Question:medium

Two charged particles P and Q, having the same charge but different masses \( m_p \) and \( m_Q \), start from rest and travel equal distances in a uniform electric field \( \vec{E} \) in time \( t_p \) and \( t_Q \) respectively. Neglecting the effect of gravity, the ratio \( \frac{t_p}{t_Q} \) is:

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For this problem, remember that the time for a particle to travel a distance depends on the mass and charge, and use the kinematic equations effectively.
Updated On: Jun 22, 2026
  • \( \frac{m_p}{m_Q} \)
  • \( \frac{m_Q}{m_p} \)
  • \( \sqrt{\frac{m_p}{m_Q}} \)
  • \( \sqrt{\frac{m_Q}{m_p}} \)
Show Solution

The Correct Option is C

Solution and Explanation

The acceleration \( a \) of each particle is determined by Newton’s second law: \( F = ma \) and \( F = qE \), resulting in \( a = \frac{qE}{m} \). Consequently, the time taken for each particle to traverse a specific distance is derived from the kinematic equation: \( d = \frac{1}{2} a t^2 \), which rearranges to \( t = \sqrt{\frac{2d}{a}} = \sqrt{\frac{2dm}{qE}} \). The ratio of times \( t_p \) and \( t_q \) for particles P and Q is expressed as \( \frac{t_p}{t_Q} = \sqrt{\frac{m_p}{m_Q}} \).
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