PHYSICS➨PART- 1
Nothing happens until something moves
Well this session consists of PHYSICS . This part consist Physical constant and formulae . I tries to tell ,in such a way as to be understood by everyone.The important thing in science is not so much to obtain new facts as to discover new ways of thinking about them.
Physical Constants
1 - Average acceleration of gravity (g) → 9.81 m/s²
2 - Gravitational constant (G) → 6.67× 10 ⁻ ¹¹ Nm²/kg²
3 - Mass of electron (mₑ ) → 9.11 × 10 ⁻³¹ kg = 0.511 MeV/c²
4 - Mass of proton (mₚ ) → 1.673 × 10 ⁻²⁷ Kg = 1.007 u
= 938.3 MeV/c²
5 - Mass of neutron (mₙ ) → 1.657 × 10 ⁻²⁷ Kg = 1.009 u
= 939.6 MeV/c²
6 - Speed of light in vaccum ( c) → 3.00 × 10 ⁸ m/s
7 - Universal gas constant ( R ) → 8.31 J/mol K
8 - Boltzmann constant ( kʙ ) → 1.38 × 10⁻²³ J/k
9 - Avogadro constant (Nᴀ) → 6.02 × 10 ²³ / mol
10 - Permittivity constant ( ∈₀ ) → 8.85 × 10⁻¹² C²/Nm² = 8.85 pF/m
11 - Coulomb constant or
Electric constant ( kₑ ) → 1/4 𝝅∈₀ = 8.99 × 10⁹ Nm²/C²
12 - Elementary charge ( e ) → 1.60 × 10 ⁻¹⁹ c
13 - Permeability constant ( μ₀ ) → 4𝝅× 10⁻⁷ Tm/A = 1.26 × 10 ⁻⁶ N/A²
14 - Magnetic constant ( kₘ = μ₀ /4𝝅 ) → 10⁻⁷ Tm/A
15 - Planck constant ( h ) → 6.63 × 10 ⁻³⁴ Js = 4.14 × 10 ⁻¹⁵ eVs
16 - Bohr radius ( r₀ ) → 5.29 × 10⁻¹¹ m = 0.529 Å
17 - Electron volt ( eV ) → 1.60 × 10⁻¹⁹ J
18 - Unified atomic mass unit ( amu) ( n) → 1.66 × 10⁻²⁷ Kg
19 - Rydberg constant ( R ) → 1.097 × 10⁷m⁻¹
20 - Bohr magneton (μ ) → 9.274 × 10⁻²⁴ J/T
2 - Gravitational constant (G) → 6.67× 10 ⁻ ¹¹ Nm²/kg²
3 - Mass of electron (mₑ ) → 9.11 × 10 ⁻³¹ kg = 0.511 MeV/c²
4 - Mass of proton (mₚ ) → 1.673 × 10 ⁻²⁷ Kg = 1.007 u
= 938.3 MeV/c²
5 - Mass of neutron (mₙ ) → 1.657 × 10 ⁻²⁷ Kg = 1.009 u
= 939.6 MeV/c²
6 - Speed of light in vaccum ( c) → 3.00 × 10 ⁸ m/s
7 - Universal gas constant ( R ) → 8.31 J/mol K
8 - Boltzmann constant ( kʙ ) → 1.38 × 10⁻²³ J/k
9 - Avogadro constant (Nᴀ) → 6.02 × 10 ²³ / mol
10 - Permittivity constant ( ∈₀ ) → 8.85 × 10⁻¹² C²/Nm² = 8.85 pF/m
11 - Coulomb constant or
Electric constant ( kₑ ) → 1/4 𝝅∈₀ = 8.99 × 10⁹ Nm²/C²
12 - Elementary charge ( e ) → 1.60 × 10 ⁻¹⁹ c
13 - Permeability constant ( μ₀ ) → 4𝝅× 10⁻⁷ Tm/A = 1.26 × 10 ⁻⁶ N/A²
14 - Magnetic constant ( kₘ = μ₀ /4𝝅 ) → 10⁻⁷ Tm/A
15 - Planck constant ( h ) → 6.63 × 10 ⁻³⁴ Js = 4.14 × 10 ⁻¹⁵ eVs
16 - Bohr radius ( r₀ ) → 5.29 × 10⁻¹¹ m = 0.529 Å
17 - Electron volt ( eV ) → 1.60 × 10⁻¹⁹ J
18 - Unified atomic mass unit ( amu) ( n) → 1.66 × 10⁻²⁷ Kg
19 - Rydberg constant ( R ) → 1.097 × 10⁷m⁻¹
20 - Bohr magneton (μ ) → 9.274 × 10⁻²⁴ J/T
Formulae of Physical Quantities
2 - Coulomb's law → F = kₑ q₁ q₂/r² ( F is the force in between two charges q₁and q₂ placed in a vacuum at a distance r )
3 - Relative permittivity Or Dielectric constant → ∈ᵣ = F/Fₘ ( ∈ᵣ is the relative permittivity of a medium . Fₘ is the force acting between two point charges q₁ and q₂ placed in a medium at the same distance r apart. )
4 - Absolute permittivity → ∈ᵣ = ∈ /∈₀ ( ∈ is absolutely permittivity of a medium )
5 - Electric field intensity → E = F / q₀ ( E is the electric field intensity and F is the force acting on a test charge q₀ placed in the field )
6 - Electric field due to an isolated point charge → E = kₑ q/r² ( E is the electric field due to an isolated point charge q at a point distant r from q. )
7 - Electric intensity due to an infinitely long thin wire → E = 2kₑλ/x = λ/ 2𝜋∈₀x ( E is the intensity due to an infinitely long thin wire at a distance x , λ being the linear charge density of the wire.)
8 - Electric intensity due to a conducting ring → E = kₑ qx/ (R²+x²)³/² ( E is the electric intensity due to a conducting ring of radius R and carrying a charge q at a point lying on it's axis of symmetry at a distance x from it's center .)
9 - Electric dipole moment → p = q × 2a = 2qa ( p is the electric dipole moment of an electric dipole of each charge of magnitude q , placed a distance 2a apart. )
10 - Electric field intensity due to a dipole on its axial line → E (axial) → kₑ2pr/(r²-a²)²
E (axial) → kₑp/r³ ( E axial is the electric field intensity due to a dipole on the axial line at a point distance r from it's center , p being the dipole moment of the dipole.)
11 - Electric field intensity due to a dipole on its equatorial line → E (equatorial ) = kₑp/ (r²+a²)³/²
E (equatorial) = kₑp/r³ (for a short dipole) (E equatorial is the electric field intensity due to a dipole on its equatorial line at a point distance r from its center , p being the dipole moment of the dipole.)
12 - Electric field intensity ➝ E= σ/2∊₀ ( E is the electric field intensity due to an infinite uniformly charged plane sheet of surface charge density σ.)
E = σ /∊₀ ( E is the electric field intensity due to an infinite charged conducting plate of surface charge density σ. )
13 - Torque → ꞇ = p × E Or ꞇ = pEsin𝜃 (ꞇ is the torque acting on an electric dipole of dipole moment p lying at angle 𝜃 with the electric field E)
14 - Potential energy → U = - p.E ( p and E both are in vector form )= -pEcosθ (U is the potential energy of an electric dipole of dipole moment p lying at an angle θ with the electric field E.)
15 - Work done → W = 2 pE ( work done to reverse the dipole , that is turning its end for end.)
16 - Electric flux → Φᴇ = EA = q/∊₀ ( Φᴇ is the electric flux through a surface of area A, placed perpendicular to a uniform electric field E.)
17 - Potential difference → Δ V = Vʙ - Vᴀ = Wᴀʙ / q₀ ( ΔV is the potential difference between points A and B and Wᴀʙ is the work done in carrying a positive charge q₀ from A to B.)
18 - Potential gradient → E = - dV/dr ( dV/dr is called the potential gradient )
E = V/r ( E is a uniform electric field .)
19 - Potential energy → U = kₑ ( q₁q₂/x₁ + q₂q₃/x₂ + q₃q₁/x₃) ( U is the potential energy of a configuration of three charges q₁,q₂,and q₃ placed in vacuum .x₁ is the distance between q₁ q₂ ; x₃ is the distance between q₂ q₃ ; x₃ is the distance between q₃ q₁.)
20 - Capacitance of a conductor → C= Q/V ( C is the capacitance of a conductor having charge Q and a potential V.)
21 - Capacitance of a parallel plate conductor → C = ∊₀A /d ( C is the capacitance of a parallel plate conductor , A is the area of the plates and d is the separation between them.)
[ A capacitor consists of isolated conductors plates carrying equal and opposite charges +Q₁ , and - Q₂ .)
22 - Capacitance of a spherical capacitors → C = ab/ kₑ(b - a) = 4𝝅∊₀ab/ (b - a) (C is the capacitance of a spherical capacitor , a is the radius of the inner charged sphere and b that of the outer earthed shell.)
24 - Resultant capacitance in series combination → 1/Cₛ = 1/C₁ + 1/C₂ +1/C₃ (Cₛ is the resultant capacitance in series combination of capacitors of capacitance C₁, C₂, C₃.)
25 - Resultant capacitance in parallel combination → Cₚ = C₁ + C₂ + C₃ ( Cₚ is the resultant capacitance in parallel combination of capacitors of capacitance C₁ ,C₂ and C₃ )
26 - Electric potential energy stored in a capacitor → U = 1/2CV² = QV/2 = Q²/2C (U is the electric potential energy stored in a capacitor of capacitance C , having charge Q and at a potential V.)
27 - Energy density → uₑ = 1/2∈₀ E² ( uₑ is called the energy density that is electric potential energy per unit volume stored in an electric field E.)
28 - Loss of energy → U₁-U₂ = 1/2 (C₁C₂/C₁+C₂)(V₁-V₂)² ( U₁-U₂ is the loss of energy on sharing the charges ; C₁ and C₂ are the capacitance of two conductors at potential V₁ and V₂.)
29 - Dielectric constant → ∈ᵣ = C/C₀ ( ∈ is the dielectric constant and C and C₀ denote the capacitance of a capacitor with and without dielectric.)
30 - Capacitance of a parallel plate capacitors → C = ∈₀A/ (d-t) + t/∈ᵣ ( C is the capacitance of a parallel -plate capacitor with a dielectric slab of thickness t between its plates, each of area A and having a separation d.)
C = ∈₀A/d-t ( C is the capacitance of the parallel - plate capacitor with a conducting slab of thickness t between its plates, each of area A and having a separation d.)
31 - Steady current → I = q/t
Instantaneous current I = dq /dt ( I is the current due to flow of charge q Or dq through a conductor for a time t Or dt.)
32 - Ohm's Law → V = RI ( V is the potential difference across the ends of a conductor through which a current I flows . Here R is the resistance of the conductor.)
33 - Conductance → G =1/R = 1/ V (G is the conductance of a conductor.)
34 - Resistivity → ⍴ = RA/l = m/ne²ꞇ (⍴ is the resistivity of the material .R is the resistance of a conductor of a lenght l , cross sectional area A . n is the number density of electrons , ꞇ is the relaxation time that is mean time between the collision of an electron with the ions of metal lattice , m is the mass of the electron and e its charge.)
35 - Current in terms of drift speed → I = nevdA ( A is the cross sectional area of a conductor , n is the number density of electrons ( number of electrons per unit volume ) , e is the charge on the electron and vd is the drift speed of the electron when current I flows through the conductor.)
36 - Current density → J = I/A = n e vd ( J is the current density.)
37 - Electrical conductivity → σ = 1/⍴ = ne²ꞇ/m ( σ is electrical conductivity)
38 - Resultant resistance → Rₛ = r₁ +r₂ +r₃ ( Rₛ is the resultant resistance of a number of resistors in series.)
1/Rₚ = 1/r₁ +1/r₂ +1/r₃ ( Rₚ is the resultant resistance of a number of resistors in parallel)
39 - emf of cell → ɛ = dW/dq (E is the emf of cell and dW is the amount of work that the cell does to force positive charge dq from the negative terminal to the positive terminal.)
40 - Internal resistance → r =(ɛ-V/V)R ( r is the internal resistance of a cell of emf ɛ and V is the potential difference across the terminals of the source when the current flows through an external resistance R.)
41 - Delivering current → V = ɛ - IR ( when the cell is delivering current , that is cell is discharging itself.)
42 - Receiving current → V = ɛ + IR ( when the cell is receiving current , that is , the cell is being charged .)
43 - Series grouping of cell → I = nɛ / R+nr ( A number (n) of cells are grouped in series to get maximum current I when the external resistance R is much more than the internal resistance r of each cell .)
44 - Parallel grouping of cells → I = ɛ /(R+r/m) ( A number (m) of cells are grouped in parallel to get maximum current I when the external resistance R is much less than the internal resistance r of each cell.)
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