Q.23 A particle starting from rest is subjected to a constant force. The plot of distance traveled along the direction of the force as a function of time is a/an ______. (A) straight line (B) circle (C) parabola (D) ellipse

Q.23 A particle starting from rest is subjected to a constant force. The plot of distance traveled along the
direction of the force as a function of time is a/an ______.
(A) straight line (B) circle (C) parabola (D) ellipse

Particle motion under constant force starts from rest, producing uniform acceleration key to competitive physics questions. The distance time graph constant acceleration from rest reveals parabolic shape through \( s = \frac{1}{2}at^2 \).

Correct Answer Explanation

The correct answer is (C) parabola. A particle starting from rest under constant force experiences constant acceleration, resulting in a quadratic distance-time relationship that plots as a parabola.

Kinematics Equation

Constant force \( F \) produces constant acceleration \( a = \frac{F}{m} \) (Newton’s second law). With initial velocity \( u = 0 \), distance \( s = \frac{1}{2}at^2 \). This quadratic equation \( s \propto t^2 \) yields a parabolic curve on a distance (y-axis) vs. time (x-axis) graph.

Option Analysis

  • (A) Straight line: Indicates constant speed (\( s = vt \)), not acceleration from rest.
  • (B) Circle: Represents closed periodic motion (e.g., uniform circular), irrelevant for linear force direction.
  • (C) Parabola: Matches \( s = \frac{1}{2}at^2 \); velocity-time is linear, integrating to parabola.
  • (D) Ellipse: Applies to orbital paths, not straight-line constant force motion.

Graph Derivation

Velocity builds linearly: \( v = at \). Distance integrates velocity: \( s = \int v \, dt = \frac{1}{2}at^2 \). Quadratic form confirms parabola, steeper with time as speed rises.

Common Misconceptions

Straight lines suggest uniform motion, absent here. Circles/ellipses suit 2D orbits, not 1D force along a line.

Exam Relevance

CSIR NET-style MCQs test this: options distinguish constant speed (line) from acceleration (parabola).

 

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