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CBSE Class 12th Hindi Notes Summary of All Chapters | Aroh Vitan Class 12 Hindi Chapters Summary

January 5, 2022April 15, 2021 by Veer

Studying from CBSE Class 12th Hindi Core Aroh Vitan Notes Summary of All Chapters Pdf Download helps students to prepare for the exam in a well-structured and organised way. Making Class 12 Hindi Aroh Vitan Chapters Summary saves students time during revision as they don’t have to go through the entire textbook. In CBSE Notes, students find the summary of the complete chapters in a short and concise way. Students can refer to the NCERT Solutions for Class 12 Hindi, to get the answers to the exercise questions.

Class 12th Hindi Notes | Class 12 Hindi Chapters Summary Aroh Vitan

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Magnetism and Matter Class 12 Notes Physics Chapter 5

January 5, 2022April 15, 2021 by Prasanna

By going through these CBSE Class 12 Physics Notes Chapter 5 Magnetism and Matter, students can recall all the concepts quickly.

Magnetism and Matter Notes Class 12 Physics Chapter 5

→ Magnetic induction (B) and magnetic intensity (H) are related as B = μH.

→ B is expressed in testa (T) and gauss (G) in S.I. and C.G.S. systems respectively.

→ H in a vacuum is expressed in overstated (C.G.S. system) and Am^-1 in S.I. system.

→ The angle of dip at poles is 90° and at the equator, it is zero.

→ S.I. unit of pole strength (m) is NT^-1 or Am.

→ The value of angle of dip and declination not only charges from place to place but also at the same place, they change from time to time.

→ Diamagnetism originates from the magnetic moment associated with the orbital motion of electrons.

→ Paramagnetism and Ferromagnetism are associated with the magnetic moment of the spinning electrons.

→ Ferromagnetism depends on temperature. It decreases with an increase in temperature. At a certain temperature called the curie point, the ferromagnetic substance is converted into a paramagnetic substance.

→ The magnetic lines of force always form closed and continuous loops both inside and outside the bar magnet.

→ The magnetic susceptibility of a diamagnetic substance is independent of temperature.

→ The hysteresis cycle for the core of a transformer should be narrow and large in height.

→ The end of the freely suspended magnet pointing towards the north of the earth is called the north pole of the magnet and the end pointing towards the south pole is called the south pole of the magnet.

→ The north and south pole of a magnet is always of equal strength.

→ Monopole never exists.

→ For all purposes, we can consider the magnetic field of a bar magnet and a straight solenoid to be identical.

→ The field inside the solenoid is stronger than the field inside a bar magnet.

→ The earth’s magnetic field at any place is a vector quantity and it requires three parameters to describe it. These are called magnetic elements of the earth.

→ 1 G = 10^-4 T.

→ 10 posted = 80 Am^-1.

→ The geometric length of a magnet is always more than the magnetic length.

→ A magnetic dipole is the simplest magnetic structure that is known to exist in nature.

→ The strength of the magnetic field of a solenoid can be increased or decreased by adjusting the current and the direction of the magnetic field can be changed by changing the direction of the current.

→ S I. unit of magnetic dipole moment is Joule/tesla (JT^-1) or Weber- meter (Wb-m) or Ampere metre² (Am²).

→ S.I. unit of magnetic flux is weber (Wb).

→ S.I. unit of magnetic permeability (p) is Tm^-1 A.

→ X_m has no units.

→ Another S.I. unit of magnetic intensity (H) is N Wb^-1.

→ S.I. unit of Intensity of magnetization (I) is Am^-1.

→ S.I. unit of Torque and P.E. is Joule (J).

→ S.I. unit of energy dissipated in hysteresis loop is J m^-3 cycle^-1.

→ B is also called magnetic flux density and has an S.I. unit in Tesla (T).

→ The unit pole is defined as one which when placed in vacuum at a distance of 1 m from an equal and similar pole exerts a force of \(\frac{\mu_{0}}{4 \pi}\) or 10^-7 N on it.

→ Magnetic elements: They are the physical quantities that are required to completely specify the earth’s magnetic field at a point, e.g., dip, declination, and B_H.

→ Declination at a place: It is defined as the angle between geographical and magnetic meridian at that place.

→ Dip at a place: It is defined as the angle made by the resultant earth’s magnetic field with the horizontal direction.

→ The intensity of induced magnetization: It is defined as the magnetic moment developed per unit volume of the magnetic material. Its value depends on the media in which it is magnetized.

→ Magnetic susceptibility of a given material. It is defined as the ratio of the intensity of magnetization and magnetizing field.
i.e., χ_m = \(\frac{I}{H}\)

→ The intensity of magnetization (I): It is defined as the magnetic moment developed per unit volume when a magnetic substance is subjected to the magnetizing field.
i.e., I = \(\frac{\mathrm{M}}{\mathrm{V}}=\frac{\mathrm{m} \cdot 2 l}{\mathrm{a} \cdot \mathrm{zl}}=\frac{\mathrm{m}}{\mathrm{a}}\)

→ I is also defined as the pole strength developed per unit area of cross-section of the specimen.

→ Magnetic Induction (B): It is defined as the total no. of magnetic lines of induction (magnetic field lines inside the material) crossing per unit area normally through the magnetic substance.

→ Magnetic permeability (μ): It is the ratio of magnetic induction to the magnetic intensity,
i.e., μ = \(\frac{B}{H}\)

→ Curie’s law: States that the magnetic susceptibility of a paramagnetic material is inversely proportional to its absolute temperature.

→ Curie point: It is defined as the temperature at which a ferromagnetic substance starts behaving as a paramagnetic substance. It is also called Curie temperature.

→ Hysteresis: It is the lag of intensity of magnetization behind the magnetizing field during the magnetization and demagnetization of the ferromagnetic substance.

→ Coercivity and retentivity are also associated with the hysteresis loop.

→ Coulomb’s law of magnetic force: It states that
F ∝ \(\frac{m_{1} m_{2}}{r^{2}}\)
or
F = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{m_{1} m_{2}}{r^{2}}\)

Important Formulae

→ Torque experienced by a magnet or a magnetic dipole in a uniform magnetic field is
τ = | \(\overrightarrow{\mathrm{M}}\) × \(\overrightarrow{\mathrm{B}}\) | = MB sin θ

→ M = magnetic moment, B = magnetic field, θ = angle between \(\overrightarrow{\mathrm{M}}\) and \(\overrightarrow{\mathrm{B}}\).

→ Magnetic dipole moment due to current loop is:
M = nIA
where n = no. of turns in it, I = current, A = area of loop.

→ Work done in rotating a magnet placed in a magnetic field from θ₁to θ₂ is
W = MB (cos θ₁ – cos θ₂)

→ Gauss’s law of magnetism states that
∮_s \(\overrightarrow{\mathrm{B}}\). \(\overrightarrow{\mathrm{dS}}\) = 0

→ Magnetic field due to a magnetic diple at a point on its axis at a distance r from its centre is :
B = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{2 \mathrm{M}}{\mathrm{r}^{3}}\)

→ On equitorial line
B = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{\mathrm{M}}{\mathrm{r}^{3}}\)

→ If the magnet is not short, then
B = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{2 \mathrm{Mr}}{\left(\mathrm{r}^{2}-l^{2}\right)}\) on axial line

→ B equitorial = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{\mathrm{M}}{\left(\mathrm{r}^{2}+l^{2}\right)^{3 / 2}}\)

→ Time period of an oscillating magnet along earth’s magnetic field is given by –
T = 2π \(\sqrt{\frac{I}{M B_{H}}}\)
when I=M.I.of magnet = m \(\left(\frac{l^{2}+b^{2}}{12}\right)\)

→ Magnetic induction is given by
B = μ₀ (H + I)

→ B in vacuum is given by
B = μ₀H

→ μ = \(\frac{B}{H}\)

→ χ_m = \(\frac{I}{H}\)

→ μ = (1 + χ_m)
or
μ = μ₀(1 + χ_m)

→ I = C\(\frac{H}{T}\)

→ μ_r = \(\frac{\mu}{\mu_{0}}\)

→ B_H = B cos δ

→ B_v = B sin δ

→ tan δ = \(\frac{\mathrm{B}_{\mathrm{v}}}{\mathrm{B}_{\mathrm{H}}}\)
where B_H and B_V are the horizontal and vertical components of earth’s total magnetic field at a point.
δ = angle of dip at that place

→ B = \(\sqrt{B_{H}^{2}+B_{V}^{2}}\)

→ B_H = B magnet at the neutral point.

→ Magnetic field due to a straight current carrying cable at a point at a distance r from it is given by:
B = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{2 I}{r}\)

→ \(\frac{\mathrm{M}_{2}}{\mathrm{M}_{1}}=\frac{\mathrm{T}_{l}^{2}-\mathrm{T}_{1}^{2}}{\left(\mathrm{~T}_{2}^{2}+\mathrm{T}_{1}^{2}\right)}\)
where M₁ and M₂ are magnetic moments of two magnetic field in the vibration magnetometor stirrup with unlike poles in the same direction having time period of T combination T₂
T₁ = Time period of the combination of two magnetic having like poles in the same direction.

→ tangent law is
B = B_H tan θ
where B and B_H are the two mutually perpendicular magnetic fields.
θ = angle made by the magnet with B_H.

→ I = k tan θ for tangent galvanometer where K = \(\frac{\mathrm{B}_{\mathrm{H}}}{\mathrm{a}}=\frac{2 \mathrm{rB}_{\mathrm{H}}}{\mu_{0} \mathrm{~N}}\) is the reduction factor.

→ Magnetic field at a point due to a Rowland ring is given by
B = μ₀ μ_r n I
where n = no. of turns per unit length.
I = current in the ring.

Moving Charges and Magnetism Class 12 Notes Physics Chapter 4

January 5, 2022April 15, 2021 by Prasanna

By going through these CBSE Class 12 Physics Notes Chapter 4 Moving Charges and Magnetism, students can recall all the concepts quickly.

Moving Charges and Magnetism Notes Class 12 Physics Chapter 4

→ An electric charge at rest produces an electric field around it while a moving charge produces both electric and magnetic fields.

→ A magnet at rest produces a magnetic field around it.

→ An oscillating, as well as an accelerated charge, produces e.m. waves.

→ No poles are produced in a coil carrying current but such a coil shows N and S polarities.

→ 1T = 10⁴ G = 1 Wb m^-2 = 10⁴ maxwell cm^-2.

→ A current-carrying conductor has a magnetic field and not an electric field around it.

→ Work done in moving a unit pole around a long conductor is
W = μ₀ I

→ The torque acting on the loop is independent of its shape but depends on the area of the loop.

→ Path of a charged particle in a magnetic field ( \(\overrightarrow{\mathrm{B}}\) ) is a straight line when it moves parallel or anti-parallel to \(\overrightarrow{\mathrm{B}}\) and is a circle when moves perpendicular to \(\overrightarrow{\mathrm{B}}\)

→ Two parallel conductors with currents in the same direction attract each other which is a magnetic interaction and if the current flows in them in opposite direction, then they repel each other.

→ Magnetic force is always normal to the field.

→ Magnetic force is not a central force.

→ A long straight current-carrying cylinder for an external point behaves like a straight current-carrying wire.

→ If the battery is connected to two points A and B of a conducting ring, the magnetic field at the center due to the current in the ring is zero.
Moving Charges and Magnetism Class 12 Notes Physics 1
→ A long coil of wire is called a solenoid. Its magnetic field is similar to that of the magnet.

→ The electric field is conservative in nature and ∮ \(\overrightarrow{\mathrm{E}}\).\(\overrightarrow{\mathrm{dl}}\)= 0 but the magnetic field is not conservative as ∮ \(\overrightarrow{\mathrm{B}}\). \(\overrightarrow{\mathrm{dl}}\) = μ₀ I.

→ The total force on a planar current loop in a magnetic field is always zero.

→ The radius of a charged particle moving in a magnetic field is directly proportional to its momentum.

→ Speed or K.E. of the particle always remains constant in \(\overrightarrow{\mathrm{B}}\) as \(\overrightarrow{\mathrm{F}_{\mathrm{m}}}\) is perpendicular to \(\overrightarrow{\mathrm{B}}\) .

→ The nature of a circular path followed by a charged particle moving in a given magnetic field depends upon the following:

Direction of \(\overrightarrow{\mathrm{B}}\),
The direction of motion of the charged particle,
Nature of charge.

→ For a positively charged particle moving towards RHS in a downward \(\overrightarrow{\mathrm{B}}\), the circular path is anticlockwise and for a negatively charged particle, it is clockwise.

→ The \(\overrightarrow{\mathrm{B}}\) is uniform (except near the ends) for a sufficiently long solenoid and is independent of its length and area of cross-section.

→ Cyclotron cannot be used to accelerate electrons.

→ A galvanometer is a low resistance instrument.

→ It can be converted into an ammeter by connecting a small resistance parallel to it.

→ Ammeter is always connected in series in the circuit.

→ A galvanometer is converted into a voltmeter by connecting a high resistance in series. The voltmeter is always connected in parallel to the circuit.

→ Two parallel streams of protons with protons moving in the same direction repel each other. There is an electric as well as magnetic interaction. The electric interaction gives repulsive force while the magnetic interaction gives an attractive force. As F_e > F_m, so there is a net repulsion between them.

→ When the above raid stream moves in the opposite direction, then they repel each other.

→ F_e and F_m being repulsive, so there is a net repulsive force between them.

→ The minimum potential difference across the terminals of the galvanometer for full-scale deflection is
V_g = I_g G.

→The potential diff. V across the terminals of a combination of R and G is V = I_g (R + G).

→ \(\frac{\mathrm{V}}{\mathrm{V}_{\mathrm{g}}}=\frac{\mathrm{R}-\mathrm{G}}{\mathrm{G}}\) is called voltage multiplying power of series resistance R and denoted as n.
∴ n = \(\frac{V}{V_{g}}=\frac{R+G}{G}\) ⇒ R = G (n – 1).

→ R_v = R + G = nG.

→ Fleming’s left-hand rule helps us to know the direction of the force on a moving charge or on a current-carrying conductor placed in a uniform magnetic field.

→ Current element: It is the product of current and the length of conductor carrying current i.e., current element = I. \(\overrightarrow{\mathrm{l}}\) .It is a vector quantity acting along I.

→ The direction in a magnetic field along which the current-carrying conductor experiences no force is called the direction of the magnetic field.

→ Pitch of the helix (p): It is defined as the distance traveled by the particle along the magnetic field in one revolution i.e., in a time T.
∴ p = υ cos θ × T = υ cos θ. \(\frac{2 \pi m}{B q}=\frac{2 \pi m v \cos \theta}{B q}\)

→ Shunt: It is a small resistance connected in parallel to the galvanometer.

Important Formulae

→ \(\overrightarrow{\mathrm{B}}\) due to a straight current carrying conductor is given by
\(\overrightarrow{\mathrm{B}}\) = \(\frac{\mu_{0} \mathrm{I}}{4 \pi \mathrm{a}}\)(sin Φ₁ + sin Φ₂)

→ For infinitely long conductor,
\(\overrightarrow{\mathrm{B}}\) = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{2 \mathrm{I}}{\mathrm{a}}\)
where a = perpendicular distance of the point from the conductor
I = current in the conductor

→ \(\overrightarrow{\mathrm{B}}\) at a point on the axis of a current carrying loop of n turns at a distance x from its centre is given by
\(\overrightarrow{\mathrm{B}}\) = \(\frac{\mu_{0} \mathrm{nIR}^{2}}{2\left(\mathrm{x}^{2}+\mathrm{R}^{2}\right)^{\frac{3}{2}}}\)
where R = radius of loop

→ \(\overrightarrow{\mathrm{B}}\) at its centre is given by
B = \(\frac{\mu_{0} \mathrm{nIR}^{2}}{2 \mathrm{R}^{3}}=\frac{\mu_{0} \mathrm{nI}}{2 \mathrm{R}}\)

→ Magnetic field inside a solenoid having n tums/length is given by
B = µ₀ nI.

→ \(\overrightarrow{\mathrm{B}}\) at a point near its end is given by
B = \(\frac{1}{2}\) µ₀ nI

→ Maximum energy attained by a particle in a cyclotron is:
Emax = \(\frac{\mathrm{e}^{2} \mathrm{~B}^{2} \mathrm{r}_{\max }^{2}}{2 \mathrm{~m}}\)

→ Potential difference required to accelerate an electron is
V = \(\frac{B^{2} r^{2} e}{2 m}\)

→ Force on a charge moving in \(\overrightarrow{\mathrm{B}}\) is
\(\overrightarrow{\mathrm{F}_{\mathrm{m}}}\) = q(\(\overrightarrow{\mathrm{υ}}\) × \(\overrightarrow{\mathrm{B}}\))
F_max = qυB

→ Force between two moviiig dia rges s
F = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{\mathrm{q}_{1} \mathrm{q}_{2} v_{1} v_{2}}{\mathrm{r}^{2}}\)

→ Force per unit length between two infinitely long current carrying parallel conductors is
F = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{2 \mathrm{I}_{1} \mathrm{I}_{2}}{\mathrm{r}}\)

→ qυB = \(\frac{\mathrm{m} v^{2}}{\mathrm{r}}\) ⇒ r = \(\frac{\mathrm{m} v}{\mathrm{q} \mathrm{B}}\)

→ Time period, T = \(\frac{2 \pi m}{B q}\)

→ \(\overrightarrow{\mathrm{B}}\) due to current carrying conductor is
B = \(\frac{\mu_{0}}{4 \pi}\).\(\frac{\mathrm{Id} l \sin \theta}{\mathrm{r}^{2}}\)
or
\(\overrightarrow{\mathrm{B}}\) = \(\frac{\mu_{0}}{4 \pi} \cdot \frac{\mathrm{I} \overrightarrow{\mathrm{d} l} \times \hat{\mathrm{r}}}{\mathrm{r}^{2}}=\frac{\mu_{0}}{4 \pi} \cdot \frac{\mathrm{I} \overrightarrow{\mathrm{d} l} \times \overrightarrow{\mathrm{r}}}{\mathrm{r}^{3}}\)

→ G.Ig = (I – Ig)S.⇒ S = \(\frac{\mathrm{I}_{\mathrm{g}} \mathrm{G}}{\mathrm{I}-\mathrm{I}_{\mathrm{g}}}\)

→ V = I_g(G + R).

→ R_A = ammeter resistance = \(\frac{\mathrm{GS}}{\mathrm{G}+\mathrm{S}}\)

→ Voltmeter resistance = R_V = G + R

→ No. of revolutions per second = \(\frac{\text { speed }}{\text { circumference }}=\frac{v}{2 \pi r}\)

→ I = ne, where n = \(\frac{\mathrm{v}}{2 \pi \mathrm{r}}\)

→ Force on current carrying conductor in a \(\overrightarrow{\mathrm{B}}\) is, F = BIl sin θ

→ F_max = BIl if θ = 90°.

→ Current sensitivity = \(\frac{\theta}{I}=\frac{N A B}{k}\)

→ Voltage sensitivity = \(\frac{\theta}{\mathrm{V}}=\frac{\theta}{\mathrm{IR}}=\frac{\mathrm{SI}}{\mathrm{R}}=\frac{\mathrm{NAB}}{\mathrm{kR}}\)

→ Torque on a current carrying coil in \(\overrightarrow{\mathrm{B}}\)is τ = nBAI sin θ = nBIA cos α where θ = angle made by \(\overrightarrow{\mathrm{B}}\) with the normal to the plane of coil and
α = angle made by \(\overrightarrow{\mathrm{B}}\) with the plane of coil.

Current Electricity Class 12 Notes Physics Chapter 3

January 5, 2022April 15, 2021 by Prasanna

By going through these CBSE Class 12 Physics Notes Chapter 3 Current Electricity, students can recall all the concepts quickly.

Current Electricity Notes Class 12 Physics Chapter 3

→ The time rate of flow of electric charge is called electric constant.

→ S.I. unit an electric current is Ampere (A).
1A = 1 C S^-1.

→ Although a direction is associated with the electric current, yet it is a scalar quantity.

→ The current density is a vector quantity directed along the direction of the flow of current.

→ The number density of free electrons is of the order of 10²² per cm³.

→ The number density of free electrons is negligible in insulators.

→ S.I. unit of resistance is the ohm (Ω)

→ The reciprocal of resistance is conductance and has S.I. unit mho or Siemen (S).

→ The conductor is said to be ohmic if they obey Ohm’s law. The V-I graph for such a conductor is a straight line.

→ The conductors are said to be non-ohmic if they don’t obey Ohm’s law. The V-I graph is not a straight line for such conductors.

→ When current is drawn from a cell its terminal potential difference is less than the e.m.f. of the cell.

→ Series combination of cells is used when the internal resistance of the cell is negligible as compared to the external resistance of the circuit.

→ The parallel combination of cells is used when the external resistance of the circuit is much smaller as compared to the internal resistance of the cell

→ The mixed grouping of cells is used when the external resistance of the circuit is of the same order as the internal resistance of the cell i.e., R ≈ r.

→ Wheatstone bridge is a circuit consisting of four resistances P, Q, R, and S a galvanometer and a battery connected such that
\(\frac{P}{Q}=\frac{R}{S}\)

→ It is said to be balanced when there is no current through the galvanometer.

→ Metre bridge or Slide wire bridge is the commonly used form of the wheat stone bridge.

→ The current in the external circuit flows from the + ve to – ve terminal of the cell or battery and is called conventional current which is opposite to the electronic current.

→ Current is the same through the resistors connected in series.

→ The pot. difference is the same through the resistors connected in parallel.

→ 1 A = 6.25 × 10¹⁸ electrons flow per second

→ When a cell is short-circuited, the terminal potential diff. across it is zero.

→ α for most metals is \(\frac{1}{273}\)K^-1.

→ a (temperature coefficient of resistance) for insulators and semiconductors is – ve but + ve for metals.

→ The terminal P.D. of a cell depends on the internal resistance (r) of the cell, hence it also depends on the factors on which r depends like, the area of plates, the separation between the plates, cone, electrolyte, nature of electrodes, temperature, etc.

→ 1 KWh = 3.6 × 10⁶ J.

→ Ohm’s law: States that if physical conditions of a conductor like temperature etc. remain unchanged, then the current flowing through it is directly proportional to the potential difference applied across it.

→ Resistance of a conductor is defined as the opposition offered by it to the flow of current. It is equal to the ratio of P.D. (V) and current (I) through the conductor.
i.e, R = \(\frac{V}{I}\)

→ Current density (I): It is defined as the current per unit area of the cross-section of the conductor.
i.e., J = \(\frac{I}{A}\)

→ The internal resistance of a cell: It is defined as the resistance offered by the electrolyte of the cell to the flow of current through it.

→ Conductance: It is defined as the reciprocal of the resistance of the conductor.
i.e., G = \(\frac{1}{R}\)

→ Conductivity: It is defined as reciprocal of the resistivity of the conductor i.e. σ = \(\frac{1}{ρ}\)

→ Temperature coefficient of resistance of a conductor: It is defined as the increase in resistance per unit original resistance at 0°C per unit rise in its temperature.

→ Principle of potentiometer: It states that when a constant current is passed through a conductor of the uniform area of cross-section, the potential drop across any part of it is always directly proportional to the length of that part.
V ∝ l

→ Electric energy: It is defined as the total work done by the source of energy in maintaining the electric current through the circuit for a given time.

→ KWh: The electric energy consumed or dissipated in the circuit is said to be 1 Kilowatt-hour if a device of 1 kW power is used for one hour. It is also called UNIT.

→ Electric power: It is defined as the rate of doing work by the source .of e.m.f. in maintaining the electric current in the circuit.

→ 1 Watt: The electric power of a circuit or a device is said to be 1 watt if one ampere current flows through it on applying a P.D. of one volt.

→ Shunt: It is defined as a small resistance connected in parallel to the cell.

Important Formulae

→ Current density (J) and electric field are related as:
J = σE
R = ρ\(\frac{l}{A}\)
ρ = \(\frac{1}{σ}\)
where ρ = resistivity or specific resistance of the conductor having conductivity σ.

→ internal resistance of the cell is given by
r = \(\left(\frac{E-V}{V}\right)\)R = \(\left(\frac{\mathrm{E}}{\mathrm{V}}-1\right)\)R

→ Using potentiometer r is calculated using
r = \(\left(\frac{l_{1}}{l_{2}}-1\right)\)S = \(\left(\frac{l_{1}-l_{2}}{l_{2}}\right)\)S
where l1 and l2 are balancing lengths with cell in open closed circuits respectively.
S = shunt resistance

→ Drift velocity is given by
υ_d = \(\frac{\mathrm{I}}{\text { neA }}\)
or
I = neAv_d.

→ Current in the serìcs circuit of n cells is
I_s = \(\frac{n E}{R+n r}\)

→ Current in the circuit of m cells in parallel is given by
I_p = \(\frac{E}{R+\frac{r}{m}}\)

→ In mixed grouping of cells, I in the circuit is given by,
I_m = \(\frac{\mathrm{nE}}{\mathrm{R}+\frac{\mathrm{nr}}{\mathrm{m}}}\)

→ I due to a single cell is
I = \(\frac{E}{R+r}\)

→ The equivalent resistance and power of resistance connected in series are given by:
R_s = R₁ + R₂ + R₃ + ……………
and \(\frac{1}{P_{\mathrm{s}}}=\frac{1}{P_{1}}+\frac{1}{P_{2}}+\frac{1}{P_{3}}+\ldots\)

→ Time required to neutralise earth’s surface,
t = \(\frac{\sigma \mathrm{A}}{\mathrm{I}}=\frac{\sigma .4 \pi \mathrm{R}^{2}}{\mathrm{I}}\)
Where R = radius of earth,
σ = surface charge density
I = current over globe

→ The equivalent resistance and power of resistance connected in parallel are given by and
\(\frac{1}{\mathrm{R}_{\mathrm{P}}}=\frac{1}{\mathrm{R}_{1}}+\frac{1}{\mathrm{R}_{2}}+\frac{1}{\mathrm{R}_{3}}+\ldots\) and
P_p = P₁ + P₂ + P₃ + ………….

→ Electric energy is given by
E = Pt = VIt = I²Rt = \(\frac{\mathrm{V}^{2}}{\mathrm{R}}\) t.

→ Electric power is given by
P = \(\frac{E}{t}\) = VI = I²R = \(\frac{\mathrm{V}^{2}}{\mathrm{R}}\)

→ Variation of resistance and resistivity with temperature is given by
R_t = R₀ (1 + α Δ t)
and p_t = p₀ (1 + αΔt)

→ V = kl for potentiometer.

→ \(\frac{\mathrm{E}_{1}}{\mathrm{E}_{2}}=\frac{l_{1}}{l_{2}}\) where E₁ and E₂ are emfs of two cells l₁, l₂ = corresponding balancing lengths.

→ \(\overrightarrow{v_{\mathrm{d}}}\) = – \(\frac{\mathrm{e} \overrightarrow{\mathrm{E}}}{\mathrm{m}}\) τ

→ ρ = \(\frac{\mathrm{m}}{\mathrm{ne}^{2} \tau}\)
where τ = relaxation time,
n = current density of free electron,
e = charge of an electron.

Electrostatic Potential and Capacitance Class 12 Notes Physics Chapter 2

January 5, 2022April 15, 2021 by Prasanna

By going through these CBSE Class 12 Physics Notes Chapter 2 Electrostatic Potential and Capacitance, students can recall all the concepts quickly.

Electrostatic Potential and Capacitance Notes Class 12 Physics Chapter 2

→ The S.I. unit of electric potential and a potential difference is volt.

→ 1 V = 1 J C^-1.

→ Electric potential due to a + ve source charge is + ve and – ve due to a – ve charge.

→ The change in potential per unit distance is called a potential gradient.

→ The electric potential at a point on the equatorial line of an electric dipole is zero.

→ Potential is the same at every point of the equipotential surface.

→ The electric potential of the earth is arbitrarily assumed to be zero.

→ Electric potential is a scalar quantity.

→ The electric potential inside the charged conductor is the same as that on its surface. This is true irrespective of the shape of the conductor.

→ The surface of a charged conductor is equipotential irrespective of its shape.

→ The potential of a conductor varies directly as the charge on it. i.e., V ∝ \(\frac{l}{A}\)

→ Potential varies inversely as the area of the charged conductor i.e.

→ S.I. unit of capacitance is Farad (F).

→ The aspherical capacitor consists of two concentric spheres.

→ A cylindrical capacitor consists of two co-axial cylinders.

→ Series combination is useful when a single capacitor is not able to tolerate a high potential drop.

→ Work done in moving a test charge around a closed path is always zero.

→ The equivalent capacitance of series combination of n capacitors each of capacitance C is
C_s = \(\frac{C}{n}\)

→ C_s is lesser than the least capacitance in the series combination.

→ The parallel combination is useful when we require large capacitance and a large charge is accumulated on the combination.

→ If two charged conductors are connected to each other, then energy is lost due to sharing of charges, unless initially, both the conductors are at the same potentials.

→ The capacitance of the capacitor increases with the dielectric constant of the medium between the plates.

→ The charge on each capacitor remains the same but the potential difference is different when the capacitors are connected in series.

→ P. D. across each capacitor remains the same but the charge stored across each is different during the parallel combination of capacitors.

→ P.E. of the electric dipole is minimum when θ = 0 and maximum when θ = 180°

→ θ = 0° corresponds to the position of stable equilibrium and θ = π to the position of unstable equilibrium.

→ The energy supplied by a battery to a capacitor is CE² but energy stored
in the capacitor is \(\frac{1}{2}\) CE².

→ A suitable material for use as a dielectric in a capacitor must have a high dielectric constant and high dielectric strength.

→ Van-de Graaf generator works on the principle of electrostatic. induction and action of sharp points on a charged conductor.

→ The potential difference between the two points is said to be 1 V if 1 J of work is done in moving 1 C test charge from one point to the another.

→ The electric potential at a point in \(\overrightarrow{\mathrm{E}}\): It is defined as the amount of work done in moving a unit + ve test charge front infinity to that point.

→ Electric potential energy: It is defined as the amount of work is done in bringing the charges constituting a system from infinity to their respective locations.

→ 1 Farad: The capacitance of a capacitor is said to be 1 Farad if 1 C charge given to it raises its potential by 1 V

→ Dielectric: It is defined as an insulator that doesn’t conduct electricity but the induced charges are produced on its faces when placed in a uniform electric field.

→ Dielectric Constant: It is defined as the ratio of the capacitance of the capacitor with a medium between the plates to its capacitance with air between the plates

→ Polarisation: It is defined as the induced dipole moment per unit volume of the dielectric slab.

→ The energy density of the parallel plate capacitor is defined as the energy per unit volume of the capacitor.

→ Electrical Capacitance: It is defined as the ability of the conductor to store electric charge.

Important Formulae

→ Electric potential at a point A is
V_A = \(\frac{W_{∞} A}{q_{0}}\)

→ V = \(\frac{1}{4 \pi \varepsilon_{0}}. \frac{q}{r}\)

→ Electric field is related to potential gradient as:
E = – \(\frac{\mathrm{dV}}{\mathrm{dr}}\)

→Electric potential at point on the axial line of an electric dipole is:
V = \(\frac{1}{4 \pi \varepsilon_{0}} \cdot \frac{q}{r^{2}}\)

→ Electric P.E. of a system of point charges is given
υ = \(\frac{1}{4 \pi \varepsilon_{0}} \sum_{i=1}^{n} \sum_{j=1 \atop j \neq i}^{n} \frac{q_{i} a_{j}}{r_{i j}}\)

→ V due to a charged circular ring on its axis is given by:
V = \(\frac{1}{4 \pi \varepsilon_{0}} \cdot \frac{q}{\left(R^{2}+r^{2}\right)^{1 / 2}}\)

→ V at the centre of ring of radius R is given by
V = \(\frac{1}{4 \pi \varepsilon_{0}} \cdot \frac{q}{R}\)

→ The work done in moviag a test large from one point A to another point B having positions vectors \(\overrightarrow{\mathrm{r}_{\mathrm{A}}}\) and \(\overrightarrow{\mathrm{r}_{\mathrm{A}}}\) respectively w.r.t. q is given by
WAB = \(\frac{1}{4 \pi \varepsilon_{0}} \cdot q \cdot\left(\frac{1}{r_{B}}-\frac{1}{r_{A}}\right)\)

→ Line integral of electric field between points A and B is given by.
∫AB \(\overrightarrow{\mathrm{E}}\) \(\overrightarrow{\mathrm{dl}}\) = \(\frac{1}{4 \pi \varepsilon_{0}} \cdot \mathrm{q}\left(\frac{1}{\mathrm{r}_{\mathrm{A}}}-\frac{1}{\mathrm{r}_{\mathrm{B}}}\right)\)

→ Electric potential energy of an electric dipole is
U = – \(\overrightarrow{\mathrm{p}}\). \(\overrightarrow{\mathrm{E}}\)

→ Capacitance of the capacitor is given by
C = \(\frac{q}{V}\)

→ P.E. of a charged capacitor is:
U = \(\frac{1}{2}\) qV = \(\frac{1}{2}\) CV² = \(\frac{\mathrm{q}^{2}}{2 \mathrm{C}}\)

→ C of a parallel plate capacitor with air between the plates is:
C₀ = \(\frac{\varepsilon_{0} \cdot A}{d}\)
C₀ = \(\frac{\varepsilon_{0} \mathrm{KA}}{\mathrm{d}}\)

→ C of a parallel plate capacitor with a dielectric medium between the plates is:
C = \(\frac{C_{m}}{C_{0}}=\frac{E_{0}}{E}\)

→ Common potential as
V = \(\frac{C_{1} V_{1}+C_{2} V_{2}}{C_{1}+C_{2}}\)

→ loss of electrical energy = \(\frac{1}{2}\left(\frac{\mathrm{C}_{1} \mathrm{C}_{2}}{\mathrm{C}_{1}+\mathrm{C}_{2}}\right)\left(\mathrm{V}_{1}-\mathrm{V}_{2}\right)\)

→ Energy supplied by battery is CE2 and energy stored in the capacitor is \(\frac{1}{2}\) CE².

→ The equivalent capacitance of series combination of three capacitor is given by
\(\frac{1}{C_{s}}=\frac{1}{C_{1}}+\frac{1}{C_{2}}+\frac{1}{C_{3}}\)

→ The equivalent capacitance of parallel grouping of three capacitors is
C_p = C₁ + C₂ + C₃

→ Capacitance of spherical capacitor is
C = 4πε₀ \(\frac{a b}{b-a}\)
a, b are radii of inner and outer spheres.

→ Capacitance of a cylindrical capacitor is given by:
C = \(\frac{2 \pi \varepsilon_{0}}{\log _{e}\left(\frac{b}{a}\right)}\)
when b, a are radii of outer and inner cylinder.

→ Capacitance of a capacitor in presence of conducting slab between the plates is .
C = \(\frac{\mathrm{C}_{0}}{1-\frac{\mathrm{t}}{\mathrm{d}}}\) = ∞ if t = d.

→Capacitances of a capacitor with a dielectric medium between the plates is given by
C = \(\frac{C_{0}}{\left[1-\frac{t}{d}\left(1-\frac{1}{R}\right)\right]}\)
C = K C₀ If t = d

→ Reduced value of electric field in a dielectric slab is given by
E = E₀ – \(\frac{P}{\varepsilon_{0}}\)
where P = σ_p = induced charge density.

→ Capacitance of an isolated sphere is given by
C = 4πε₀ r .
C = 4πε₀ Kr