were used for both experiments following CRD with four replications. Results revealed that plant heights (45.96 and 50.33 cm) of amaranth grown in alluvial and hill soils, respectively, were the highest in T4 treatment. Similarly, treatment T4 showed the highest fresh (118.53 and 116.11 g pot−1, respectively) and dry biomasses (16.98 and 19.54 g pot−1, respectively) for both soils. For both soils, treatment T4 resulted better nutrient uptake of N, P, K, S, Zn, Fe and Mn by edible stem, while non-amended soil gave the lowest result at all parameters. Analytical values of post-harvest soils indicated that T4 and/or T5 treatments resulted in an improvement in soil pH, organic carbon, total N, exchangeable K and extractable P, S and Zn. Treatment T3 showed elevated concentrations of extractable soils Fe and Mn. The amendment RSB combined with lime can be preferably used in strong acidic soils for cultivation of stem amaranth. [ABSTRACT FROM AUTHOR]

Published

2024

12. Combating Drought Stress Anomalies in Grain Quality of Phaseolus vulgaris: Role of Soil Amendments.

Author

Mondal, Subham C., Gogoi, Nirmali, and Nath, Dhrubajyoti

Subjects

*SOIL amendments, *FARM manure, *DROUGHTS, *PHYTIC acid, *WATER withdrawals, *COMMON bean

Abstract

Phaseolus vulgaris is one of the most widely consumed legumes across the globe. It is rich in protein, carbohydrates, fiber, bioactive compounds, and mineral contents. Occurrences of drought under changing climate have posed a challenge to the quality and quantity of the crop yield. Our study, taking Phaseolus vulgaris as a test legume, reports that as a soil amendment, biochar and farmyard manure mitigated drought-induced damage in the plant. The experiment was set up in a greenhouse with 1 m2 blocks together arranged in factorial randomized block design. Water withdrawal was done for 15 days in either vegetative or reproductive stage of the crop to simulate drought conditions. Biochar or Farmyard manure was applied at the rate of 10t ha−1 as soil amendment and each treatment was replicated thrice. Higher photosynthesis (up to 23% and 16%, respectively), leaf protein (41% and 30%, respectively), grain protein (4% and 19%, correspondingly), and in-vitro protein digestibility (60% and 254%, respectively) were noted under application of both the amendments. Grain quality in terms of protein content, in-vitro protein digestibility, and protein fractions of Phaseolus vulgaris was improved under drought due to the addition of biochar and farmyard manure. However, the application of those amendments at the rate of 10t ha−1, especially farmyard manure, had a negative impact on the antinutritional factor (phytic acid) and mineral bioavailability. Between the two amendments studied, farmyard manure proved to be more efficient in promoting the overall grain quality of P. vulgaris, but its inimical effects must be concorded. [ABSTRACT FROM AUTHOR]

Published

2024

13. Effect of spent tea waste, compost and biochar on some growth parameters and concentration of nitrogen, phosphorus and potassium in spinach (Spinacia oleracea L.) under salinity stress.

Author

Abdolahi Arshad, Mohammad, Rangzan, Nafiseh, and Nadian Ghomsheh, Habibollah

Subjects

*SPINACH, *SOIL salinity, *BIOCHAR, *EFFECT of salt on plants, *COMPOSTING, *SALINITY, *SOIL amendments, *POTASSIUM

Abstract

Salinity is a major environmental problem that adversely affects plant growth by increasing soil osmotic pressure and disrupting plant nutrition. Using organic amendments is a viable tool for reducing physiological and morphological effects of excessive soil salinity on plants. To show the impacts of tea waste, compost and biochar on nutrient status and growth parameters of spinach (Spinacia oleracea L.) raised in salinity conditions, this study has employed factorial CRD with two treatments involving soil salinity (2.5 and 8 dS m−1) and organic materials (spent tea waste (STW), spent tea waste compost (STWC) and spent tea waste biochar (STWB)) at 0 and 3% w/w in three replications. As soil salinity increased from 2.5 to 8 dS m−1, fresh weight and dry matter production decreased by 31.5% and 30.4%, respectively. Phosphorous and potassium concentrations in plant tissue also decreased significantly due to the increase in salinity. Organic amendments (except STW) due to their physicochemical properties increased the nutrients uptake and growth parameters of the plant. Compared to other amendments, biochar reduced salinity effects on plant growth more effectively, which is possibly due to its high nutrient adsorbing and water holding capacity. In saline conditions, the highest potassium to sodium ratio belonged to the biochar treatment, which was 3.22 and 2.78 times greater than spent tea waste and compost, respectively. Therefore, it was preferred to change the spent tea waste into biochar before being used as soil amendment. [ABSTRACT FROM AUTHOR]

Published

2024

14. Rhizoctonia solani disease suppression: addition of keratin-rich soil amendment leads to functional shifts in soil microbial communities.

Author

Russ, Lina, Andreo Jimenez, Beatriz, Nijhuis, Els, and Postma, Joeke

Subjects

*SOIL amendments, *RHIZOCTONIA solani, *MICROBIAL communities, *LEAD in soils, *AGRICULTURE

Abstract

Promoting soil suppressiveness against soil borne pathogens could be a promising strategy to manage crop diseases. One way to increase the suppression potential in agricultural soils is via the addition of organic amendments. This microbe-mediated phenomenon, although not fully understood, prompted our study to explore the microbial taxa and functional properties associated with Rhizoctonia solani disease suppression in sugar beet seedlings after amending soil with a keratin-rich waste stream. Soil samples were analyzed using shotgun metagenomics sequencing. Results showed that both amended soils were enriched in bacterial families found in disease suppressive soils before, indicating that the amendment of keratin-rich material can support the transformation into a suppressive soil. On a functional level, genes encoding keratinolytic enzymes were found to be abundant in the keratin-amended samples. Proteins enriched in amended soils were those potentially involved in the production of secondary metabolites/antibiotics, motility, keratin-degradation, and contractile secretion system proteins. We hypothesize these taxa contribute to the amendment-induced suppression effect due to their genomic potential to produce antibiotics, secrete effectors via the contractile secretion system, and degrade oxalate—a potential virulence factor of R. solani —while simultaneously possessing the ability to metabolize keratin. [ABSTRACT FROM AUTHOR]

Published

2024

15. Si-Humate as soil ameliorant to improve the properties of acid sulfate soil, growth, and rice yield.

Author

Maftu'ah, Eni, Saleh, Muhammad, Sulaeman, Yiyi, Napisah, Khairatun, Agustina, Rusmila, Mukhlis, Mukhlis, Anwar, Khairil, Ningsih, Rina Dirgahayu, Masganti, Masganti, Maharani, Puspita Harum, Asikin, Syaiful, Karolinoerita, Vicca, Wakhid, Nur, Hayati, Afiah, and Lestari, Yuli

Subjects

*ACID sulfate soils, *SOIL amendments, *RICE hulls, *WATER hyacinth, *RICE, *SOILS

Abstract

Soil ameliorants play a crucial role in enhancing soil fertility and rice (Oryza sativa L.) production in acidsulfate soils. This research aims to study the impact of Si-humic ameliorants on soil chemical properties, plant growth, Fe levels, and rice production in acid-sulfate soil. The experiments were conducted at the Laboratory and Greenhouse of the Indonesia Swampland Agricultural Research Institute. The greenhouse experiment adopted a factorial RCBD with Factor 1 representing the ameliorant formula type: 100% lime (F0), 30% commercial humate+30% rice husk ash+40% lime (F1), 30% water hyacinth humate+0% rice husk ash+40% lime (F2), 30% water hyacinth humate+30% rice husk biochar+40% lime (F3), 30% commercial humate+30% rice husk biochar+40% lime (F4), and control without ameliorant. Factor 2 represents dosage of soil ameliorant: 0, 1, 2, and 4 t ha-1. Observations included soil properties such as pH, exchangeable Fe, available P, plant growth, Fe toxicity, yield, and yield components. Silicon-humic soil ameliorant demonstrated the ability to enhance soil pH from 3.16 to 3.63, available P from 6.12 to 30.16 mg kg-1, and decrease Fe 690 to 371 mg kg-1. Specifically, the F3 Si-humate formulation alleviated Fe toxicity, enhanced P availability, promoted rice growth, and improved yield. The application of 4 t ha-1 Sihumate F3 had the best effect in increasing grain yield by 4.22 g pot-1 compared to the control. The application of Si-humate F3 not only improved soil quality and increased rice yields but also reduced the need for lime, contributing to the potential maintenance of soil health. [ABSTRACT FROM AUTHOR]

Published

2024

16. Residual Effect of Compost and Biochar Amendment on Soil Chemical, Biological, and Physical Properties and Durum Wheat Response.

Author

Leogrande, Rita, Vitti, Carolina, Castellini, Mirko, Garofalo, Pasquale, Samarelli, Ignazio, Lacolla, Giovanni, Montesano, Francesco Fabiano, Spagnuolo, Matteo, Mastrangelo, Marcello, and Stellacci, Anna Maria

Subjects

*SOIL amendments, *DURUM wheat, *BIOCHAR, *CROPPING systems, *SOIL management, *COMPOSTING

Abstract

The residual effect of compost and biochar amendment on soil properties and durum wheat response was evaluated under field conditions in a Mediterranean environment. The treatments compared in a randomized complete block experimental design with three replications were: mineral fertilizer (100 kg N ha−1), compost applied at the rate of 25 Mg ha−1, biochar applied at the rates of 10 and 30 Mg ha−1, unfertilized control. Wheat was the second crop included in a sorghum–wheat cropping system and did not receive fertilizer supply. A hierarchical statistical analysis was carried out to investigate how different treatments could impact the cropping system performance. The findings highlight the significant influence of soil properties, particularly total N, WEOC, and TOC, on wheat and protein yield. One year after the amendment and fertilizer application, compost and biochar significantly increased soil total organic carbon content. The highest soil water extractable organic carbon was found with the compost application (76.9 mg kg−1), whereas the lowest value (50 mg kg−1) was with the highest rate of biochar. Soil respiration rates and hydraulic properties were not affected by the investigated treatments. This behavior is probably related to the short experimental duration and to the silty clayey soil texture. Significant correlations were observed between bulk density and water content at pressure heads in the −20 and −100 cm range; this range accounts for the effect of soil macro and mesopores. Multiple linear regression analysis revealed strong predictive power for grain (R2_adj = 0.78; p < 0.001) and protein yield (R2_adj = 0.77; p < 0.001). The highest grain yield (3.36 Mg ha−1) was observed with compost, and the lowest (2.18 Mg ha−1) with biochar at a rate of 30 Mg ha−1. These findings lay the basis for understanding how different soil amendment management may impact soil quality and wheat performance, even in consideration of climate change. [ABSTRACT FROM AUTHOR]

Published

2024

17. Effect of Oil Palm Kernel Shell Biochar and Inorganic Fertilizer on Soil Microbial Biomass and Population in the Humid Tropics.

Author

Halmi, M. Farid A. and Simarani, Khanom

Subjects

*BIOCHAR, *OIL palm, *MICROORGANISM populations, *SOIL amendments, *ACID soils, *LYOTROPIC liquid crystals

Abstract

Soil amendment with biochar from oil palm biomass has been found to improve the quality of the infertile weathered soils and enhance crop productivity in the humid tropics. Meanwhile, the field information on microbial responses to oil palm-derived biochar application and its residual effect in acidic tropical soils is still limited. A field study was carried out over three cropping cycles of sweet corn on a Haplic Acrisol of Peninsular Malaysia. The soil was amended once with oil palm kernel shell (OPKS) biochar before the first cropping cycle, with or without inorganic fertiliser. Soil samples were taken at each harvesting stage and analysed for soil pH, cation exchange capacity (CEC), organic C, total N, available P, microbial biomass (C (MBC), N (MBN), and P (MBP)). Microbial biomass ratios (MBC : MBN, MBC : MBP) were calculated. The total bacterial and fungal populations were quantified from soil genomic DNA, employing qPCR amplification of the 16S rDNA and ITS gene. The sole application of biochar and its combined application with fertiliser, increased soil pH, CEC, organic C and N. Coapplication of OPKS biochar and NPK fertiliser hindered N loss in the second cycle. The bacterial and fungal abundance was stimulated following biochar treatment majorly due to the elevation of soil pH and CEC. The ratio of MBC : MBN had a significant negative correlation with N, signifying that this ratio could reflect soil N content and be used as a soil fertility indicator. [ABSTRACT FROM AUTHOR]

Published

2024

18. Hydrological properties of biochar-amended expansive soil under dynamic water environment and biochar-amended soil's application in green roofs.

Author

Li, Muyang, Garg, Ankit, Huang, Shan, Jiang, Mingjie, Mei, Guoxiong, Liu, Jiaqin, and Wang, Hao

Subjects

*SWELLING soils, *GREEN roofs, *ENVIRONMENTAL soil science, *PORE size distribution, *SOIL amendments

Abstract

Biochar is widely used as a soil amendment in green roofs because it can increase the soil's water-holding capacity, inhibit cracking, and provide nutrients for vegetation. The interaction mechanism between biochar and expansive soil is a significant factor in the performance of green roofs. However, research mainly focused on the hydrological scale (i.e. runoff regulation and rainwater storage), and there is a lack of research on the hydrological properties (i.e. hysteresis of soil–water characteristic curves, changes in soil pore size and pore distribution, formation and development of cracks and swelling–shrinking characteristics) of biochar-amended expansive soils under dynamic water environment. This test was conducted out on soil columns with expansive soil and 5% (by mass) biochar-amended under 5 drying–wetting cycles. The results showed that within the range of water content suitable for plant growth (i.e. between the anaerobic point and wilting point), the hysteresis area of soil–water characteristic curves of the amended soil is smaller than the bare soil at each drying–wetting cycle. The addition of biochar changes the pore size distribution of the soil, reduces the pore size and swelling–shrinking characteristics of the expansive soil, and inhibits the development of cracks. Therefore, the addition of biochar significantly attenuates the hysteresis characteristics of the soil–water characteristic curves of expansive soils, which may improve the stability of the hydraulic performance of green roofs. The results contribute to the understanding of the physicochemical and water properties of biochar-amended expansive soil and provide theoretical support for the application of biochar to green roofs. [ABSTRACT FROM AUTHOR]

Published

2024

19. Humalite enhances the growth, grain yield, and protein content of wheat by improving soil nitrogen availability and nutrient uptake.

Author

Rathor, Pramod, Rouleau, Vianne, Gorim, Linda Yuya, Chen, Guanqun, and Thilakarathna, Malinda S.

Subjects

*NUTRIENT uptake, *NITROGEN in soils, *SEED proteins, *AGRICULTURE, *WHEAT proteins, *POTASSIUM, *GRAIN yields, *SOIL amendments

Abstract

Background: The application of synthetic chemical inputs in current agricultural practices has significantly increased crop production, but their use has caused severe negative consequences on the environment. Humalite is an organic soil amendment that is rich in humic acid and found in large deposits in southern Alberta, Canada. Humic products can enhance nutrient uptake and assimilation in plants by reducing nutrient losses and enhancing bioavailability in the soil. Aim: Here, we evaluated the effects of different humalite rates in the presence of nitrogen, phosphorus, potassium (NPK) at recommended rates on soil nitrogen availability, wheat growth, grain yield, seed nutritional quality, and nitrogen use efficiency (NUE) under controlled environmental conditions. Methods: A series of studies were conducted by applying five different rates of humalite (0, 200, 400, 800, and 1600 kg ha−1) with NPK at recommended rates. Soil nitrogen availability and shoot and root growth parameters were recorded at flowering stage. NUE was calculated based on the grain yield at maturity stage. Results: Plants grown in the presence of humalite augmented root morphological parameters (root length, volume, and surface area), plant biomass (shoot and root), and nutrient uptake (N, P, K, and S) compared to the plants supplied with recommended fertilizer alone. Furthermore, humalite application significantly increased grain yield (14%–19%), seed protein content (23%–30%), and NUE (14%–60%) compared to the fertilizer application alone. Conclusion: These findings suggest that humalite can be used as an organic soil amendment to reduce synthetic fertilizer application and improve plant growth and yield while enhancing fertilizer use efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

20. Organic amendments enhance transpiration efficiency of corn plants via changes in soil microbial abundance and leaf hormones.

Author

Wang, Xiaojuan, Sale, Peter, Wood, Jennifer L., Reddy, Priyanka, Franks, Ashley E., Clark, Gary, Jin, Jian, Rochfort, Simone, Hunt, James, and Tang, Caixian

Subjects

*POULTRY litter, *LIGNITE, *INDOLEACETIC acid, *CORN, *BACILLUS (Bacteria), *SOIL amendments

Abstract

Background and Aims: The use of organic amendments improves soil functioning and thus crop productivity. Our previous studies have shown that the banding of organic amendments increases the transpiration efficiency (TE) of wheat plants, but the underlying mechanism remained unclear. This study aims to determine whether and how the organic amendments can increase the TE of corn plants (Zea mays L.). Methods: The effects of nutrient-enriched poultry litter, compost and brown coal on TE were compared with inorganic fertilizer. Corn plants were grown in Chromosol topsoil in pots for 50 days. Results: The poultry litter and compost but not brown coal, increased the TE of corn plants by 25% and 14%, respectively (P < 0.05), compared to inorganic fertilizer. At the leaf level, poultry litter and compost also increased the instantaneous TE due to either decreased transpiration or increased instantaneous CO2 assimilation rates. The increased TE at the plant level was closely associated with increased abundances of soil fungi, bacteria and bacteria in genus Bacillus. Meanwhile, there were increases in the concentrations of leaf hormones abscisic acid (ABA) (> 50%), methyl jasmonate (JA) (> 80%) and indole acetic acid (IAA). Conclusion: Organic amendments enhanced the population of plant beneficial soil microorganisms such as those in the Bacillus genus, which likely led to the increased biosynthesis of leaf hormones ABA and JA, resulting in stomatal close, reduced total transpiration and increased transpiration efficiency of the corn canopy. [ABSTRACT FROM AUTHOR]

Published

2024

21. Organic amendments enhanced the humification degree in soil formation of bauxite residue.

Author

Guo, Ying, Zhang, Xianchao, Qin, Xinfeng, Jiang, Yifan, Zhu, Feng, and Xue, Shengguo

Subjects

*POULTRY manure, *SOIL formation, *HUMIFICATION, *BAUXITE, *SOIL amendments, *CARBON cycle, *CORN straw, *FOURIER transform infrared spectroscopy

Abstract

Purpose: Revegetation of bauxite residue disposal areas is an effective disposal strategy for large-scale in-situ disposal and reduction of environmental risk. The application of organic amendments is an effective method of increasing the organic carbon content of residue. Humification of bauxite residue by different types of organic amendments in the synergistic effect of Ca-containing solid waste was investigated. Methods: 100-day incubation experiments using Fourier Transform Infrared Spectroscopy (FTIR), Excitation-Emission Matrix (EEM) fluorescence, Ultraviolet–Visible (UV–Vis) spectroscopy, Illumina high-throughput sequencing technology for the analysis of bauxite residue treated with different organic amendments. The organic amendments treatments applied included corn straw (BGS), nitrohumic acid (BGH), and poultry manure (BGM), and the pretreated residue (desulphurization gypsum mixed with bauxite residue) was the BG. Results: The composition and parameters of humic substances of bauxite residues with different treatments was ranked as BG < BGM < BGS < BGH. BGS treatment has the highest humification rate. For carbon cycle-related enzymes, enzyme activities of corn straw treatment were higher, indicating that straw addition was more intense on carbon turnover. Combined with microbial activity, the manure had sufficient nutrients, which was conducive to microbial growth and reproduction. Redundancy analysis (RDA) and two-factor correlation network showed that microorganisms influence humification characteristics by secreting carbon cycle-related enzymes. Conclusions: The nitrohumic acid treatment had a higher humification degree but limited microbial activity, whilst corn straw treatment had a wide potential for humification and enzyme activity. Desulfurization gypsum and corn straw have novel application prospects on ecological rehabilitation at disposal areas. Highlights: The effects of different organic amendments in bauxite residue from two dimensions of humification and microbial activity were evaluated. Organic amendments significantly changed the humification characteristics of the residues in both solid and liquid phases. Corn straw addition was more intense on enzymes related to carbon cycle and has a wide humification potential in bauxite residue. Desulfurization gypsum and corn straw have novel application prospects on ecological rehabilitation at disposal areas. [ABSTRACT FROM AUTHOR]

Published

2024

22. Customized plant microbiome engineering for food security.

Author

Batool, Maria, Carvalhais, Lilia C., Fu, Brendan, and Schenk, Peer M.

Subjects

*MICROBIAL inoculants, *FOOD security, *CROP yields, *SOIL amendments, *PLANT-microbe relationships, *CULTIVARS

Abstract

Optimizing beneficial plant–microbe interactions can significantly enhance plant growth and resilience, which may be achievable through a targeted step-by-step process using customized microbiome engineering. 'Plant/microbe-friendly' soils can be prepared through traditional and targeted soil amendments to increase microbial diversity and soil fertility to suit specific plant cultivation needs. 'Microbe-friendly' plants and genotypes should be chosen because different crops and varieties vastly differ in their ability to benefit from microbes. 'Plant-friendly' microbiomes can be generated by applying suitable functional microbial inoculants with optimal formulations and supportive substrates. Microbiome breeding, microbiome transplanting, and the use of artificial microbial consortia to fill microbiome functional deficiencies are promising emerging areas that warrant further validation. Plant microbiomes play a vital role in promoting plant growth and resilience to cope with environmental stresses. Plant microbiome engineering holds significant promise to increase crop yields, but there is uncertainty about how this can best be achieved. We propose a step-by-step approach involving customized direct and indirect methods to condition soils and to match plants and microbiomes. Although three approaches, namely the development of (i) 'plant- and microbe-friendly' soils, (ii) 'microbe-friendly' plants, and (iii) 'plant-friendly' microbiomes, have been successfully tested in isolation, we propose that the combination of all three may lead to a step-change towards higher and more stable crop yields. This review aims to provide knowledge, future directions, and practical guidance to achieve this goal via customized plant microbiome engineering. Plant microbiomes play a vital role in promoting plant growth and resilience to cope with environmental stresses. Plant microbiome engineering holds significant promise to increase crop yields, but there is uncertainty about how this can best be achieved. We propose a step-by-step approach involving customized direct and indirect methods to condition soils and to match plants and microbiomes. Although three approaches, namely the development of (i) 'plant- and/or microbe-friendly' soils, (ii) 'microbe-friendly' plants, and (iii) 'plant-friendly' microbiomes, have been successfully tested in isolation, we propose that the combination of all three may lead to a step-change towards higher and more stable crop yields. This review aims to provide knowledge, future directions, and practical guidance to achieve this goal via customized plant microbiome engineering. [ABSTRACT FROM AUTHOR]

Published

2024

23. Sugarcane Trash Biochar Released Least Extractable Phosphorus in an Acidic Incubated Soil.

Author

Hridi, Subrina Jaman, Islam, Md. Shoffikul, and Kashem, Md. Abul

Subjects

*ACID soils, *SUSTAINABLE agriculture, *BIOCHAR, *PHOSPHATE fertilizers, *SOIL amendments

Abstract

Recycling of phosphorus (P) from feedstocks to soils can provide sustainability in agriculture. In our incubation study, we investigated the effects of adding cow manure-derived vermicompost (CMV), cow manure (CM), sugarcane trash biochar (STB), and triple super phosphate (TSP) to extractable P in a sandy loam soil. P was added to the soil at rates of 0, 50, 100, 200, and 300 mg kg−1 based on their total P contents. The amended soils were incubated for 1, 4, 8, and 16 weeks (wk) at room temperature and extractable P samples were measured (by water, Olsen, Mehlich-3 and Bray and Kurtz) and soil pH was monitored. After 1 wk of incubation, the extractable P values were 1.4 mg kg−1 with STB at the smallest while the highest was 79 mg kg−1 with TSP. The corresponding P values in the CMV and CM amended soils were 33 mg kg−1 and 31 mg kg−1. The reductions of extractable P from 1 to 16 wks of incubation were 40%, 35%, and 80% in the CMV, CM and TSP amended soils, respectively, while they increased from 1.43 mg kg−1 to 6.05 mg kg−1 ((320%) in the STB amended soil. Among the amendments, a significant positive relationship was observed between extractable P and the pH in soils amended with STB. The findings revealed that varying P extractability in soils depends on amendment types and duration of incubation. Sugarcane trash biochar did not exhibit an ability to substitute inorganic P fertilizer for assessing bioavailable P. [ABSTRACT FROM AUTHOR]

Published

2024

24. ICT4Agroecology part II: outcomes for maize production systems.

Author

Hilbeck, Angelika, Tisselli, Eugenio, Crameri, Simon, Sibuga, Kallunde P., Constantine, John, Shitindi, Mawazo J., Kilasara, Method, Churi, Ayubu, Sanga, Camillius, Kihoma, Luambano, Brush, Gladness, Stambuli, Fadhili, Mjunguli, Rainard, Burnier, Blaise, Maro, Janet, Mbele, Angelina, Hamza, Suleyman, Kissimbo, Mary, and Ndee, Ayoub

Subjects

*INTERCROPPING, *CORN, *BIOLOGICAL pest control, *CORN seeds, *SOIL amendments, *FARMERS, *CATCH crops, *SOIL fertility

Abstract

Agroecology is gaining increased attention by experts and global organizations; however, it's practical application in the field remains understudied, particularly in developing countries. Here, we aimed to evaluate common agroecological practices at three sites in Tanzania, including organic soil amendments, intercropping, and biological pest control – individually, in pairs, or in three-way combinations at each site. Information Communication Technology tools – the AgroEco Research and AgroEco Analysis application – were used for data gathering & storage and data visualization & statistical analysis, respectively. We found that high maize kernel weights (as proxy for yield) can be obtained from nutrient-poor soils specifically when grown with a combination of organic soil amendments and intercropped with legumes – ranging from 3 to 4.5 t/ha (with a maximum of 7 t/ha on one occasion) and exceeding national maize yields of 1–2 t/ha in Tanzania. However, intercropping and biological pest control individually and in combination did not affect maize yield. Under flood or drought conditions, only plots with soil fertility amendments produced some harvestable maize kernels. Our results provide a substantial reference for recommending and advocating agroecological methods to smallholder farmers, farmer training organizations, and policy makers. [ABSTRACT FROM AUTHOR]

Published

2024

25. Evaluation of Biochar as an Amendment for the Removal of Metals, Nutrient, and Microplastics in Bioretention Systems.

Author

Struzak, Maya, Poor, Cara, Wolfand, Jordyn, and Radke, Abigail

Subjects

*BIOCHAR, *BIOSWALES, *MICROPLASTICS, *SOIL amendments, *METALS, *COPPER, *PLANT-soil relationships

Abstract

Bioretention systems use plants and soil media to treat pollutants in stormwater. Biochar can be an effective amendment to bioretention soil media for removing pollutants due to its adsorption properties. This study evaluates biochar as an amendment to bioretention soil media for the removal of contaminants in stormwater. Columns with varying ratios of biochar to bioretention soil media (0%, 25%, and 50% biochar) were tested to evaluate the removal efficiencies of copper, zinc, phosphorus, nitrogen, and microplastics from stormwater. Five trials were conducted with stormwater collected from parking lot runoff. Results show that the addition of biochar in bioretention systems improves the removal efficiency of zinc (average of 79% in columns with 50% biochar compared to 54% in columns without biochar) and copper (average of 73% in columns with 50% biochar compared to 25% in columns without biochar). Stormwater effluent from the biochar-amended columns also had significantly lower turbidity (21 NTU) than that of the control columns (58 NTU). Consistent leaching of nitrogen and phosphorus species was evident in the control as well as the biochar-amended columns, with average removal efficiencies of −1,114% for total nitrogen and −703% for total phosphorus. Microplastics were effectively removed by all columns, regardless of biochar amendment, with an average removal of 86%. This study indicates that biochar has the potential to reduce metal concentrations in stormwater when used as an amendment to bioretention systems but has a limited impact on nutrients and microplastics. [ABSTRACT FROM AUTHOR]

Published

2024

26. Investigating the Effects of Various Soil Amendments on Forages Production in the Field.

Author

Burezq, Hana'a

Subjects

*SOIL amendments, *SOIL conditioners, *WATER conservation, *PLANT residues, *CROP yields

Abstract

An initial investigation into the utilization of recycled plant and animal residues as soil amendments (SAs), including compost, biochar, and soil conditioner, was conducted using alfalfa crops. This study evaluated the impact of SAs on alfalfa seed germination, resulting in an 87% germination rate for biochar, 82% for soil conditioner, and 82% for compost. In comparison, untreated seeds displayed a 78% germination rate. After successful germination, the SAs were employed to enhance soil health, with a focus on water conservation and increased forage yield. The study used sandy-textured soil with moderate alkalinity, very slight salinity, slight calcareousness, and high permeability. The germination trial confirmed that SAs usage did not hinder seed germination, even for salt-sensitive crops like alfalfa. Two field experiments were carried out in Al-Wafra, using different application rates of compost, biochar, and soil conditioner at 5, 7.5, and 10 tons per hectare. The results highlighted the positive impact of SAs application on increasing forage production, with varying degrees of enhancement, and confirmed a 40% reduction in water usage compared to treatment without SAs but under 100% irrigation (100% ETc). In conclusion, SAs show promising potential for local forages intensification and water conservation. [ABSTRACT FROM AUTHOR]

Published

2024

27. Promoting success in thin layer sediment placement: effects of sediment grain size and amendments on salt marsh plant growth and greenhouse gas exchange.

Author

Wilburn, Brittany P., Raper, Kirk, Raposa, Kenneth B., Gray, Andrew B., Mozdzer, Thomas J., and Watson, Elizabeth B.

Abstract

Thin layer sediment placement (TLP) is used to build elevation in marshes, counteracting effects of subsidence and sea level rise. However, TLP success may vary due to plant stress associated with reductions in nutrient availability and hydrologic flushing or through the creation of acid sulfate soils. This study examined the influence of sediment grain size and soil amendments on plant growth, soil and porewater characteristics, and greenhouse gas exchange for three key U.S. salt marsh plants: Spartina alterniflora (synonym Sporobolus alterniflorus), Spartina patens (synonym Sporobolus pumilus), and Salicornia pacifica. We found that bioavailable nitrogen concentrations (measured as extractable NH4+‐N) and porewater pH and salinity were inversely related to grain size, while soil redox was more reducing in finer sediments. This suggests that utilizing finer sediments in TLP projects will result in a more reduced environment with higher nutrient availability, while larger grain sized sediments will be better flushed and oxygenated. We further found that grain size had a significant effect on vegetation biomass allocation and rates of gas exchange, although these effects were species‐specific. We found that soil amendments (biochar and compost) did not subsidize plant growth but were associated with increases in soil respiration and methane emissions. Biochar amendments were additionally ineffective in ameliorating acid sulfate conditions. This study uncovers complex interactions between sediment type and vegetation, emphasizing the limitations of soil amendments. The findings aid restoration project managers in making informed decisions regarding sediment type, target vegetation, and soil amendments for successful TLP projects. [ABSTRACT FROM AUTHOR]

Published

2024

28. Biochar alleviated the toxic effects of microplastics-contaminated geocarposphere soil on peanut (Arachis hypogaea L.) pod development: roles of pod nutrient metabolism and geocarposphere microbial modulation.

Author

Liyu Yang, Haiyan Liang, Qi Wu, and Pu Shen

Subjects

*PEANUTS, *POISONS, *BIOCHAR, *ARACHIS, *MICROBIAL metabolism, *SOIL amendments

Abstract

BACKGROUND: The accumulation of microplastics in agricultural soil poses a threat to the sustainability of agriculture, impacting crop growth and soil health. Due to the geocarpy feature of peanut, geocarposphere soil environment is critical to pod development and its nutritional quality. While the effects of microplastics in the rhizosphere have been studied, their impact on peanut pod in the geocarposphere remains unknown. Biochar has emerged as a potential soil agent with the ability to remediate soil contamination. However, the mechanisms of biochar in mitigating the toxic effects of microplastics-contaminated geocarposphere soil on peanut pod development remain largely unexplored. RESULTS: We evaluated the peanut pod performance and microbiome when facing microplastics contamination and biochar amendment in geocarposphere soil. The results showed that microplastics present in geocarposphere soil could directly enter the peanut pod, cause pod developmental disorder and exert adverse effects on nutritional quality. Aberrant expression of key genes associated with amino acid metabolism, lipid synthesis, and auxin and ethylene signaling pathways were the underlying molecular mechanisms of microplastics-induced peanut pod developmental inhibition. However, these expression abnormalities could be reversed by biochar application. In addition, peanut geocarposphere microbiome results showed that biochar application could restore the diversity of microbial communities inhibited by microplastics contamination and promote the relative abundance of bacteria correlated with pathogen resistance and nitrogen cycle of geocarposphere soil, further promoting peanut pod development. CONCLUSION: This study demonstrated that biochar application is an effective strategy to mitigate the toxic effects of microplastics-contaminated geocarposphere soil on pod development and nutritional quality. [ABSTRACT FROM AUTHOR]

Published

2024

29. Roles of biochars' properties in their water-holding capacity and bound water evaporation: quantitative importance and controlling mechanism.

Author

Zhang, Huiying, Cheng, Yue, Zhong, Yinhua, Ni, Jinzhi, Wei, Ran, and Chen, Weifeng

Subjects

*BIOCHAR, *SOIL amendments, *WHEAT straw, *AGRICULTURE, *SOIL moisture, *HYDROGEN bonding

Abstract

Important properties of biochar as an effective soil amendment are its high water-holding capacity (WHC) and inhibition of water evaporation. However, the mechanism and the importance of biochar properties in controlling its own WHC and bound water evaporation remain little known. In this study, wheat straw and pine sawdust biochars were pyrolyzed in N2-flow, CO2-flow, and air-limitation environments at 300–750 ℃, and a series of the produced biochars' properties were characterized to explore the dominant controlling factors of their WHC and bound water evaporation. The results have shown that with the increasing contents of hydrogen, nitrogen, and oxygen as well as such ratios as H/C, and (O + N)/C, WHC of the biochars was also increasing while the evaporation of biochar-bound water was decreasing. With an increase in the other studied factors, such as carbon content, pH, and specific surface area (SSA), WHC of the biochars was decreasing, and the evaporation of biochar-bound water was increasing. That was connected with the fact that biochar-nitrogen was mainly in pyridinic and pyrrolic forms, while oxygen was in the form of C = O and C–O bonds. These forms of nitrogen and oxygen could be the receptors of hydrogen bonds to link to H2O molecules. Aliphatic hydrogen with a weak positive charge could be a donor of hydrogen bonds to link to H2O molecules. However, high carbon content, as well as high SSA, indicated more exposed aromatic carbon (hydrophobic sites) that could suppress the binding of H2O molecules. Additionally, high pH indicated that H2O molecules were dominated by OH–, which generated strong electrostatic repulsion with the negatively charged nitrogen- and oxygen-containing groups of biochar. It was also shown that the nitrogen-containing groups played a more important role (importance – 0.31) in WHC of the biochar than other parameters, including carbon, oxygen, hydrogen, ash contents, pH, SSA (importance from 0.02 to 0.09). Nitrogen, oxygen, and carbon contents had the most important influence on the evaporation of biochar-bound water in all studied factors. Furthermore, wheat straw biochar produced at low pyrolysis temperatures in N2 atmosphere (with high nitrogen and oxygen contents) had the highest WHC and the lowest evaporation of biochar-bound water. Consequently, it can be suggested that biochar rich in nitrogen can be an effective water retention agent and can improve agricultural soil moisture. Highlights: Nitrogen-containing groups (pyridinic and pyrrolic nitrogen) played a crucial role in the improvement of biochar water-holding capacity. Nitrogen- and oxygen-containing groups inhibited the evaporation of biochar-bound water. Biochar rich in nitrogen and oxygen may be an effective water retention agent to maintain soil moisture. [ABSTRACT FROM AUTHOR]

Published

2024

30. Insight of Cadmium Solidification by Mineral‐Based Soil Conditioner.

Author

Liu, ShanKe, Liu, Jianming, Liu, Yanhong, and Yuan, Yuan

Subjects

*SOIL conditioners, *SOLIDIFICATION, *SOIL remediation, *SOIL amendments, *CADMIUM

Abstract

In response to the environmental concerns posed by cadmium (Cd) contamination, the application of nano‐submicron mineral‐based soil conditioner (MSC) as a potential soil amendment has garnered interest due to its promising Cd mitigation properties. In this study, we aimed to investigate the solidification capacity and mechanism of Cd in MSC and examine the phase and morphology changes following solidification. Systematic experiments were conducted to assess the solidification capacity of MSC for Cd, revealing an impressive efficiency of nearly 100 % even at Cd concentrations of approximately 800 mg/L. The solidification efficiency was found to be positively correlated with the pH value, significantly declining as the environment shifted from pH>7 to pH<7. Notably, under alkaline conditions (pH>7), Cd solidification in MSC was primarily attributed to the Cd‐OH complex formed on the surface of MSC and aided by cation‐exchange reaction. In contrast, under acidic conditions (pH<7) and exposure to extreme Cd concentrations, Cd(OH)Cl precipitation became the dominant mechanism for solidification. Interestingly, the presence of KCdCl3, a water‐soluble phase, did not significantly contribute to the overall solidification efficiency. These findings provide valuable insights into the solidification mechanism of Cd in MSC and offer potential implications for soil remediation efforts targeting Cd contamination. [ABSTRACT FROM AUTHOR]

Published

2024

31. Effect of silicon nanoparticle-based biochar on wheat growth, antioxidants and nutrients concentration under salinity stress.

Author

Gill, Sidra, Ramzan, Musarrat, Naz, Gul, Ali, Liaqat, Danish, Subhan, Ansari, Mohammad Javed, and Salmen, Saleh H.

Subjects

*EFFECT of salt on plants, *BIOCHAR, *SALINITY, *SOIL amendments, *SILICON, *ABIOTIC stress, *WHEAT

Abstract

Globally, salinity is an important abiotic stress in agriculture. It induced oxidative stress and nutritional imbalance in plants, resulting in poor crop productivity. Applying silicon (Si) can improve the uptake of macronutrients. On the other hand, using biochar as a soil amendment can also decrease salinity stress due to its high porosity, cation exchange capacity, and water-holding capacity. That's why the current experiment was conducted with novelty to explore the impact of silicon nanoparticle-based biochar (Si-BC) on wheat cultivated on salt-affected soil. There were 3 levels of Si-BC, i.e., control (0), 1% Si-BC1, and 2.5% Si-BC2 applied in 3 replicates under 0 and 200 mM NaCl following a completely randomized design. Results showed that treatment 2.5% Si-BC2 performed significantly better for the enhancement in shoot and root length, shoot and root fresh weight, shoot and root dry weight, number of leaves, number of tillers, number of spikelets, spike length, spike fresh and dry weight compared to control under no stress and salinity stress (200 mM NaCl). A significant enhancement in chlorophyll a (~ 18%), chlorophyll b (~ 22%), total chlorophyll (~ 20%), carotenoid (~ 60%), relative water contents (~ 58%) also signified the effectiveness of treatment 2.5% Si-BC2 than control under 200 mM NaCl. In conclusion, treatment 2.5% Si-BC2 can potentially mitigate the salinity stress in wheat by regulating antioxidants and improving N, K concentration, and gas exchange attributes while decreasing Na and Cl concentration and electrolyte leakage. More investigations at the field level are recommended for the declaration of treatment 2.5% Si-BC2 as the best amendment for alleviating salinity stress in different crops under variable climatic conditions. [ABSTRACT FROM AUTHOR]

Published

2024

32. Effect of biological sewage sludge and its derived biochar on accumulation of potentially toxic elements by corn (Zea mays L.).

Author

Namdari, Maryam, Soleimani, Mohsen, Mirghaffari, Nourollah, and Kharrazi, Seyyedeh Maryam

Subjects

*SEWAGE sludge, *SOIL pollution, *BIOCHAR, *CORN, *ACTIVATED sludge process, *SOIL amendments, *PLANT shoots, *COPPER

Abstract

The land application of sewage sludge can cause different environmental problems due to the high content of potentially toxic elements (PTEs). The objective of this study was to compare the effect of urban biological sewage sludge (i.e. the waste of activated sludge process) and its derived biochar as the soil amendments on the bioavailability of PTEs and their bioaccumulation by corn (Zea mays L.) under two months of greenhouse conditions. The soil was treated by adding biochar samples at 0 (control), 1, 3, 5% w/w. The diethylenetriamine pentaacetic acid (DTPA)-extractable concentrations of PTEs including Zn, Pb, Cd, Cr, Ni, Fe, and Cu in soil and their accumulation by plant shoot and root were measured. Conversion of the biological sewage sludge into the biochar led to decrease the PTEs bioavailability and consequently decreased their contents in plant tissues. The DTPA extractable metal concentrations of produced biochar in comparison to the biological sewage sludge reduced 75% (Cd), 65% (Cr), 79% (Ni and Pb), 76% (Zn), 91% (Cu) and 88% (Fe). Therefore, the content of Ni, Fe, Zn and Cd in corn shoot was decreased 61, 32, 18 and 17% respectively in application of 5% biochar than of raw sewage sludge. Furthermore, the application of 5% biochar enhanced the physiological parameters of the plants including shoot dry weight (twice) and wet weight (2.25 times), stem diameter (1.70 times), chlorophyll content (1.03 times) in comparison to using 5% raw sewage sludge. The results of the study highlight that application of the biochar derived from urban biological sewage sludge in soil could decrease the risk of PTEs to the plant. [ABSTRACT FROM AUTHOR]

Published

2024

33. The Ameliorating Effect of Alkaline Industrial Byproducts in the Presence of Exogenous Low-Molecular-Weight Organic Acids on an Acidic Brown Soil from Jiaodong Peninsula of China.

Author

Shen, Yuwen, Liu, Ping, Lin, Haitao, Chen, Haining, Li, Yuxiao, Li, Guodong, Li, Mingli, Gao, Wensheng, Ma, Zheng, Chang, Shourui, and Yan, Xuchun

Subjects

*ACID soils, *ORGANIC acids, *SOIL respiration, *SOIL acidity, *SOIL amendments, *SUCCINIC acid, *MAGNESIUM alloys

Abstract

It has been proposed that the quality of acidic soils can be improved in the presence of alkaline byproduct amendments containing silicon (Si), calcium (Ca), magnesium (Mg), and potassium (K). In the present study, we aimed to explore the effect of byproduct amendments on ameliorating acidic soil in Jiaodong Peninsula of China in the existence of different types of low-molecular-weight organic acids (LOAs, such as malic acid, citric acid, oxalic acid, and succinic acid) that are usually excreted by plant roots. Therefore, a 60-day incubation test was carried out to assess the effect of byproduct amendments and LOAs on soil physicochemical properties, soil available Mg and Ca, cation exchange capacity (CEC), soil respiration, and enzyme activities. The results showed that in the presence of LOAs, the byproduct amendments could still increased the soil pH and decreased the soil exchangeable acid and exchangeable Al3+. Compared with the control group (CK), all byproduct amendment-containing treatments could increase soil available Mg and Ca, soil CEC, soil respiration, and soil sucrase (S-SC) activity. The addition of byproduct amendments could significantly improve the chemical and biological properties of the acidic brown soils in Jiaodong Peninsula of China. However, LOAs, especially the LOAs that could precipitate with Ca in byproduct amendments, negatively impair the ameliorating effect on acidic soil compared with byproduct amendments alone treatment. When using byproduct amendments to ameliorate acidic soil, the type of LOAs secreted by plant roots was an influencing factor that must be considered. [ABSTRACT FROM AUTHOR]

Published

2024

34. Effects of Applying Sewage Sludge Treated with Amendments on Soil Chemical Properties.

Author

Karagianni, Anastasia-Garyfallia, Balidakis, Athanasios, Ipsilantis, Ioannis, and Matsi, Theodora

Subjects

*SOIL amendments, *ACID soils, *CHEMICAL properties, *BENTONITE, *VERMICULITE, *CLAY minerals, *SLUDGE management, *SEWAGE sludge

Abstract

Soil application of treated sewage sludge is considered a beneficial management option for agriculture and environment. Sludge treated with clay minerals or biochar was evaluated as soil amendment, in comparison with limed or untreated sludge. Bentonite, vermiculite, biochar or lime was added to dewatered sewage sludge at 0 and 15% rates, in three replications and air-dried. Then, the treated and untreated sludge were added to two soils, one acid and one alkaline, at 0 (control), 1 and 3% rates, in three replications. The results showed that the pH of acid soil significantly increased compared to control upon addition of treated and untreated sludge at both rates, but remained acidic (<6.0) in all cases except for limed sludge. Upon addition of 3% treated or untreated sludge to both soils, organic carbon (OC) significantly increased compared to control. The same stands for soil available ammonium nitrogen (NH4-N), phosphorus (P), potassium (K), copper (Cu), zinc (Zn) and boron (B) for both soils and rates. Soil total heavy metals, which regulate sludge's agronomic use, were below the legislative limits. However, the 3% addition rate of all kinds of sludge, especially of untreated, to both soils increased the electrical conductivity of saturation extract (ECse >2 dS m−1) at unacceptable levels for sensitive crops and available P, B and Zn 2–3, 2–4 and 6–12 times above the initial, respectively. Consequently, sewage sludge treated with bentonite, vermiculite or biochar could be used as a soil amendment but at rates lower than 3% (≈120 Mg ha−1). [ABSTRACT FROM AUTHOR]

Published

2024

35. NUTRIENT PROPERTIES OF FRESH AND COMPOSTED COTTON GIN BYPRODUCTS AND CATTLE MANURE FOR SOIL AMENDMENT.

Author

Alege, Femi Peter, Blake, Cody Daniel, Donohoe, Sean P., and Thomas, Joseph W.

Subjects

*CATTLE manure, *SOIL amendments, *COTTON gins & ginning, *COMPOSTING, *MANURES

Abstract

Applications of fresh and composted Cotton Gin Byproducts (CGB) and cattle manure as soil amendments are very common practices in the industry. However, composting and direct application of the materials are often limited by factors such as bulkiness, varying nutrient composition and application rates, and handling/transportation costs. This study was conducted to characterize fresh and composted CGB and beef manure (BM) for subsequent co-pelletization and utilization as soil amendments, and to investigate the effects of composting on the nutrient composition and agronomic values. Raw and composted samples of CGB and BM at different storage periods and composting ages were sourced from two commercial gins and a beef farm. Nutrient content, acidity, and compost maturity indices such as carbon/nitrogen (C/N) and ammonium/nitrate (NH4-N/NO3-N) ratios were determined and compared. All samples were obtained at four sampling points on the respective storage or composting piles. The results showed that composted CGB generally contained at least 55% more total-N and phosphorus oxide (P2O5), but approximately 35% less potassium oxide (K2O) than fresh CGB. Composted BM had approximately 3% less total-N, but at least 25% more P2O5 than raw BM. The nutrient compositions affirm the potential for co-pelletizing both forms of CGB and BM to improve the agronomic values and enhance the utilization as soil amendments. In addition, establishing the various properties of CGB and BM is crucial for determining product formulations and selecting process parameters for co-pelletization. [ABSTRACT FROM AUTHOR]

Published

2024

36. Effect of Biochar on Soil Health and Crop Productivity: A Review.

Author

Ramamoorthy, P., Nirmala Mary, P. Christy, Chandra Bose, K. Subas, Karthikeyan, B., and Manivelan, K.

Subjects

*BIOCHAR, *SOIL remediation, *SOIL amendments, *CLIMATE change mitigation, *PLANT health

Abstract

Biochar has been recently proposed as a management strategy to improve crop productivity and global warming mitigation. Biochar may be added to soils with the goal to improve the soil properties and relocate an amount of conventional fossil fuel based fertilizers and sequester carbon. Biochar production and incorporation in soil must play a role in climate change mitigation. The need for further clarity on optimizing biochar application to various crop yields is necessary if it is to gain widespread acceptance as a soil amendment. There is urgent need to intensify agricultural production to secure food supply for the ever increasing population especially in developing country like India of the tropics. Biochar proponents have placed on biochar stability in soil and it also includes increased soil fertility and water holding capacity, increased crop production and remediation of contaminated soils. The biochar have potential to feasibly and sustainably sequester/offset over 1 Pg of CO2-carbon equivalents annually. Current carbon market incentives are not sufficient to rapidly increase or maximize the initiation and development of biochar implementation. [ABSTRACT FROM AUTHOR]

Published

2024

37. Biochar and Silicon for Sustainable Agriculture in Acid Soil-Nutrient Dynamics and Maize Production: A Review.

Author

Abubakar, Wasil, Uddin, M. K., Kasim, Susilawati, Zaibon, Syaharudin, Shamsuzzaman, S. M., Haque, A. N. A., and Reza, A.

Subjects

*SUSTAINABLE agriculture, *BIOCHAR, *SOIL acidification, *SOIL amendments, *SOIL acidity

Abstract

The central part of the country in the world classified Maize as their staple and essential crop, but this crop cannot cultivate appropriately in acidic soil. Thus, biochar, silicon and phosphorus observation can act as an agent to improve the growth of Maize in acidic soil. Additionally, biochar, well known for its alkaline properties, can reduce soil acidification and, at the same time, improve crop production. This low pH condition was caused by aluminium, manganese and low of phosphorus. Thus, silicon and phosphorus can improve crop productivity. Using biochar as a soil amendment raises the pH value, alone or in combination. Maize (Zea mays L.) and the acidity of the soil are much related to the application of biochar combined with silicon and phosphorus. Biochar simply can reduce exchangeable soil acidity, but when combined with silicon and phosphorus, it can have a greater influence on reducing soil Al toxicity. The importance of biochar with different rates combined with silicon and phosphorus to increase the pH of soil is still an inconsistent result by various studies. This review summarizes the properties of biochar, silicon and phosphorus and provides the scientific reference for its application to archive high yield of maize and reduce the acidification effect on soil. [ABSTRACT FROM AUTHOR]

Published

2024

38. Water-Retaining Agent as a Sustainable Agricultural Technique to Enhance Mango (Mangifera indica L.) Productivity in Tropical Soils.

Author

Zang, Xiaoping, Yun, Tianyan, Wang, Lixia, Zhan, Rulin, Ding, Zheli, Ma, Weihong, Eissa, Mamdouh A., Jing, Tao, Liu, Yongxia, Xie, Jianghui, and He, Yingdui

Subjects

*AGRICULTURE, *SOIL productivity, *SOIL amendments, *AGRICULTURAL productivity, *SOIL leaching, *MANGO, *FRUIT yield

Abstract

Reducing fertilizer doses under sustainable agricultural management is possible by increasing nutrient utilization efficiency, which will decrease crop production costs and boost economic return. Soil amendments known as water retention agents (WRAs) are added to the soil to enhance crop growth conditions. We hypothesize that the addition of WRAs may support the soil-retaining nutrients given through fertilization and prevent them from leaching into tropical soils characterized by severe rainfall due to WRAs' exceptional capacities to absorb and store water. Mango trees (Mangifera indica L. cv Tainong No. 1) aged 18 years were fertilized with 100% or 80% of the recommended doses of nitrogen (N), phosphorus (P), and potassium (K). The experimental design included three treatments, i.e., complete recommended doses of N, P, and K (CRF), 80% of the complete recommended doses (RRF), and water-retaining agent (40 kg ha−1) + 80% of the complete recommended doses (WRARRF). Reducing the fertilization doses by 20% for mango trees in the studied tropical soil significantly (p < 0.05) minimized the nutrient availability in the soil compared to the complete fertilization doses. WRARRF compensated for the nutrient reduction by increasing the availability of N, P, and K. The addition of WRARR increased N, P, and K in mango leaf by 11%, 4%, and 7% in the first year and by 11%, 6%, and 7% in the second year, respectively, compared to CRF. The addition of WRARR increased the partial fertilizer productivity (PFP) value by 36% and 41% in the first and second years, respectively. The highest mango fruit output was achieved by the addition of WRARRF, which resulted in increases in mango fruit yield of 11.9% and 16.5% in the first and second years, respectively, compared to RRF. Fruit quality traits showed the descending order: WRARRF > RRF > CRF. WRARRF produced the maximum economic benefit (USD 7372 per hectare) compared to CRF and RRF. The polyacrylamide/attapulgite water-retaining agent exhibited remarkable improvement in mango fruit yield and economic profit by regulating the release of nutrients in tropical soils. Water-retaining agents are an effective strategy for overcoming the extensive fertilization used in mango orchards, which has resulted in numerous environmental contaminations and the inefficient use of fertilizers. [ABSTRACT FROM AUTHOR]

Published

2024

39. Evaluation of Soil Total Nitrogen as an Indicator of Soil Bacterial Community Response to Biochar and Plant Growth-Promoting Rhizobacteria Applications.

Author

Ding, Chenke, Lv, Chengqun, Chen, Hualin, Zhou, Jiangmin, and Ren, Han

Subjects

*PLANT growth-promoting rhizobacteria, *BACTERIAL communities, *NITROGEN in soils, *BIOCHAR, *SOIL amendments

Abstract

Biochar and plant growth-promoting rhizobacteria (PGPR) are widely used as an amendment for soil physicochemical properties and soil bacterial community diversity. In Guangxi, China, we carried out a study to determine how PGPR and biochar influence the soil's environmental stability in an Eucalypt plantation. We applied biochar and PGPR in a contrasting application manner to an acidic red loam soil. Thus, three treatments were set up as 5 × 1010 CFU·mL−1 PGPR-only (MB0), 20 t·hm−2 biochar-only (B20), and co-application of 20 t·hm−2 biochar and 5 × 1010 CFU·mL−1 PGPR (MB20), as well as no biochar and no PGPR (M0B0). Our results indicated that MB20 significantly decreased the soil total nitrogen (TN) and increased the soil total phosphorus (Soil TP), soil ammonium nitrogen (NH4+), and soil water content (SWC) when compared with the control. The MB20 also significantly increased the Simpson, ACE, and Chao indices of the soil bacterial community's diversity relative to the control. We also observed a significant effect of the Soil TN on both the bacterial community and the functional diversity in soil. These findings may indicate that assessing the soil N status is expected to be an essential indicator of the soil microenvironment's response to biochar and PGPR applications. [ABSTRACT FROM AUTHOR]

Published

2024

40. Effect of Integrated Disease Management (IDM) Practices on Disease Severity and Incidence of Common Scab of Potato.

Author

Kumar, Shivam, Biswas, Samir Kumar, Kumar, Anil, Rajput, Vishnu D., Kumar, Ravi, Kumar, Saurabh, Thanuja, K. H., and Kumar, Ravinder

Subjects

*DISEASE incidence, *DISEASE management, *PESTICIDE resistance, *COPPER, *SODIC soils, *IRON, *SOIL amendments

Abstract

Common scab is a disease caused by Streptomyces spp. that can significantly reduce potato crop yield and quality, affecting marketability. Traditionally, pesticides have been used to prevent this disease, but this approach has several drawbacks, including the development of pesticide resistance and negative effects on the environment and human health. Therefore, it was essential to develop eco-friendly Integrated Disease Management (IDM) strategies for common scab management. In this study, we evaluated 13 different treatments in various combinations with three replications each. We found that treatment T2 (soil amendments with gypsum at 2.0 t/ha + tuber treatments with Trichoderma harzianum at 5 g/kg + foliar spray of copper oxychloride with streptocycline in a 3:1 ratio) showed the highest reduction in disease severity (3.63%) and incidence (1.79%) compared to the control (46.60% and 34.57%, respectively). Moreover, IDM practices also altered the physiochemical properties of the soil. T2 treatment resulted in the highest pH value of 5.86 after planting and 5.30 after harvesting, with the minimum Electrical Conductivity (EC) value estimated to be 0.089 S/m after planting and 0.087 S/m after harvesting. After planting, T2 treatment showed a soil content of 2.12 mg/kg zinc, 3.41 mg/kg copper, and 38.83 mg/kg iron, which increased to 2.42 mg/kg zinc, 3.27 mg/kg copper, and 38.39 mg/kg iron after harvesting. T4 treatment (soil amendments with elemental sulphur at 0.5 t/ha + tuber treatments with T. harzianum at 5 g/kg + foliar spray of copper oxychloride with streptocycline in a 3:1 ratio) showed the highest sulphur content, estimated at 47.69 mg/kg after planting and 48.43 mg/kg after harvesting, and reduced the disease severity and incidence by 10.89% and 7.19%, respectively. T3 treatment (MnSO4 at 15 kg/ha + T. harzianum at 5 g/kg + copper oxychloride with streptocycline in a 3:1 ratio) resulted in the highest soil content of manganese, with 96.47 mg/kg after planting and 98.84 mg/kg after harvesting. Overall, T2 treatment showed the most effective control against common scab disease and is recommended as the best IDM strategy for potato common scab management. [ABSTRACT FROM AUTHOR]

Published

2024

41. Temporal Stability of Management Zone Patterns: Case Study with Contact and Non-Contact Soil Electrical Conductivity Sensors in Dryland Pastures.

Author

Serrano, João, Shahidian, Shakib, Marques da Silva, José, Paniágua, Luís L., Rebollo, Francisco J., and Moral, Francisco J.

Subjects

*ELECTRIC conductivity, *SOIL surveys, *DETECTORS, *PASTURES, *SOIL amendments

Abstract

Precision agriculture (PA) intends to validate technological tools that capture soil and crop spatial variability, which constitute the basis for the establishment of differentiated management zones (MZs). Soil apparent electrical conductivity (ECa) sensors are commonly used to survey soil spatial variability. It is essential for surveys to have temporal stability to ensure correct medium- and long-term decisions. The aim of this study was to assess the temporal stability of MZ patterns using different types of ECa sensors, namely an ECa contact-type sensor (Veris 2000 XA, Veris Technologies, Salina, KS, USA) and an electromagnetic induction sensor (EM-38, Geonics Ltd., Mississauga, ON, Canada). These sensors were used in four fields of dryland pastures in the Alentejo region of Portugal. The first survey was carried out in October 2018, and the second was carried out in September 2020. Data processing involved synchronizing the geographic coordinates obtained using the two types of sensors in each location and establishing MZs based on a geostatistical analysis of elevation and ECa data. Although the basic technologies have different principles (contact versus non-contact sensors), the surveys were carried out at different soil moisture conditions and were temporarily separated (about 2 years); the ECa measurements showed statistically significant correlations in all experimental fields (correlation coefficients between 0.449 and 0.618), which were reflected in the spatially stable patterns of the MZ maps (averaging 52% of the total area across the four experimental fields). These results provide perspectives for future developments, which will need to occur in the creation of algorithms that allow the spatial variability and temporal stability of ECa to be validated through smart soil sampling and analysis to generate recommendations for sustained soil amendment or fertilization. [ABSTRACT FROM AUTHOR]

Published

2024

42. Multi-Omics Analysis of the Effects of Soil Amendment on Rapeseed (Brassica napus L.) Photosynthesis under Drip Irrigation with Brackish Water.

Author

Li, Ziwei, Fan, Hua, Yang, Le, Wang, Shuai, Hong, Dashuang, Cui, Wenli, Wang, Tong, Wei, Chunying, Sun, Yan, Wang, Kaiyong, and Liu, Yantao

Subjects

*MICROIRRIGATION, *BRACKISH waters, *IRRIGATION water, *RAPESEED, *SOIL testing, *SOIL amendments, *FLOWERING time, *PLATEAUS

Abstract

Drip irrigation with brackish water increases the risk of soil salinization while alleviating water shortage in arid areas. In order to alleviate soil salinity stress on crops, polymer soil amendments are increasingly used. But the regulation mechanism of a polymer soil amendment composed of polyacrylamide polyvinyl alcohol, and manganese sulfate (PPM) on rapeseed photosynthesis under drip irrigation with different types of brackish water is still unclear. In this field study, PPM was applied to study the responses of the rapeseed (Brassica napus L.) phenotype, photosynthetic physiology, transcriptomics, and metabolomics at the peak flowering stage under drip irrigation with water containing 6 g·L−1 NaCl (S) and Na2CO3 (A). The results showed that the inhibitory effect of the A treatment on rapeseed photosynthesis was greater than that of the S treatment, which was reflected in the higher Na+ content (73.30%) and lower photosynthetic-fluorescence parameters (6.30–61.54%) and antioxidant enzyme activity (53.13–77.10%) of the A-treated plants. The application of PPM increased the biomass (63.03–75.91%), photosynthetic parameters (10.55–34.06%), chlorophyll fluorescence parameters (33.83–62.52%), leaf pigment content (10.30–187.73%), and antioxidant enzyme activity (28.37–198.57%) under S and A treatments. However, the difference is that under the S treatment, PPM regulated the sulfur metabolism, carbon fixation and carbon metabolism pathways in rapeseed leaves. And it also regulated the photosynthesis-, oxidative phosphorylation-, and TCA cycle-related metabolic pathways in rapeseed leaves under A treatment. This study will provide new insights for the application of polymer materials to tackle the salinity stress on crops caused by drip irrigation with brackish water, and solve the difficulty in brackish water utilization. [ABSTRACT FROM AUTHOR]

Published

2024

43. Recent advances on environmentally sustainable valorization of spent mushroom substrate: A review.

Author

Kousar, Aafia, Khan, Hasnat Ayub, Farid, Soban, Zhao, Quanbao, and Zeb, Iftikhar

Subjects

*EDIBLE mushrooms, *CIRCULAR economy, *MUSHROOMS, *SOIL amendments, *BIOGAS production

Abstract

Commercial cultivation of edible mushrooms utilizes a large amount of lignocellulosic material as a substrate. After harvest, the leftover substrate, referred to as a spent mushroom substrate (SMS), largely remains biochemically unaltered. In light of the global rise in the number of edible mushroom production facilities, it is pertinent to sustainably manage the by‐products of the mushroom production process, particularly SMS. Following the principles of the circular economy, SMS has shown potential for a variety of applications: SMS can be used as substrate for a new cycle of mushroom cultivation or as animal feed, fertilizer, soil amendment, bioremediation agent or a substrate for renewable energy production such as biogas, bioethanol, biohydrogen, solid biofuel, bio‐crude and bio‐oil. This article summarizes the current state of knowledge in various applications, highlights recent developments in the field, discusses potential barriers and offers suggestions for the long‐term growth of the mushroom industry worldwide. [ABSTRACT FROM AUTHOR]

Published

2024

44. Nutrient retention after crop harvest in a typic hapludults amended with biochar types under no-tillage system.

Author

Sarfaraz, Qamar, Drescher, Gerson Laerson, Zafar, Mohsin, Shah, Muhammad Nadeem, Zhao, Fengliang, Danish, Subhan, Mustafa, Abd El-Zaher M. A., Elshikh, Mohamed S., and Souza da Silva, Leandro

Subjects

*BIOCHAR, *SUSTAINABILITY, *SOIL amendments, *PLANT residues, *SWINE manure, *NO-tillage, *TILLAGE

Abstract

The utilization of biochar's as soil amendments for enhancing nutrient retention in subsoils present potential limitations. To address this issue, we conducted a greenhouse experiment to assess the effects of various biochar's derived from animal manures (swine manure, poultry litter, cattle manure) and plant residues (rice straw, soybean straw, corn straw) when applied to surface of an acidic soil. Our study focused on wheat crops under a no-tillage system, with a subsequent evaluation of the residual impacts on soybeans. The experimental design involved the application of biochar's at different rates i.e. 10 and 20 Mg ha−1, followed by the assessment of their influence on NPK levels, pH, and exchangeable Al in stratified soil layers (0–5, 5–10, 10–15, and 15–25 cm). Furthermore, we investigated the interplay between biochar doses and the application of nitrogen (N) in the top 5 cm of soil, specifically examining NO 3 - , NH 4 + , P and K levels. Our findings revealed that in the top 5 cm of soil, biochar doses and N application significantly affected NO 3 - , NH 4 + , P and K concentrations. However, in deeper soil layers, no significant differences were observed among biochar doses with or without N application. Interestingly, K levels were impacted throughout all soil depths, regardless of the presence or absence of N application. Moreover, biochar application up to a 5 cm depth induced favorable changes in soil pH and reduced exchangeable Al. In contrast, deeper layers experienced a decrease in soil pH and an increase in exchangeable Al following biochar treatment. In conclusion, our study demonstrates that biochar's can effectively retain NPK nutrients, enhance soil pH, and decrease exchangeable Al, independent of the type and dosage of application under a no-tillage system. Nonetheless, the efficacy of biochar amendments may vary with soil depth and type of nutrient, warranting careful consideration for maximizing their benefits in sustainable agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

45. Biochar produced at high temperature mitigates N2O emission and promotes nitrogen retention in subtropical forest soils.

Author

Cheng, Liutao, Wang, Bingtao, Ren, Mengfan, Wang, Yuzhe, Hu, Yalin, and Liu, Xian

Subjects

*FOREST soils, *BIOCHAR, *HIGH temperatures, *SOIL amendments, *BIOMASS burning

Abstract

Biochar is produced by burning biomass under oxygen‐limited conditions, and it has been widely used as a soil amendment to improve soil functions such as nutrient retention. However, whether the impact of biochar application on soil nitrogen (N) transformation and N2O emission varies with the pyrolysis temperature remains unclear, especially in different forest types in subtropical regions. In this study, a 60‐day laboratory incubation experiment was conducted to evaluate the impact of biochar with different pyrolysis temperatures (300°C [BC300], 500°C [BC500], and 800°C [BC800]) on net N transformation rates and N2O emission in soils collected from Castanopsis kawakamii dominated natural forest (NF) and Chinese fir (Cunninghamia lanceolate, CF) plantation in subtropical China. The results showed that the application of biochar significantly increased soil ammonium (NH4+) content (p < 0.001) but reduced nitrate (NO3−) content (p < 0.001) compared with the control. The soil NH4+ content of the BC800 treatment was significantly higher than that of other treatments (p < 0.001). Biochar application significantly reduced soil net N mineralization (NRmin) and nitrification (NRnit) rate (p < 0.001), but increased net ammonification (NRamm) rate (p < 0.001). The application of biochar led to a remarkable decrease in cumulative N2O emission compared to the control (p < 0.001). In particular, soils treated with high‐temperature biochar emitted significantly lower N2O compared to other treatments (p < 0.001). The partial least squares path model demonstrated that biochar influenced N2O emission through a direct effect in NF soil and an indirect effect in CF soil. This study highlights the distinct role of biochar, particularly that produced under high pyrolysis temperatures as a soil amendment to mitigate N2O emission and promote N retention in both subtropical natural and planted forests. [ABSTRACT FROM AUTHOR]

Published

2024

46. Biochar as a potential tool to mitigate nutrient exports from managed boreal forest: A laboratory and field experiment.

Author

Mosquera, Virginia, Gundale, Michael J., Palviainen, Marjo, Laurén, Annamari, Laudon, Hjalmar, and Hasselquist, Eliza Maher

Subjects

*BIOCHAR, *TAIGAS, *FIELD research, *DITCHES, *SOIL amendments, *NUTRIENT cycles, *FORESTED wetlands

Abstract

Forest management in drained forested peatlands can negatively affect water quality due to the increase in exports of organic matter and nutrients. Therefore, new methods to alleviate this impact are needed. In laboratory conditions, biochar has been shown to be a strong sorbent of organic and inorganic nutrients due to its high surface area and ion‐exchange capacity. However, evidence of the adsorption capacity in field conditions is lacking. Here, we studied the water purification performance of two different biochar feedstocks (wood‐ and garden residue‐based) in a 10‐day laboratory experiment where we incubated biochar with runoff water collected from drainage ditches in clear‐cut peatland forests. We measured changes in pH and concentrations of inorganic phosphorus (PO4), total dissolved nitrogen (TDN), and dissolved organic carbon (DOC). The biochar with the best adsorbent capacity in the laboratory experiment was then tested in field conditions in a replicated catchment‐scale experiment, where both clear‐cutting and ditch cleaning were performed. We determined the nutrient concentration of water at the inlet and outlet of biochar filters placed in outflow ditches of four catchments. We found that under laboratory conditions wood‐based biochar efficiently adsorbed TDN and DOC, however, it released PO4. Furthermore, we found that the biochar filters reduced TDN and DOC concentration in field conditions. However, the percentage decrease in concentration was dependent on the initial concentrations of nutrients in the water and could be considered low. Moreover, we found that the biochar in the filters increased in TN content over the course of the experiment. This suggests that a wood‐based biochar filter has the potential to be a water protection tool for reducing the export of nutrients from catchments with high nutrient concentration. And that the biochar from the ditches could be applied back to the regenerating forest catchment as a potential soil amendment, closing the nutrient cycle. [ABSTRACT FROM AUTHOR]

Published

2024

47. EDDS and polystyrene interactions: implications for soil health and management practices.

Author

Rassaei, Farzad

Subjects

*SOIL management, *SUSTAINABLE agriculture, *SOIL remediation, *ENVIRONMENTAL research, *CROPS

Abstract

Ethylenediamine-N,N'-disuccinic acid (EDDS) has been studied extensively for its potential use as an amendment in agriculture due to its numerous beneficial properties. The widespread usage of microplastics (MPs) poses a growing threat to plant growth. This study investigated the effects of Polystyrene MPs (PSMPs) and EDDS on soil pH, EC, organic matter (OM), available nutrients, and maize (Zea mays L.) growth in a calcareous soil. Results showed that both PS and EDDS had significant effects on soil pH, with higher concentrations leading to a decrease in pH. PSMPs negatively impacted soil health by increasing EC and decreasing OM, nitrogen (N), phosphorus (P), and potassium (K). EDDS had potential applications in soil remediation and phytoremediation by decreasing EC and increasing N, P, and K. The interaction between EDDS and PSMPs suggests that their effects on soil pH may be modulated by each other. The study highlights the potential negative impacts of high concentrations of PS on soil health and the potential benefits of using EDDS at lower concentrations in soil remediation and phytoremediation. However, further research is needed to understand the mechanisms and environmental impacts of EDDS and the combined effects of EDDS and PSMPs on soil properties and plant growth. Plastic pollution is a serious environmental issue affecting soil health worldwide, and this study sheds new light on the potential benefits of using EDDS at lower concentrations for soil remediation and phytoremediation. The findings reveal that EDDS can mitigate the negative impacts of PS on soil health and maize growth by improving nutrient availability, enhancing soil structure, and water retention. The study is the first to investigate the interactive effects of EDDS and PS on maize growth parameters across different levels of PS contamination. The results provide critical insights into the mechanisms underlying the mitigating effects of EDDS and highlight the need for further research on the environmental impacts of plastic pollution and effective management practices. Overall, this study presents a novel approach to mitigating the negative impacts of plastic pollution on soil health and crop production, with important implications for sustainable agriculture and environmental preservation. This study shows that EDDS, at lower concentrations, can mitigate the negative impacts of PSMPS on soil health and maize growth. It is the first to examine interactions between EDDS and PSMPS across varying levels of contamination. The results point to the potential benefits of EDDS as a soil amendment to remediate MPs pollution, revealing insights into its mechanisms of action. Findings suggest possible solutions for MPs pollution in agriculture but call for more research to balance environmental goals. Both EDDS and PSMPs impacted soil pH, EC, OM, and nutrient levels. PSMPS caused pH decrease, increased EC, and reduced OM, N, P, and K levels, negatively affecting soil health. EDDS showed potential for soil remediation, increasing N, P, and K levels, and decreasing EC, with optimal concentrations. Interaction between EDDS and PSMPs influenced soil pH modulation, revealing interplay between their effects. PSMPs had significantly negative effects on maize growth parameters, including root and shoot dry weight, chlorophyll content, leaf area, and plant height. EDDS amendment mitigated PSMPs's adverse impacts on maize growth, especially chlorophyll content and leaf area. Interaction between PSMPs and EDDS improved soil and plant health, possibly via chelation, property alteration, and enhanced nutrient availability. EDDS demonstrates promise as an environmentally friendly strategy to counteract the effects of PSMPs contamination on agricultural soils and crop productivity. Further research is essential to understand EDDS mechanisms and environmental impacts, as well as the combined effects of EDDS and PSMPs on soil and plant properties. [ABSTRACT FROM AUTHOR]

Published

2024

48. Agriculture in the Ancient Maya Lowlands (Part 2): Landesque Capital and Long-term Resource Management Strategies.

Author

Fedick, Scott L., Morell-Hart, Shanti, and Dussol, Lydie

Subjects

*MAYAS, *RESOURCE management, *AGRICULTURE, *SOIL amendments, *LAND tenure, *WEED competition, *SOCIAL capital, *INFORMATION resources management

Abstract

Pre-Columbian food production in the Maya Lowlands was long characterized as reliant on extensive, slash-and-burn agriculture as the sole cultivation system possible in the region, given environmental limitations, with maize as the dominant crop. While aspects of this "swidden thesis" of Maya agriculture have been chipped away in recent years, there has been an underappreciation of the many forms of long-term capital investments in agriculture made by ancient Maya people. Here, we review the last three decades of research that has overturned the swidden thesis, focusing on long-term strategies. We demonstrate long-lasting agricultural investments by Maya people, in social capital including multigenerational land tenure, in cultivated capital including long-lived trees, and in landesque capital including soil amendments and landscape engineering projects, such as terracing and wetland modification. [ABSTRACT FROM AUTHOR]

Published

2024

49. The Impact of Biochar and Compost as Soil Amendments, Combined with Poultry Manure, on the Growth, Yield, and Chemical Composition of Lettuce ( Lactuca sativa )

Author

Laith Mohamad Alomari, Taha Ahmad Al-Issa, Mu’ad Abdul-Latif Kiyyam, and Abdel Rahman Al Tawaha

Subjects

biochar, compost, soil amendments, poultry manure, lettuce, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350

Abstract

In 2019, the experiment was carried out at Jordan University of Science and Technology (JUST). Various soil amendments, including biochar and compost, both with and without the combination of poultry manure, were employed. The experimental design followed a completely randomized layout, with seven distinct treatments: T1 - soil (control), T2 - Biochar (3%) (BC), T3 - compost (3%) (Comp), T4 - poultry manure (3%) (PM 3% (38.2 ton/ha)), T5 - Biochar (3%) + poultry manure (60 ton/ha) (BC+PM 60 ton/ha), T6 - compost (3%) + poultry manure (60 ton/ha) (Comp+PM 60 ton/ha), and T7 - poultry manure (60 ton/ha) (PM 60 ton/ha). The assessment encompassed the examination of various physicochemical characteristics of the soil, including bulk density, porosity, water holding capacity, pH, and EC. Morphological and physiological measurements comprised plant shoots and roots' height and length, leaves number, shoots and roots' fresh and dry weight, leaf relative water content, and chlorophyll content. Additionally, the chemical composition, encompassing crude fibers, crude fats, antioxidant activities, total phenols, flavonoids content, and minerals was evaluated. Physicochemical results revealed that (BC+PM 60 ton/ha) excelled in water holding capacity and porosity, whereas PM 60 ton/ha exhibited the optimal soil pH. In terms of morphological results, (Comp+PM 60 ton/ha) and (PM 3% (38.2 ton/ha)) demonstrated superiority in plant height, shoot fresh and dry weight. The application of (BC) outperformed in root fresh and dry weight and leaf relative water content, while (Comp) exhibited the highest root length. Poultry manure applications scored higher values in chlorophyll content, with (BC+PM 60 ton/ha) recording the highest among them. Chemical analysis revealed that crude fibers were highest with the application of (PM 3% (38.2 ton/ha)), while (control) recorded the highest antioxidant activities, total phenols, and total flavonoids. In terms of minerals content in shoots, (Comp+PM 60 ton/ha) demonstrated the highest nitrogen content. Phosphorus, Potassium, magnesium, and calcium were most abundant in (BC+PM 60 ton/ha). Moreover, PM (60 ton/ha) exhibited the highest sodium content. Notably, the (BC+PM 60 ton/ha) application excelled in physiochemical soil properties, excluding soil pH and EC, while also demonstrating superior mineral content in lettuce plants, except for sodium.

Published

2024

50. The role of biochar and compost to mitigate agrochemical contamination impact on agricultural soils.

Author

Dewi, Triyani, Erwinda, Ardiwinata, Asep Nugraha, and Hindersah, Reginawanti

Subjects

*AGRICULTURE, *BIOCHAR, *SOIL amendments, *PESTICIDE residues in food, *SOIL pollution, *AGRICULTURAL chemicals

Abstract

Agrochemicals such as plant growth agents, pesticides, and fertilizers are widely utilized in agricultural practices to promote crop yields. The long-term and excessive usage of agrochemical inputs often results in poor soil health, contamination of pesticide residue, and heavy metals in the environment and food chain, which can also cause human health-related problems. Using biochar and compost in agricultural soils is known to increase soil fertility, improve degraded land, increase the soil microbial population, and reduce heavy metal contamination and pesticide residues. This article aims to examine the role of biochar and compost in reducing the impact of agrochemical contamination on soils in supporting environmentally friendly agricultural management. Biochars are organic matrices, and organic matrices can make heavy metals immobile and nonbioavailable in various physicochemical ways. Biochar could be effective in medium-fertility soils in term of water and nutrient retention and carbon sequestration. Compost is wealthy in nutrients, microorganisms, and humic matter. Compost may be added to agricultural soil as a fertilizer to increase soil fertility and support the growth of crops and microorganisms and as a soil amendment to mitigate heavy metal contamination in soil. The biochar-compost mixture application was shown to be more effective than biochar alone in improving soil properties and having direct economic value on crop yields. Other advantages informed by biochar-compost merging into soils can reduce fertilizer applications, increase the efficiency of fertilizer and water input, and decrease environmental contamination (heavy metal accumulation and pesticide residue in soil). [ABSTRACT FROM AUTHOR]

Published

2024