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Thrust vectoring is a technology that allows an aircraft or rocket engine to direct its exhaust in different directions, giving it extraordinary control and maneuverability. Instead of relying only on wings or fins, the engine itself helps steer the vehicle, enabling sharp turns, stable hovering, and advanced aerial movements... show more

Mechanical Knowledge

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An SU-34 closes in, hot on the tail of a Saab JAS 39 Gripen. The Sukhoi SU-35 stands as one of Russia’s most formidable fighter jets, renowned for its sheer size and striking presence in the sky. Its twin engines, broad wingspan, and aggressive silhouette make it tower over lighter fighters like the Saab JAS 39 Gripen, projecting dominance both on the ground and in flight. The SU-35’s design balances raw power with refined aerodynamics, creating a jet that is as agile as it is visually imposing. Developed in the late 2000s as an advanced evolution of the SU-27, the SU-35 features thrust-vectoring engines that enable maneuvers beyond the capabilities of most aircraft. It can exceed Mach 2.25 and fly nearly 2,200 miles without refueling. Its sophisticated radar can track up to 30 targets simultaneously and engage multiple threats at once, making the SU-35 not just a giant of the skies, but a precision predator in combat.

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