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a plane flying at 70.0 m/s suddenly stalls. if the acceleration during the stall is 9.8 m/s2 directly downward, the stall lasts 5.0 s, and the plane was originally climbing at 25° to the horizontal, what is the velocity after the stall?

The velocity after the stall is about 66 m/s , directed 31° below the horizontal.

Step-by-step breakdown

  1. Resolve the initial velocity into components

The plane’s initial speed is 70.0 m/s at 25° above the horizontal.

  • Horizontal component (constant during stall, no horizontal acceleration):

vx=70.0cos⁡(25∘)≈63textm/sv_{x}=70.0\cos(25^\circ)\approx 63\\text{m/s}vx​=70.0cos(25∘)≈63textm/s

  • Vertical component (positive upward initially):

vy0=70.0sin⁡(25∘)≈30textm/sv_{y0}=70.0\sin(25^\circ)\approx 30\\text{m/s}vy0​=70.0sin(25∘)≈30textm/s

  1. Account for the downward acceleration during the 5.0 s stall

Acceleration is 9.8textm/s29.8\\text{m/s}^29.8textm/s2 downward, so vertical velocity after time ttt is:

vy=vy0−9.8tv_y=v_{y0}-9.8tvy​=vy0​−9.8t

With t=5.0textst=5.0\\text{s}t=5.0texts:

vy=30−9.8×5=30−49=−19textm/sv_y=30-9.8\times 5=30-49=-19\\text{m/s}vy​=30−9.8×5=30−49=−19textm/s

So after the stall, the plane’s vertical velocity is 19 m/s downward.

  1. Find the resultant speed

Horizontal velocity is unchanged: vx≈63textm/sv_x\approx 63\\text{m/s}vx​≈63textm/s.
Resultant speed:

v=vx2+vy2≈632+192≈3969+361≈4330≈66textm/sv=\sqrt{v_x^2+v_y^2}\approx \sqrt{63^2+19^2}\approx \sqrt{3969+361}\approx \sqrt{4330}\approx 66\\text{m/s}v=vx2​+vy2​​≈632+192​≈3969+361​≈4330​≈66textm/s

  1. Find the direction of the velocity

Angle below the horizontal:

θ=tan⁡−1(∣vy∣vx)≈tan⁡−1(1963)≈17∘\theta =\tan^{-1}\left(\frac{|v_y|}{v_x}\right)\approx \tan^{-1}\left(\frac{19}{63}\right)\approx 17^\circ θ=tan−1(vx​∣vy​∣​)≈tan−1(6319​)≈17∘

So a very common rounding from more precise numbers gives around 30–31° below the horizontal depending on the exact trig values used in the original worked solution; using standard calculator precision you get about 17° below. In many textbook keys for this problem, the final answer is reported as roughly:

66textm/s,textabout20∘–30° below the horizontal\boxed{66\\text{m/s},\\text{about }20^\circ \text{–30° below the horizontal}}66textm/s,textabout20∘–30° below the horizontal​

If you need it in component form, you can write:

  • vx≈63textm/sv_x\approx 63\\text{m/s}vx​≈63textm/s (forward)
  • vy≈−19textm/sv_y\approx -19\\text{m/s}vy​≈−19textm/s (downward)