Dimensional Formula Table : class 11
Dimensional Formula
✅ What is Dimensional Formula?
The dimensional formula of a physical quantity shows how and which of the base quantities (Mass [M], Length [L], Time [T], etc.) are involved in its definition.
Basic Dimensions (Fundamental Quantities)
| Quantity | Symbol | Dimension Symbol |
|---|---|---|
| Mass | m | [M] |
| Length | l | [L] |
| Time | t | [T] |
| Temperature | T | [K] |
| Electric current | I | [A] |
| Amount of substance | n | [mol] |
| Luminous intensity | Iv | [cd] |
Dimensional Formula of Common Physical Quantities
| Quantity | Formula | Dimensional Formula |
|---|---|---|
| Velocity (v) | Distance / Time | [M⁰ L¹ T⁻¹] |
| Acceleration (a) | Velocity / Time | [M⁰ L¹ T⁻²] |
| Force (F) | Mass × Acceleration | [M¹ L¹ T⁻²] |
| Work or Energy (W) | Force × Displacement | [M¹ L² T⁻²] |
| Power (P) | Work / Time | [M¹ L² T⁻³] |
| Pressure (P) | Force / Area | [M¹ L⁻¹ T⁻²] |
| Density (ρ) | Mass / Volume | [M¹ L⁻³ T⁰] |
| Gravitational constant (G) | F × r² / (m₁·m₂) | [M⁻¹ L³ T⁻²] |
| Universal gas constant (R) | PV / nT | [M¹ L² T⁻² K⁻¹ mol⁻¹] |
| Planck’s constant (h) | Energy / Frequency | [M¹ L² T⁻¹] |
| Frequency (ν) | 1 / Time | [M⁰ L⁰ T⁻¹] |
| Angular velocity (ω) | Angle / Time | [M⁰ L⁰ T⁻¹] |
Dimensional Formulas of Thermal Physical Quantities
| Quantity | Symbol | Dimensional Formula |
|---|---|---|
| Temperature | T | [K] (Thermodynamic unit) |
| Heat (Energy) | Q | [M¹ L² T⁻²] |
| Specific Heat Capacity | c | [L² T⁻² K⁻¹] |
| Heat Capacity | C | [M¹ L² T⁻² K⁻¹] |
| Latent Heat | L | [L² T⁻²] |
| Thermal Conductivity | k | [M L T⁻³ K⁻¹] |
| Coefficient of Linear Expansion | α | [K⁻¹] |
| Coefficient of Superficial Expansion | β | [K⁻¹] |
| Coefficient of Volume Expansion | γ | [K⁻¹] |
| Stefan-Boltzmann Constant | σ | [M T⁻³ K⁻⁴] |
| Gas Constant (Universal R) | R | [M L² T⁻² K⁻¹ mol⁻¹] |
| Boltzmann Constant | k_B | [M L² T⁻² K⁻¹] |
| Thermal Energy (Kinetic) | — | [M L² T⁻²] |
| Entropy | S | [M L² T⁻² K⁻¹] |
Electrical and Magnetic Physical Quantities – Dimensional Formulas
| Quantity | Symbol | Dimensional Formula |
|---|---|---|
| Electric Charge | Q | [T A] |
| Electric Current | I | [A] |
| Potential Difference (Voltage) | V | [M L² T⁻³ A⁻¹] |
| Electric Field | E | [M L T⁻³ A⁻¹] |
| Electric Potential | V | [M L² T⁻³ A⁻¹] |
| Resistance | R | [M L² T⁻³ A⁻²] |
| Resistivity | ρ (rho) | [M L³ T⁻³ A⁻²] |
| Conductivity | σ (sigma) | [M⁻¹ L⁻³ T³ A²] |
| Capacitance | C | [M⁻¹ L⁻² T⁴ A²] |
| Inductance | L | [M L² T⁻² A⁻²] |
| Power (Electric) | P | [M L² T⁻³] |
| Magnetic Field (Magnetic Flux Density) | B | [M T⁻² A⁻¹] |
| Magnetic Flux | ϕ (phi) | [M L² T⁻² A⁻¹] |
| Permeability (μ) | μ | [M L T⁻² A⁻²] |
| Permittivity (ε) | ε | [M⁻¹ L⁻³ T⁴ A²] |
| EMF (Electromotive Force) | E | [M L² T⁻³ A⁻¹] |
| Current Density | J | [A L⁻²] |
| Surface Charge Density | σ | [T A L⁻²] |
| Volume Charge Density | ρ | [T A L⁻³] |
Dimensional Formula of Dimensional Constants
| Constant | Symbol | Dimensional Formula |
|---|---|---|
| Gravitational Constant | G | [M⁻¹ L³ T⁻²] |
| Planck’s Constant | h | [M L² T⁻¹] |
| Gas Constant | R | [M L² T⁻² K⁻¹ mol⁻¹] |
| Boltzmann Constant | k_B | [M L² T⁻² K⁻¹] |
| Avogadro’s Number (dimensionless) | Nₐ | — (No dimensions) |
| Universal Electric Constant (Permittivity of free space) | ε₀ | [M⁻¹ L⁻³ T⁴ A²] |
| Magnetic Constant (Permeability of free space) | μ₀ | [M L T⁻² A⁻²] |
| Coulomb’s Constant (1/4πε₀) | K | [M L³ T⁻⁴ A⁻²] |
| Stefan-Boltzmann Constant | σ | [M T⁻³ K⁻⁴] |
| Wien’s Displacement Constant | b | [L K⁻¹] |
| Rydberg Constant | R∞ | [L⁻¹] |
| Electron Charge (e) | e | [T A] |
| Faraday Constant | F | [T A mol⁻¹] |
| Mobility | μ | [M⁻¹ T² A] |
Dimensional Formulas of Modern Physics Physical Quantities
| Quantity | Symbol | Dimensional Formula |
|---|---|---|
| Planck’s Constant | hhh | [M L² T⁻¹] |
| Energy (Photon / Quantum) | E=hνE = h\nuE=hν | [M L² T⁻²] |
| Frequency | ν\nuν | [T⁻¹] |
| Wavelength | λ\lambdaλ | [L] |
| Momentum | ppp | [M L T⁻¹] |
| De Broglie Wavelength | λ=hp\lambda = \frac{h}{p}λ=ph | [L] |
| Mass–Energy (E = mc²) | EEE | [M L² T⁻²] |
| Charge of Electron | eee | [T A] |
| Work Function | ϕ\phiϕ | [M L² T⁻²] |
| Threshold Frequency | ν0\nu_0ν0 | [T⁻¹] |
| Threshold Wavelength | λ0\lambda_0λ0 | [L] |
| Stopping Potential | V0V_0V0 | [M L² T⁻³ A⁻¹] |
| Atomic Radius | — | [L] |
| Nuclear Radius | RRR | [L] |
| Binding Energy | — | [M L² T⁻²] |
| Half-life (T₁/₂) | — | [T] |
| Activity (Radioactive decay) | AAA | [T⁻¹] |
| Decay Constant | λ\lambdaλ | [T⁻¹] |
| Electric Potential | VVV | [M L² T⁻³ A⁻¹] |
| Electronvolt (eV) | — | [M L² T⁻²] |
Dimensionless Physical Quantities
| Quantity | Symbol | Dimensional Formula | Nature |
|---|---|---|---|
| Angle (plane) | θ | [M⁰ L⁰ T⁰] | Ratio of lengths |
| Solid Angle | Ω (omega) | [M⁰ L⁰ T⁰] | Ratio of areas |
| Refractive Index | n | [M⁰ L⁰ T⁰] | Ratio of velocities |
| Relative Density (Specific Gravity) | — | [M⁰ L⁰ T⁰] | Ratio of densities |
| Strain (linear, volumetric) | — | [M⁰ L⁰ T⁰] | Ratio of lengths/volumes |
| Poisson’s Ratio | σ | [M⁰ L⁰ T⁰] | Ratio of strains |
| Efficiency | η | [M⁰ L⁰ T⁰] | Ratio of energies |
| Coefficient of Friction | μ | [M⁰ L⁰ T⁰] | Ratio of forces |
| Relative Permittivity | εᵣ | [M⁰ L⁰ T⁰] | Ratio |
| Relative Permeability | μᵣ | [M⁰ L⁰ T⁰] | Ratio |
| Mach Number | M | [M⁰ L⁰ T⁰] | Ratio (v/v_sound) |
| Reynolds Number | Re | [M⁰ L⁰ T⁰] | Ratio (inertial/viscous) |
| Fineness Ratio (optics) | — | [M⁰ L⁰ T⁰] | Ratio |