Interactive effects of rice-residue biochar and N-fertilizer on soil functions and crop biomass in contrasting soils

Availability of Zinc (Zn) is very low in calcareous soils and hence, an amendment must be used to increase Zn availability to plants. The main objective of this study was to assess the changes in chemical fractions and availability of Zn in a calcareous soil amended with corn residue biochar. Three corn residue biochars were produced at 200 (B200), 350 (B350), and 500°C (B500) and applied at 1 and 2% w/w to a calcareous soil with low organic C content (4.1 g kg −1) and high pH (7.7). The mixtures were incubated for 90 days in the laboratory (25 ± 2°C and 80% of soil field capacity). The application of biochar increased soil total organic carbon (TOC) (1.81-to 3.27-fold), cation exchange capacity (CEC) (1.03-to 1.14-fold) and Zn bound to organic matter (1.34-to 2.15-fold). Relative to untreated soil, the B200 biochar (1) decreased soil pH (0.22-0.30 unit); (2) increased dissolved organic carbon (DOC) (1.34-to 1.59-fold), microbial biomass carbon (MBC) (1.56-to 1.67-fold) and DTPA-extractable Zn (1.32-to 1.42-fold); and (3) maximized Zn content in 3 out of 5 soil pools, i.e., exchangeable Zn; organically bounded Zn; and Fe/ Mn-oxide-bounded Zn. In contrast, the B500 biochar (1) increased soil pH; (2) did not affect DOC or DTPA-extractable Zn quantities in soil extracts; and (3) maximized Zn content in carbonate-Zn and residual-Zn soil fractions. The B350 biochar (1) did not affect soil DOC and DTPA-extractable Zn and (2) slightly increased carbonate-Zn fractions. The effects of biochar addition on soil properties and chemical fractions of Zn were greater at 2% than 1% application rates. Results suggest that corn residue biochar produced at 200°C and applied to calcareous soils at a 2% rate may effectively increase Zn availability by increasing the amount of Zn held in the more labile Zn soil fractions.

Section: Soil Ph and Cecsupporting

confidence: 59%

Section: Soil Toc Doc and Mbcmentioning

confidence: 99%

Chemical Fractions and Availability of Zn in a Calcareous Soil in Response to Biochar Amendments

Karimi

Moezzi

Chorom

et al. 2019

“…Cornelissen et al (2013) reported that BC application to maize plants exposed to drought stress triggered the increased nutrient retention in growth media with variable physical/chemical characteristics. Also, in soils with contrasting texture (loamy sand and sandy clay loam), maize had the beneficial effects of biochar on biomass (Singh Mavi et al 2018). Therefore, as well as trials in the soil environment, there might be an interaction between nutrient mobility and BC in hydroponic culture.…”

Section: Discussionmentioning

confidence: 99%

“…in biochar (Inyang et al 2016). Thanks to functional groups, in soils treated with biochar, it has influenced the physicochemical properties including soil pH and water holding capacity, and aeration, soil biological activity, and aggregate stability (Bamminger et al 2016;Singh Mavi et al 2018). Besides, under stress conditions (such as water, drought, and salt stress), there is an improvement on photosynthetic apparatus, water-use efficiency, and crop productivity in BC-applied plants such as tomato, maize, and milk thistle (Akhtar et al 2014;Haider et al 2015;Keshavarz Afshar et al 2016;Paneque et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Biochar Triggers Systemic Tolerance Against Cobalt Stress in Wheat Leaves Through Regulation of Water Status and Antioxidant Metabolism

Yildiztugay

Özfidan-Konakçi

Yıldıztugay

et al. 2019

To eliminate the damages of metal toxicity by reducing metal uptake by plants, organic amendments are useful. The use of carbon-rich materials known as biochar (BC) is a strong candidate to enhance the plant tolerance against stress conditions. The current study examined the effects of BC in wheat hydroponically grown treated with BC (1 and 3 g L −1) alone or in combination with cobalt (Co, 150 and 300 μM). Stress reduced the relative growth rate (RGR), relative water content (RWC), osmotic potential (Ψ Π), and increased proline content (Pro). Besides, endogenous contents of Ca 2+ , K + , and Mn 2+ in leaves decreased under stress. In response to Co stress, a decline in the activities of peroxidase (POX), ascorbate peroxidase (APX), and glutathione reductase (GR) resulted in the induction of hydrogen peroxide (H 2 O 2) content. BC applied with stress decreased endogenous Co 2+ content and increased RGR, RWC, chlorophyll fluorescence and Pro content. Also, the activities of superoxide dismutase (SOD), catalase (CAT), APX and GR were induced and the ascorbate (AsA) and glutathione (GSH) pool and their redox state were maintained by BC application under stress condition. While, with the addition of BC, H 2 O 2 content and lipid peroxidation displayed remarkable decreased, the scavenging activity of hydroxyl radical (OH •) increased as compared to Co stress-treated wheat plants. Besides, in wheat leaves, BC application triggered AsA-GSH pathway including activities of monodehydroascorbate reductase, dehydroascorbate reductase, and the contents of dehydroascorbate, GSH, and GSH/GSSG ratio. The presented results supported the view that biochar under stress could minimize the Co-induced oxidative damages through modulation of the growth, water status, photosynthetic apparatus, and antioxidant enzyme activity found in cellular compartments and ascorbate-glutathione cycle in wheat leaves.

“…Biochar helps to improve the soil physical, chemical, and biological properties. Soil pH, electrical conductivity (EC), cation exchange capacity (CEC), organic carbon content (OC), and available nutrients (NPK) are significantly increased with different application rates of biochar (Nzediegwu et al 2019;Singh et al 2018). Biochar is a cost-effective or cheaper organic fertilizer as compared to other inorganic fertilizers (William and Qureshi 2015).…”

Section: Introductionmentioning

confidence: 99%

Application of Biochar as an Adsorbent and Its Significance on Berseem (Trifolium alexandrinum) Growth Parameters in Farm Soil Contaminated with PAH

Kaur

Sharma

2020

Soil properties can be significantly influenced by the addition of biochar and are known to enhance plant productivity and soil quality. Berseem acts as a good phytoaccumulator. The main aim of this study was to evaluate the effect of different concentrations of biochar on plant height, biomass, and chlorophyll content and on PAHs adsorption capacity at different time intervals. Sixteen treatment combinations were designed in three replicates for a total 144 pots. A soil/biochar (w/w) mixture and polyaromatic hydrocarbon (PAH) content (50 mg kg −1 naphthalene and 100 mg kg −1 phenanthrene) of suitable ratio for each application was used for filling different pots, having dimensions of 19.6 cm diameter × 20.6 cm height. Various qualitative and quantitative methods were followed for further analysis of soil, plant, and biochar samples. Maximum plant height and plant biomass were observed at 5% and 10% biochar level in the soil as compared to control. Total available nutrients increased with biochar application rate. Increase in biochar concentration resulted in increased PAH adsorption capacity, thereby making it less available to cause the negative effect on plant growth parameters. Bio-concentration factor significantly decreased with increased biochar concentration in soil, i.e., from 92.5 to 5.31 in phenanthrene-contaminated soil and from 17.4 to 1.36 in mixed contaminated soil as compared to control. These results significantly prove that biochar enhanced the PAHs adsorption capacity as well as removal efficiency and crop yield. This study also shows the effectiveness of biochar on contaminant remediation with the help of Trifolium alexandrinum.