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. 2024 Sep 30;24(1):908.
doi: 10.1186/s12870-024-05569-5.

Elucidating morphogenic and physiological traits of rice with nitrogen substitution through nano-nitrogen under salt stress conditions

Ashwani Kumar  1 Parvender Sheoran  2   3 Naresh Kumar  4   5 Sunita Devi  4 Arvind Kumar  4 Kapil Malik  4 Manu Rani  4 Ajay Kumar Bhardwaj  4 Anita Mann  6
Affiliations

Elucidating morphogenic and physiological traits of rice with nitrogen substitution through nano-nitrogen under salt stress conditions

Ashwani Kumar et al. BMC Plant Biol. .

Abstract

Background: Sustainable crop production along with best nutrient use efficiency is the key indicator of smart agriculture. Foliar application of plant nutrients can complement soil fertilization with improved nutrient uptake, translocation and utilization. Recent developments in slow releasing, nano-fertilizers in agriculture, begins a new era for sustainable use and management of natural resources. This study aims to explore the effectiveness of nano-nitrogen usage on plant growth, yield attributes and sustaining rice production while optimizing fertilizer N application through conventional (prilled urea) and nano-N source under salt stress conditions.

Results: The strategic substitutions of traditional urea by nano-nitrogen was distributed from partial to complete with 33, 50, 66 and 100% applications. Further, the strategic substitutions were compared in saline (ECe ∼ 6.0 dSm- 1) and sodic stress (pH ∼ 9.1) conditions along with normal soils to dissect the beneficial response of nano-N in two rice varieties (CSR 30 and PB 1121). Salt stress affected the plant performance by decreasing leaf relative water content upto 10%, total chlorophyll content by 1.3-1.5%, leaf area upto 29.9%, gas exchange attributes by 10-39%, with concomitant yield reductions upto ∼ 4%. Collateral improvement in leaf greenness (SPAD index) crop growth rate and net assimilation rate was observed with foliar application of Nano-N. 0.2-1.64% enhancement in growth traits, 0.93-1.85% in physiological traits, and comparable yield gains with 100% recommended dose of prilled were comparative with nano-substitutions. Salt tolerant rice variety, CSR-30 performed better than PB 1121 with better expression of morphological, physiological and yield traits under stress conditions and nitrogen substitutions.

Conclusions: Overall, our experimental findings revealed agricultural use of nano-N in improving the plant physiological efficiency and optimizing rice yields with partial N substitution through nano fertilizers under salt stress conditions. These studies are further open for futuristic aspects of long term effects of nano-fertilizers on soil nutrient depletion in correlation to yield enhancement in salt affected soils.

Keywords: Basmati rice; CSR-30; Nano-nitrogen; PB1121; Physiological traits; Salinity.

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Conflict of interest statement

The authors declare no competing interests.

Figures

Fig. 1
Fig. 1
Circos plot depicting the interactive effect of different N substitutions on grain and biological yield of rice under salt stress conditions. Columns A-F and G-L represents N substitutions as N0, NRD, N33, N50, N66, N100 for variety Pusa 1121 and variety, CSR-30 under normal (M), sodic (N) and saline (O) stress treatments, respectively
Fig. 2
Fig. 2
Pearson correlation matrix between different parameters of crop growth and yield under no-stress (red color), salinity stress (green color) and sodicity stress (blue color).*, **, and *** significant at p < 0.05, p < 0.01, and p < 0.001, respectively. (PH -plant height; Chl-chlorophyll; LA-leaf area; RWC-relative water content; Pn-photosynthesis; gS-stomatal conductance; E-transpiration; WUE- instantaneous water use efficiency; RGR- relative growth rate; CGR- comparative growth rate; NAR- net assimilation rate grain; NT- number of total tillers; NET-number of effective tillers; BY-biological yield; GY-grain yield
See this image and copyright information in PMC

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