Central to the transformative endeavor of quantum communication are entangled states, the fundamental building blocks that ensure data security through unassailable encryption. The tripartite entangled W-state stands out for its high degree of entanglement and resilience against decoherence, making it a key player in this domain. Despite its importance, there is a scarcity of simulation prototypes or experimental proofs demonstrating its effectiveness in practical applications. Additionally, the correlation/fusion of W-states with Local Operations and Classical Communication (LOCC) protocols to enhance communication efficiency has not been extensively explored. Optimizing W-state-based communication protocols for diverse applications, especially splitting and sharing of quantum information, remains an active research area. The pivotal aspect of our research is the integration of perfect W-states with LOCC, creating a synergy that significantly boosts the effectiveness and security of quantum communication systems. We propose a prototype/protocol for quantum information sharing and splitting (QISS) using LOCC by experimentally creating and controlling the W-states. We also delve into generating and utilizing tripartite W-states via quantum circuits, underscoring their applications in quantum computing, error correction, and secure data transmission. The effectiveness and performance of the proposed protocol are quantified using quantum state tomography. Employing superconducting qubits (Eagle r3 processor), our results demonstrate a fidelity of 0.82 ± 0.02 for the W-state circuit and 0.55 ± 0.03 for the combined W-state + LOCC in QISS communication process, under controlled experimental conditions. These findings have significant implications for the development of secure communication systems. Furthermore, our work paves the way for future research into scalable quantum networks and advanced quantum encryption methods, marking a substantial stride in the realm of quantum communication.