Sahitya's Isolated Flesh Experiment SIFE thesis

This project explores the **fundamental principles of mass-energy conservation** through a highly controlled and conceptual physics experiment termed **"Sahitya's Isolated Flesh Experiment."** The experiment involves placing **two identical samples**—one biological (a 1kg piece of flesh) and one inert (a 1kg standardized weight)—into identical, perfectly sealed vacuum-tight containers that are **engineered to prevent any kind of physical, chemical, or biological interaction** with the external environment. The system is equipped with an innovative **torque-neutralizing machine** designed to counteract the Earth’s natural rotational torque, thus minimizing inertial effects. Once initial conditions are precisely set to ensure **zero mass difference**, the system is left undisturbed for a period equivalent to the normal biological decomposition timeline. Subsequent setups manipulate external **rotational dynamics** and **thermal gradients** to test whether motion or environmental asymmetry can induce any internal transformation in the isolated mass. The project is extended through two critical scenarios: 1. **Mechanical Manipulation** — including rotational torque doubling and motion-cancelled conveyor dynamics 2. **External Thermal Gradients** — involving rising temperatures at the base and falling temperatures at the top of the environmental chamber Across all scenarios, the results consistently demonstrate that **no mass loss, decomposition, or internal energy transformation occurs**, reinforcing the universal law that **mass and energy are strictly conserved in a perfectly isolated system**. By modeling this with modern physics principles and ideal isolation conditions, this project provides **conceptual clarity and empirical reasoning** about the **immutability of conservation laws**, even in biologically active matter, unless external influence is introduced. It challenges perceptions of decay as intrinsic and emphasizes its dependence on environmental interactions—marking a unique contribution to thought-based experimental physics. <br>