Advertisements
Advertisements
प्रश्न
Two particles A and B with charges q and 2q, respectively, are placed on a smooth table with a separation d. A third particle C is to be clamped on the table in such a way that the particles A and B remain at rest on the table under electrical forces. What should be the charge on C and where should it be clamped?
उत्तर
For equilibrium,
\[\text{Again }, \vec{F}_{AC} = \vec{F}_{CB} \]
\[\text{So} , \frac{1}{x^2} = \frac{2}{\left( d - x \right)^2}\]
\[\text{Or 2 x}^2 = \left( d - x \right)^2 \]
\[ \text{Or }\sqrt{2}x = d - x\]
\[ \text{Or x } = (\sqrt{2} - 1)d\]
For a charge at rest,
\[\vec{F}_{AC} = \vec{F}_{CB} \]
\[\frac{1}{4\pi \in_0}\frac{q\theta}{[(\sqrt{2} - 1)d ]^2} + \frac{1}{4\pi \in_0}\frac{q \times 2q}{d^2}\]
\[ = 0\]
\[ \text{ Or } \theta = (6 - 4\sqrt{2})q\]
APPEARS IN
संबंधित प्रश्न
A proton and an electron are placed in a uniform electric field.
Two particles A and B, each with a charge Q, are placed a distance d apart. Where should a particle of charge q be placed on the perpendicular bisector of AB, so that it experiences maximum force? What is the magnitude of this maximum force?
A positively charged glass rod is brought close to a metallic rod isolated from ground. The charge on the side of the metallic rod away from the glass rod will be ______.
Choose the correct option.
An electron is placed between two parallel plates connected to a battery. If the battery is switched on, the electron will
Two parallel plates have a potential difference of 10 V between them. If the plates are 0.5 mm apart, what will be the strength of electric charge.
When 1019 electrons are removed from a neutral metal plate through some process, the electric charge on it is ______
When a glass rod is rubbed with silk, it ______.
Which of the following graphs shows the variation of electric field E due to a hollow spherical conductor of radius R as a function of distance from the centre of the sphere?
Which one of the following is the unit of electric charge?
A positive charge particle of 100 mg is thrown in opposite direction to a uniform electric field of strength 1 × 105 NC–1. If the charge on the particle is 40 μC and the initial velocity is 200 ms-1, how much distance it will travel before coming to the rest momentarily ______.
Given below are two statements:
- Statement I: The electric force changes the speed of the charged particle and hence changes its kinetic energy; whereas the magnetic force does not change the kinetic energy of the charged particle.
- Statement II: The electric force accelerates the positively charged particle perpendicular to the direction of the electric field. The magnetic force accelerates the moving charged particle along the direction of the magnetic field.
In light of the above statements, choose the most appropriate answer from the options given below.
A certain charge Q is divided into two parts q and (Q - q). How should the charges Q and q be divided so that q and (Q - q) placed at a certain distance apart experience maximum electrostatic repulsion?
A straight infinitely long cylinder of radius R0 = 10 cm is uniformly charged with a surface charge density σ = + 10-12 C/m2. The cylinder serves as a source of electrons, with the velocity of the emitted electrons perpendicular to its surface. Electron velocity must be ______ × 105 m/s to ensure that electrons can move away, from the axis of the cylinder to a distance greater than r = 103 m.
A particle of mass m and charge q is placed at rest in a uniform electric field E and then released. The kinetic energy gained by the particle after moving a distance of y will be ______.
A charge of magnitude 3e and mass 2m is moving in an electric field E. The acceleration imparted to the charge is ______.
Two particles A and B having the same mass have charges +q and +4q, respectively. When they are allowed to fall from rest through the same electric potential difference the ratio of their speeds vA to vB will become ______.
