Bacteria, which has been effectively documented to increase salt strain tolerance by inducing systemic tolerance [162]. Current study also draws emphasis on the usage of `Biochar’ (strong carbonaceous residue) as a sustainable ameliorant because it really is very helpful in reclaiming physico-chemical and biological properties of salinity and sodicity affected soils [163,164]. 9. Conclusions Salinity and sodicity have an effect on the productivity of irrigated lands and pose among the major environmental and resource-related challenges facing the globe now. Unscientific cultivation practices and soil degradation by salinization and sodification alter the physiochemical properties of your soil, minimize infiltration rates, boost the surface runoff, and significantly decrease agricultural yield. Salinity and sodicity influence the underlying aquifers via the leaching of salts, contaminating groundwater both locally and regionally. The management of saline and sodic soils demands various sources and strategies, which includes the usage of non-saline or less saline water for irrigation, improvement of suitable drainage facilities (artificial drainage), inorganic or mineral amendments, the addition of soil ameliorants, and cultivation of salt-tolerant crops. Integrated soil fertility management practices (based on agronomic principles for sustainable agriculture) show promising prospects in mitigating the hazardous effects of salinity and sodicity on soil and groundwater than conventional unsustainable irrigation practices. Contemporary technological solutions, for instance Electromagnetic Induction sensors, can swiftly analyze the extent of in situ salinity, and satellite remote sensing approaches can aid in the large-scale mapping of Choline (bitartrate) GPCR/G Protein salinity-affected lands. There’s a have to have to get a standard understanding of processes contributing to salinity and sodicity of soils regionally and involve relevant stakeholders, principally the farmers and public institutions (government agencies and research institutions) for the expansion, adoption, and awareness about accessible technologies for the remediation or reclamation of impacted lands. Early realization of symptoms (either visual, physical, biological, chemical, or integrative) of salt-affected soils help in locating regions exactly where prospective fertility challenges could occur. Large-scale land reclamation projects as well as the adoption of sophisticated approaches of water application could partially or solely inhibit the risk of salinity hazards. Furthermore, its equally crucial to quantify the ecological, agricultural, and socio-economic impacts of soil degradation resulting from salinity/sodicity and create novel technologies to effectively handle and mitigate the hazardous effects of salinity and sodicity on soil and groundwater for sustaining future food and water sustainability.Author Contributions: Conceptualization, A.M. and S.R.N.; Writing–original draft, A.M.; Writing– assessment and editing, S.R.N. along with a.M.; Literature critique, A.M.; Supervision, S.R.N.; Funding acquisition, N.A.-A. All authors have study and agreed for the published version of the manuscript. Funding: The APC was funded by Lulea University of Technologies, Sweden. Institutional Overview Board Statement: Not Applicable. Information SS-208 Purity & Documentation Availability Statement: Information sharing just isn’t applicable to this short article as no new data had been made or analyzed in this study. Acknowledgments: The authors would like to express good appreciation to Yusuf Jameel from the Division of Civil and Environmental Enginee.