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JUPITER SCIENCE

IIT JEE Particle Motion Numericals

iit jee particle motion : Charged Particle Motion Numericals for IIT JEE : Problems on particles in E and B fields.

IIT JEE particle motion numericals challenge students to apply electromagnetic principles in dynamic scenarios. This guide delves into solving problems involving charged particles in electric and magnetic fields, enhancing your preparation with clear explanations and practical examples.



IIT JEE particle motion problems often involve charged particles in electromagnetic fields, testing understanding of forces and circular motion. Mastery requires solving numericals with precision and conceptual clarity.

Analyzing Charged Particle Dynamics

When a charged particle enters a magnetic field, it experiences a force perpendicular to its velocity, leading to circular motion. This fundamental principle is key to solving IIT JEE problems.

Force and Motion Equations

The magnetic force on a charged particle is given by ##\vec{F} = q(\vec{v} \times \vec{B})##, where q is charge, v is velocity, and B is magnetic field strength. This force provides the centripetal acceleration for circular motion.

For a particle of mass m moving in a circle of radius r, the centripetal force is ##\frac{mv^2}{r}##. Equating this to the magnetic force gives the radius formula: ##r = \frac{mv}{qB}##.

Application to Given Problem

In the provided numerical, a particle with charge q = 1 μC (or ##1 \times 10^{-6}## C), mass m = 10⁻⁶ kg, enters a magnetic field B = 0.1 T with velocity v = 100 m/s. Substituting into the formula: ##r = \frac{(10^{-6}) \times 100}{(1 \times 10^{-6}) \times 0.1} = \frac{0.0001}{0.0000001} = 1000## meters.

This result indicates a radius of 1000 meters, showcasing how even small charges and masses can lead to large paths in weak fields, a common trick in IIT JEE questions.

Expanding Beyond Basic Calculations

Beyond simple radius finding, IIT JEE often integrates electric fields or non-uniform conditions, demanding deeper analysis.

Incorporating Electric Fields

When both electric and magnetic fields are present, the net force alters the motion. For example, if an electric field E is applied, the total force is ##q(\vec{E} + \vec{v} \times \vec{B})##, leading to helical or linear paths.

This complexity requires vector addition and understanding of Lorentz force, a staple in advanced IIT JEE problems that test multidimensional thinking.

Real-World Implications

In particle accelerators like cyclotrons, similar principles are used to control particle beams. The radius calculation helps in designing magnetic fields to achieve desired particle energies and paths.

Such applications highlight the practical importance of these numericals, linking textbook problems to cutting-edge technology in physics and engineering.

Key Takeaways

Mastering charged particle motion in fields is essential for IIT JEE success. Practice varied numericals to build intuition and speed, ensuring you can handle any twist in the exam.

Parameter Value Description
Charge (q) 1 μC Microcoulomb charge of the particle
Mass (m) 10⁻⁶ kg Mass in kilograms
Magnetic Field (B) 0.1 T Tesla strength of the magnetic field
Velocity (v) 100 m/s Speed in meters per second
Radius (r) 1000 m Calculated path radius using r = mv/(qB)


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