Cyclic stability is a crucial metric for assessing the service lifespan of supercapacitors, as it determines the retention capacity of the electrode material. This study demonstrates the significant impact of Carbon Nanotubes (CNT) on enhancing the cyclic stability of a binary hybrid MoO2/MoS2 (MOS) electrode material, thereby improving supercapacitor performance and durability. The combination of MoO2 and MoS2 enhances capacitance due to their high surface area and electrical conductivity. Introducing CNTs into MOS significantly enhances cyclic stability and provides a crucial pathway for electrolyte ions during charging-discharging cycles, despite a minor compromise in conductivity and energy efficiency. This trade-off is justified by the substantial improvement in overall performance and durability. The materials were synthesized and deposited on Nickel foam via a hydrothermal route without any binding agent. Electrochemical tests showed specific capacitances of 2617 F/g for MOS and 2052 F/g for MOSC at a current density of 1 A/g. The MOSC system exhibited a 41.4 % increase in cyclic stability after 2000 cycles. Additionally, a symmetric coin cell device fabricated with the MOSC material demonstrated a maximum energy density of 153.41 mWh/kg and a power density of 3 kW/kg at a current density of 0.05 A/g, with a capacitive retention of 74.05 %. This underscores the potential of MOSC as a scalable electrode material for industrial energy storage applications.