Biochar addition alleviate the negative effects of drought and salinity stress on soybean productivity and water use efficiency

Zhang, Yaojun; Ding, Jiaqi; Hong, Wooyoung; Su, Lei; Zhao, Changwei

doi:10.1186/s12870-020-02493-2

Cited by 62 publications

(40 citation statements)

References 56 publications

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“…The application of biochar has a great potential to decrease Na + uptake and increase K + uptake. Biochar application increased cell formation and size in the root and allowed rice roots to absorb more K + and hold Na + ions away under salt stress avoiding ion toxicity, reducing the transport of Na + into the xylem isolating Na + into the vacuole [ 38 , 39 ]. Application of glycine betaine as foliar spraying improved seedling vigor, cell elongation, and growth, while enabling the plants with the developed transporter linked with the positive ion selectivity on the cell membrane and vacuole wall [ 40 ].…”

Section: Discussionmentioning

confidence: 99%

Incorporated Biochar-Based Soil Amendment and Exogenous Glycine Betaine Foliar Application Ameliorate Rice (Oryza sativa L.) Tolerance and Resilience to Osmotic Stress

Hafez

Gowayed

Nehela

et al. 2021

Plants

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Osmotic stress is a major physiologic dysfunction that alters the water movement across the cell membrane. Soil salinity and water stress are major causal factors of osmotic stress that severely affect agricultural productivity and sustainability. Herein, we suggested and evaluated the impact of integrated biochar-based soil amendment and exogenous glycine betaine application on the growth, physiology, productivity, grain quality, and osmotic stress tolerance of rice (Oryza sativa L., cv. Sakha 105) grown in salt-affected soil under three irrigation intervals (6, 9, or 12 days), as well as soil properties and nutrient uptake under field conditions during the 2019 and 2020 seasons. Our findings showed that dual application of biochar and glycine betaine (biochar + glycine betaine) reduced the soil pH, electrical conductivity, and exchangeable sodium percentage. However, it enhanced the K+ uptake which increased in the leaves of treated-rice plants. Additionally, biochar and glycine betaine supplementation enhanced the photosynthetic pigments (chlorophyll a, b, and carotenoids) and physiological attributes (net photosynthetic rate, stomatal conductance, relative water content, and electrolyte leakage) of osmotic-stressed rice plants. Biochar + glycine betaine altered the activity of antioxidant-related enzymes (catalase, ascorbate peroxide, and peroxidase). Moreover, it improved the yield components, biological yield, and harvest index, as well as the nutrient value of rice grains of osmotic-stressed rice plants. Collectively, these findings underline the potential application of biochar and glycine betaine as a sustainable eco-friendly strategy to improve plant resilience, not only rice, but other plant species in general and other cereal crops in particular, to abiotic stress, particularly those growing in salt-affected soil.

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Section: Discussionmentioning

confidence: 99%

Incorporated Biochar-Based Soil Amendment and Exogenous Glycine Betaine Foliar Application Ameliorate Rice (Oryza sativa L.) Tolerance and Resilience to Osmotic Stress

Hafez

Gowayed

Nehela

et al. 2021

Plants

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“…Overall, the meta-analysis studies broadly indicate biochar to be a suitable tool for improving crop yield in acidic and nutrientpoor soils. Contrary to the positive effects of biochar application, studies have also reported negative effects of application of biochar on the crop yield, plant growth, and nutrient availability (Jeffery et al, 2017;Sänger et al, 2017;Zhang et al, 2020). In some studies, the application of freshly prepared biochar has been reported to hinder crop yield due to the immobilization of nutrients (Ding et al, 2010;Taghizadeh-Toosi et al, 2012;Kammann et al, 2015).…”

Section: Effects Of Biochar On Plant Growth and Crop Yieldmentioning

confidence: 99%

“…Biederman and Stanley, 2013;Shareef and Zhao, 2017). On the contrary, some studies in temperate regions have reported no effect or negative effects on crop productivity (Hussain et al, 2017;Sänger et al, 2017;Cornelissen et al, 2018;Zhang et al, 2020). Moreover, the majority of literature available on biochar production, its characterization, and effects on soils are based on lab scale (pot or plot) studies; the field scale studies being very limited.…”

Section: Introductionmentioning

confidence: 99%

Review of Large-Scale Biochar Field-Trials for Soil Amendment and the Observed Influences on Crop Yield Variations

et al. 2021

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Increasing pressure on farming systems due to rapid urbanization and population growth has severely affected soil health and fertility. The need to meet the growing food demands has also led to unsustainable farming practices with the intensive application of chemical fertilizers and pesticides, resulting in significant greenhouse gas emissions. Biochar, a multifunctional carbon material, is being actively explored globally for simultaneously addressing the concerns related to improving soil fertility and mitigating climate change. Reviews on biochar, however, mainly confined to lab-scale studies analyze biochar production and its characteristics, its effects on soil fertility, and carbon sequestration. The present review addresses this gap by focusing on biochar field trials to enhance the current understanding of its actual impact on the field, w.r.t. agriculture and climate change. The review presents an overview of the effects of biochar application as observed in field studies on soil health (soil’s physical, chemical, and biological properties), crop productivity, and its potential role in carbon sequestration. General trends from this review indicate that biochar application provides higher benefits in soil properties and crop yield in degraded tropical soils vis-a-vis the temperate regions. The results also reveal diverse observations in soil health properties and crop yields with biochar amendment as different studies consider different crops, biochar feedstocks, and local climatic and soil conditions. Furthermore, it has been observed that the effects of biochar application in lab-scale studies with controlled environments are not always distinctly witnessed in corresponding field-based studies and the effects are not always synchronous across different regions. Hence, there is a need for more data, especially from well-designed long-term field trials, to converge and validate the results on the effectiveness of biochar on diverse soil types and agro-climatic zones to improve crop productivity and mitigate climate change.

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“…Biochar not only improves the soil structure, fertility, and ion transfer ability but also increased the activity of microbes and nutrient holding and exchange capacity of the soil. Therefore, biochar addition is proposed as an effective management to improve crop performance [21], as supported by the results we obtained from the experiments on Ehretia asperula plants, for which all biochar treatments clearly improved the growth characteristics such as plant height; number of leaves; and dry biomasses of root, shoot and leaves. These results agree with previous data obtained by several researchers who reported that the application of biochar increased the plant height and leaf area of okra [30] and maize [31] under drought-stress conditions.…”

Section: Discussionmentioning

confidence: 55%

“…Furthermore, biochar enriches the physicochemical properties, biological properties, and soil enzymatic activity of the soil, increasing the water status of plants. Several studies have revealed that biochar improves soil quality and crop productivity under limited water conditions [18][19][20][21]. However, some results also reported that biochar does not always seem to be useful for crop growth [22,23].…”

Section: Introductionmentioning

confidence: 99%

Biochar-Improved Growth and Physiology of Ehretia asperula under Water-Deficit Condition

et al. 2021

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Ehretia asperula’s physiological responses to growth performance following oak-wood biochar application under water stress conditions (WSC) and no water stress conditions (non-WSC) were investigated in a pot experiment. Biochar (WB) was incorporated into the soil at concentrations of 0, 5, 10, 15, and 20 tons ha−1 before transplanting Ehretia asperula in the pots. One month after transplanting, Ehretia asperula plants were put under water stress by withholding water for ten days. Water stress significantly decreased the growth and physiology of Ehretia asperula. Under WSC, the application of WB at the concentrations of 15 and 20 tons ha−1 to the soil increased the plant height; number of leaves; fresh and dry weight of the roots, shoots, and leaves; Fv/Fm; chlorophyll content; leaf relative water content; and soil moisture as well as decreased the relative ion leakage. The application of WB enhanced drought tolerance in Ehretia asperula plants by lowering the wilting point. The findings suggest that WB application at the concentration of 15 tons ha−1 could be recommended for ensuring the best physiological responses and highest growth of Ehretia asperula plants.

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Biochar addition alleviate the negative effects of drought and salinity stress on soybean productivity and water use efficiency

Cited by 62 publications

References 56 publications

Incorporated Biochar-Based Soil Amendment and Exogenous Glycine Betaine Foliar Application Ameliorate Rice (Oryza sativa L.) Tolerance and Resilience to Osmotic Stress

Incorporated Biochar-Based Soil Amendment and Exogenous Glycine Betaine Foliar Application Ameliorate Rice (Oryza sativa L.) Tolerance and Resilience to Osmotic Stress

Review of Large-Scale Biochar Field-Trials for Soil Amendment and the Observed Influences on Crop Yield Variations

Biochar-Improved Growth and Physiology of Ehretia asperula under Water-Deficit Condition

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