Water-dispersible carbon nanomaterials improve lettuce (Latuca sativa) growth and enhance soil biochemical quality at low to medium application rates

Water-dispersible carbon nanomaterials improve lettuce (Latuca sativa) growth and enhance soil biochemical quality at low to medium application rates

Purpose Improving crop yields by increasing fertilizer-use-efficiency is essential to minimizing agriculture's environmental impact. Water-dispersible carbon nanomaterials (CNM) have emerged as an innovative material to improve crop yields by increasing nutrient utilization and enhancing crop p...

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Bibliographic Details
Published in:Plant and soil Vol. 485; no. 1-2; pp. 569 - 587
Main Authors: Nepal, Jaya, Xin, Xiaoping, Maltais-Landry, Gabriel, Wright, Alan L., Stoffella, Peter J., Ahmad, Wiqar, He, Zhenli L.
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-04-2023
Springer
Springer Nature B.V
Subjects:
Accumulation
Agricultural production
Agriculture
Biochemistry
Biological activity
Biomedical and Life Sciences
Carbon
Carbon content
Crop growth
Crop yield
Crop yields
Crops
Dispersion
Ecology
Environmental impact
Enzymatic activity
Enzyme activity
Enzymes
Farm buildings
Fertilizers
Growth
Life Sciences
Microorganisms
Nanomaterials
Nanotechnology
Nitrogen
Nutrient utilization
Phosphatases
Physiological aspects
Plant Physiology
Plant Sciences
Research Article
Soil amendment
Soil fertility
Soil improvement
Soil properties
Soil Science & Conservation
Soils
Statistics
Urease
Vegetables
Nutrient availability
Agriculture
Carbon nanoparticles
Soil microbial activity
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Summary:Purpose Improving crop yields by increasing fertilizer-use-efficiency is essential to minimizing agriculture's environmental impact. Water-dispersible carbon nanomaterials (CNM) have emerged as an innovative material to improve crop yields by increasing nutrient utilization and enhancing crop physiological processes. However, the optimum dose of CNM, performance on crop growth, and impact on soil biochemical properties remain poorly understood. Methods A greenhouse pot experiment (55 days) was conducted to evaluate the effect of three CNM rates, applied basally as a soil drench amendment, on the growth of two lettuce varieties and soil biochemical properties. We compared three CNM rates (200, 400 & 800 mg kg −1 ; C200F, C400F & C800F) along with a negative control (C0F0; no fertilizer or CNM) and a positive control (C0F; fertilizer at recommended doses like CNM treatments, no CNM applied). Results We found that nitrogen (N), phosphorus and potassium (K) accumulation by lettuce and availability in soil were enhanced with CNM application, with 31% (C200F) and 34% (C400F) increases in shoot N accumulation compared to C0F, and K accumulation peaking at C800F (230% increase over C0F). Compared to C0F, soil microbial biomass carbon was 67–180% (C200F) or 42–150% (CF400) higher, phosphatase enzyme activity was 29–32% higher with C200F, and urease enzyme activity was 37–38% higher at C400F, indicating greater soil biological activity at lower application rates. Conclusion Overall, CNM (200–400 mgkg −1 soil) promoted lettuce growth, enhanced soil fertility and soil biological activity, elucidating that water-dispersible CNM can be an alternative soil amendment to improve crop growth and soil biochemical quality.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-022-05852-0