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@article{179792,
        author = {N. SRUTHILAYA and T. WASIMA},
        title = {ELECTRON FLOW OPTIMIZATION AND MODULAR SYSTEM INTEGRATION FOR IMPROVED PERFORMANCE},
        journal = {International Journal of Innovative Research in Technology},
        year = {2025},
        volume = {11},
        number = {12},
        pages = {8407-8411},
        issn = {2349-6002},
        url = {https://ijirt.org/article?manuscript=179792},
        abstract = {This project aims to enhance the efficiency, resilience, and sustainability of space systems for future missions. It focuses on optimizing electron flow within propulsion systems to reduce energy consumption while increasing thrust, and improving fuel management through advanced computational techniques to minimize waste and costs. Material resilience is also evaluated to ensure system durability against extreme temperatures, radiation, and pressure fluctuations in space.
Advanced simulation models are employed to assess propulsion efficiency, fuel utilization, and material performance under realistic space conditions, guiding the optimization of system designs. Additionally, the project integrates Secure Multi-Party Computation (SMC), a cryptographic technique that enables multiple agencies to collaboratively analyze sensitive mission data without exposing private inputs.
By combining propulsion, fuel management, material testing, and secure data collaboration, the project aims to contribute significantly to the development of energy-efficient, cost-effective, and resilient space technologies, advancing the overall success and sustainability of future space exploration.},
        keywords = {},
        month = {May},
        }