AUTHOR=Harish M. N. , Choudhary Anil K. , Bhupenchandra Ingudam , Dass Anchal , Rajanna G. A. , Singh Vinod K. , Bana R. S. , Varatharajan T. , Verma Parkash , George Saju , Kashinath G. T. , Bhavya M. , Chongtham S. K. , Devi E. Lamalakshmi , Kumar Sushil , Devi Soibam Helena , Bhutia Tshering Lhamu 

TITLE=Double zero-tillage and foliar-P nutrition coupled with bio-inoculants enhance physiological photosynthetic characteristics and resilience to nutritional and environmental stresses in maize–wheat rotation

JOURNAL=Frontiers in Plant Science

VOLUME=13

YEAR=2022

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2022.959541

DOI=10.3389/fpls.2022.959541

ISSN=1664-462X

ABSTRACT=<p>Conventionally tilled maize–wheat cropping system (MWCS) is an emerging cereal production system in semi-arid region of south-Asia. This system involves excessive tillage operations that result in numerous resource- and production-vulnerabilities besides impeding environmental-stresses. Likewise, phosphorus is a vital nutrient that limits crop growth and development. It’s a matter of great concern when ∼80% of Indian soils are low to medium in available-P due to its sparing solubility, resulting in crop stress and low yields. Hence, crop productivity, photosynthetic parameters and resilience to nutritional and environmental stresses were assessed in a MWCS using four crop-establishment and tillage management (CETM) practices [FBCT-FBCT (Flat bed-conventional tillage both in maize and wheat); RBCT-RBZT (Raised bed-CT in maize and raised bed-zero tillage in wheat); FBZT-FBZT (FBZT both in maize and wheat); PRBZT-PRBZT (Permanent raised bed-ZT both in maize and wheat)], and five P-fertilization practices [P<sub>100</sub> (100% soil applied-P); P<sub>50</sub>+2FSP (50% soil applied-P + 2 foliar-sprays of P through 2% DAP both in maize and wheat); P<sub>50</sub>+PSB+AM-fungi; P<sub>50</sub>+PSB+AMF+2FSP; and P<sub>0</sub> (100% NK with no-P)] in split-plot design replicated-thrice. The results indicated that double zero-tilled PRBZT–PRBZT system significantly enhanced the grain yield (6.1; 5.4 t ha<sup>–1</sup>), net photosynthetic rate (Pn) (41.68; 23.33 μ mol CO<sub>2</sub> m<sup>–2</sup> s<sup>–1</sup>), stomatal conductance (SC) (0.44; 0.26 mol H<sub>2</sub>O m<sup>–2</sup> s<sup>–1</sup>), relative water content (RWC) (83.3; 77.8%), and radiation-use efficiency (RUE) (2.9; 2.36 g MJ<sup>–1</sup>) by 12.8–15.8 and 8.5–44.4% in maize and wheat crops, respectively over conventional tilled FBCT–FBCT. P<sub>50</sub>+PSB+AMF+2FSP conjugating soil applied-P, microbial-inoculants and foliar-P, had significantly higher Pn, SC, RUE and RWC over P<sub>100</sub> besides saving ∼34.7% fertilizer-P under MWCS. P<sub>50</sub>+PSB+AMF+2FSP practice also had higher NDVI, PAR, transpiration efficiency and PHI over P<sub>100</sub>. Whereas lower stomatal limitation index (Ls) was observed under PRBZT–PRBZT system as compared to the conventional FBCT–FBCT system indicating that P is the limiting factor but not stomata. Hence, optimum P supply through foliar P-fertilization along with other sources resulted in higher grain yield by 21.4% over control. Overall, double zero-tilled PRBZT–PRBZT with crop residue retention at 6 t/ha per year, as well as P<sub>50</sub>+PSB+AMF+2FSP in MWCS, may prove beneficial in enhancing the crop productivity and, thereby, bolstering food security in semi-arid south-Asia region.</p>