An uncharged parallel plate capacitor having a dielectric of constant K is connected to a similar air-cored parallel capacitor charged to a potential V. The

Q: An uncharged parallel plate capacitor having a dielectric of constant $K$ is connected to a similar air-cored parallel capacitor charged to a potential $V$. The two share the charge and the common potential is $V'$. The dielectric constant $K$ is

d $\mathrm{V}^{\prime}=\frac{\mathrm{C}_{1} \mathrm{V}_{1}+\mathrm{C}_{2} \mathrm{V}_{2}}{\mathrm{C}_{1}+\mathrm{C}_{2}}=\frac{\mathrm{CV}+\mathrm{KC0}}{\mathrm{C}(\mathrm{K}+1)}$ $\mathrm{V}^{\prime}=\frac{\mathrm{V}}{\mathrm{K}+1} \Rightarrow \mathrm{K}=\frac{\mathrm{V}-\mathrm{V}^{\prime}}{\mathrm{V}^{\prime}}$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

An uncharged parallel plate capacitor having a dielectric of constant $K$ is connected to a similar air-cored parallel capacitor charged to a potential $V$. The two share the charge and the common potential is $V'$. The dielectric constant $K$ is

A$\frac{{V' - V}}{{V' + V}}$
B$\frac{{V' - V}}{{V'}}$
C$\frac{{V' - V}}{{V}}$
D$\frac{{V - V'}}{{V'}}$

Medium

STD 11 Science
NEET
STD 12 - 2. Electric potential and capacitance
Physics

Download our app
and get started for free

Experience the future of education. Simply download our apps or reach out to us for more information. Let's shape the future of learning together!No signup needed.*

Download App

Similar Questions

1
Given,

${R_1} = 1\,\Omega $ $C_1 \,= 2\,\mu F$

${R_2} = 2\,\Omega $ $C_2 \,= 4\,\mu F$

The time constants ( in $\mu\, s$) for the circuits $I, II, III$ are respectively
View Solution
2
This question has Statement $-1$ and Statement $-2$ Of the four choices given after the Statements, choose the one that best describes the two Statements

Statement $1$ : No work is required to be done to move a test charge between any two points on an equipotential surface

Statement $2$ : Electric lines of force at the equipotential surfaces are mutually perpendicular to each other
View Solution
3
Four identical charges $ + \,50\,\mu C$ each are placed, one at each corner of a square of side $2\,m$. How much external energy is required to bring another charge of $ + \,50\,\mu C$ from infinity to the centre of the square......$J$ $\left( {{\rm{Given}}\frac{{\rm{1}}}{{{\rm{4}}\pi {\varepsilon _{\rm{0}}}}} = 9 \times {{10}^9}\,\frac{{N{m^2}}}{{{C^2}}}} \right)$
View Solution
4
In a region, electric field varies as $E = 2x^2 -4$ where $x$ is the distance in metre from origin along $x-$ axis. A positive charge of $1\,\mu C$ is released with minimum velocity from infinity for crossing the origin, then
View Solution
5
A parallel-plate capacitor consists of a fixed plate and a movable plate that is allowed to slide in the direction parallel to the plates. Let $x$ be the distance of overlap, as shown in the figure. The separation between the plates is fixed. Assume that the plates are electrically isolated, so that their charges $±Q$ are constant. Force on the movable plate is proportional to
View Solution
6
Figure shows a positively charged infinite wire. $A$ particle of charge $2C$ moves from point $A$ to $B$ with constant speed. (Given linear charge density on wire is $\lambda = 4 \pi \varepsilon_0$)
View Solution
7
A negative point charge placed at the point $A$ is
View Solution
8
A $400\, pF$ capacitor is charged with a $100\, V$ battery. After disconnecting battery this capacitor is connected with another $400\, pF$ capacitor. Then find out energy loss.
View Solution
9
Find the equivalent capacitance of the circuit between point $A$ and $B$.
View Solution
10
In the given figure the capacitors ${C_1},{C_3},{C_4},{C_5}$ have a capacitance $4\,\mu F$ each if the capacitor $C_2$ has a capacitance $10\,F$, then effective capacitance between $A$ and $B$ will be.....$\mu F$
View Solution

Download our appand get started for free

Similar Questions

Download our app
and get started for free