gt h, where g is the gravitational pull and h is the nitial height.) Suppose a NASA rover on Mars throws a baseball upward with an initial velocity of 10 meters per second, letting go of the ball 2 meters above the ground. Since the gravity stuff works different on Mars, it will take longer for the baln to land. How much longer will the ball stay in the air on Mars? The answer to this question rounded to the nearest tenth is equal to A. 3.7 m/s2 cceleration due to gravity Jertical Motion Equation 9.8 m/s2

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Scene 6 conquering device. The final note was left on the stall of a NASA restroom. The final text Kennedy Space Center NASA was rocked when the entire facility was hit with a bioweapon. Calcuu Paraboloid used Florida, USA -- CO opportunity to steal a space shuttle Presumably, this is the final piece of nis wO message followed. Derore you know it, the Mathemagicians are finally going to conquer the world! For my last puzzie, Mars Rover baseball toss problem! (Vertical Motion Equations: The height H of an object t seconds after it is propelled upward with an Intial velocity v represented by H = -% gt2 + vt + h, where g is the gravitational pull and h is the initial height.) Suppose a NASA rover on Mars throws a baseball upward with an initial velocity of 10 meters per second, letting go of the ball 2 meters above the ground. Since the gravity stuff works different on Mars, it will take longer for the bal to land, How much longer will the ball stay in the air on Mars? The answer to this question rounded to the nearest tenth is equal to A. 9.8 m/s2 3.7 m/s2 Acceleration due to gravity Vertical Motion Equation When does the baseball hit the ground? a =