What languages does Phyansy support?

Phyansy supports 14 languages: English, Hindi, Bengali, Tamil, Telugu, Marathi, Arabic, Spanish, French, Portuguese, Russian, Japanese, Chinese (Simplified), and German. Physics equations stay in English — the universal language of physics — while descriptions and explanations are translated.

Does Phyansy work on mobile phones?

Yes. Phyansy is fully responsive and works on mobile phones, tablets, and desktops. It supports dark mode and light mode, auto-detected from your system preference.

Phyansy was designed and built by Tanay Guha (GitHub: s4sxam), a student developer from West Bengal, India. It is an independent, open-source project created as a free resource for physics students everywhere.

What physics topics does Phyansy cover?

Phyansy covers 13 physics domains: Classical Mechanics, Electromagnetism, Thermodynamics, Quantum Mechanics, Special and General Relativity, Optics, Waves and Oscillations, Nuclear and Particle Physics, Astrophysics and Cosmology, Fluid Mechanics, Solid State and Condensed Matter Physics, and Mathematical Physics.

Does Phyansy include physics equation derivations?

Yes. Every equation in Phyansy includes a step-by-step derivation, a plain-English explanation of what the equation says, its deep physical meaning, historical attribution, real-world significance, common misconceptions, dimensional analysis, and SI units for every variable.

Can I use Phyansy as a physics calculator?

Yes. Phyansy includes a built-in physics calculator for common computations, so you can look up an equation and calculate with it without leaving the app.

Phyansy — Free Physics Reference

Q: What physics equations does Phyansy cover?

Phyansy covers 295 physics equations across all branches including Classical Mechanics, Electromagnetism, Thermodynamics, Quantum Mechanics, Relativity, Optics, and more.

Q: Is Phyansy open source?

Yes. Phyansy's source code is publicly available on GitHub under a source-available license. It is free for personal and educational use.

An interactive physics reference with 295 equations, 79 constants, 51 symbols, SI units, and a calculator. Please enable JavaScript to use the full interactive experience.

295 Physics Equations (Mechanics, Electromagnetism, Thermodynamics, Quantum, Relativity, and more)
79 Physical Constants (speed of light, Planck constant, gravitational constant, Boltzmann constant…)
51 Physics Symbols (Greek alphabet, mathematical notation)
SI Units — base units, derived units, metric prefixes
Physics Calculator — solve equations for any variable

Made by Tanay (s4sxam) — free for all students worldwide.

Physical Constants

Fundamental constants of the universe — click any card to expand

Key Equations

Essential formulas across all branches of physics — click to see variable legend

Symbols Reference

Greek alphabet and mathematical notation used in physics

Units & Measurement

SI base units, derived units, and metric prefixes — click any symbol to copy

SI Base Units

Common Derived Units

Non-SI Units (Widely Used in Physics)

Metric Prefixes

Physics Calculator

Pick an equation, choose what to solve for, enter known values

Equation

Solve for

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Result

🔥 Fun Facts

Mind-bending facts across Physics, Chemistry, Biology, Space & more — because science is wild

About Phyansy

Phyansy is a free interactive physics reference built by Tanay, a developer passionate about making physics accessible to students worldwide. The project covers 295 physics equations with full derivations and context, 79 physical constants with CODATA-standard values, 51 symbols, SI units, and a built-in calculator — all free, with no sign-up required.

Constant values are sourced from CODATA 2018 recommended values. The project is open-source on GitHub. Third-party services: Google Translate (for 14-language support) and KaTeX (for math rendering).

Frequently Asked Questions

What is Phyansy?

Phyansy is a free, open-source physics reference web app. It gives students and researchers instant access to 295 physics equations, 79 physical constants, 51 symbols, SI units, and a built-in calculator — all beautifully rendered with KaTeX math typesetting.

Is Phyansy free to use?

Yes. Phyansy is completely free with no sign-up, no account, and no ads required. It is available to all students worldwide.

What physics equations does Phyansy cover?

Phyansy covers 295 equations across 13 categories: Classical Mechanics, Electromagnetism, Thermodynamics, Quantum Mechanics, Relativity, Optics, Waves, Nuclear Physics, Astrophysics, Fluid Mechanics, Solid State Physics, Particle Physics, and Mathematical Physics.

How many physical constants does Phyansy include?

Phyansy includes 79 fundamental physical constants sourced from CODATA 2018 recommended values, including the speed of light, Planck constant, gravitational constant, Boltzmann constant, and more.

Does Phyansy work in multiple languages?

Yes. Phyansy supports 14 languages including English, Hindi, Bengali, Tamil, Telugu, Marathi, Arabic, Spanish, French, Portuguese, Russian, Japanese, Chinese, and German.

Does Phyansy work on mobile?

Yes. Phyansy is fully responsive and works on mobile phones, tablets, and desktops with dark mode support.

Is Phyansy open source?

Yes. Phyansy's source code is available on GitHub under a source-available license for personal and educational use.

Who created Phyansy?

Phyansy was designed and built by Tanay Guha (s4sxam), a student developer from West Bengal, India.

What math rendering does Phyansy use?

Phyansy uses KaTeX for fast, accurate LaTeX math typesetting directly in the browser — producing publication-quality equations.

Can I use Phyansy offline?

Phyansy requires an internet connection for initial load, but once loaded the core reference data works entirely in the browser with no server calls.

Physics Equations — Complete Reference

Classical Mechanics

Final Velocity (time) — v = u + a·t — Final velocity after accelerating from initial velocity u for time t.
Final Velocity (displacement) — v² = u² + 2a·s — Relates final velocity to initial velocity and displacement — no time needed.
Weight — W = m·g — Gravitational force on a mass m near Earth's surface, directed downward.
Kinetic Friction — f_k = µ_k · N — Friction force opposing sliding motion equals the kinetic friction coefficient times the normal force.
Static Friction — f_s ≤ µ_s · N — Static friction is a reactive force that can take any value up to a maximum of µ_s · N.
Hooke's Law — F = −k·x — A spring exerts a restoring force proportional to its displacement from equilibrium.
Work Done — W = F·d·cos(θ) — Work is the component of force along the displacement, times the displacement.
Gravitational Potential Energy — PE = mgh — Potential energy stored in a mass at height h above a reference level in a uniform gravitational field.
Conservation of Momentum — m₁u₁ + m₂u₂ = m₁v₁ + m₂v₂ — In an isolated system, total momentum before a collision equals total momentum after.
Moments of Inertia — I = mr² (and variants) — Moment of inertia measures resistance to angular acceleration — the rotational analogue of mass.

Thermodynamics

Ideal Gas Law — PV = nRT — Pressure times volume equals moles times gas constant times absolute temperature.
Ideal Gas Law (molecular form) — PV = NkT — Ideal gas law in terms of number of molecules N and Boltzmann's constant k.
Heat Capacity — Q = mcΔT — Heat energy required to raise temperature of mass m by ΔT.
Latent Heat — Q = mL — Heat energy for a phase transition — temperature stays constant while bonds form or break.
Thermal Expansion (linear) — ΔL = α·L₀·ΔT — A solid expands in length proportionally to its original length and temperature change.
Thermal Expansion (volume) — ΔV = β·V₀·ΔT — Volume expands with temperature, governed by the volumetric expansion coefficient β.
Stefan-Boltzmann Law — P = εσAT⁴ — Total power radiated by a body depends on the fourth power of its absolute temperature.
First Law of Thermodynamics — ΔU = Q − W — Change in internal energy equals heat added to the system minus work done by the system.
Isobaric Work — W = PΔV — At constant pressure, work done by a gas is simply pressure times volume change.
Boltzmann Entropy — S = k·ln(Ω) — Entropy equals Boltzmann's constant times the logarithm of the number of accessible microstates.
Gibbs Free Energy — G = H − TS — Gibbs free energy determines spontaneity at constant temperature and pressure — ΔG < 0 means spontaneous.
Helmholtz Free Energy — A = U − TS — Helmholtz free energy — maximum work from a system at constant temperature and volume.
Enthalpy — H = U + PV — Enthalpy combines internal energy with pressure-volume work — the natural energy for constant-pressure processes.

Waves & Oscillations

SHM Displacement Solution — x(t) = A·cos(ωt + φ) — General solution of SHM — displacement is sinusoidal with amplitude A, angular frequency ω, and phase φ.
Wave Speed — v = fλ — Wave speed equals frequency times wavelength — the fundamental kinematic relation for any wave.
Transverse Wave — y(x,t) = A·sin(kx − ωt) — Sinusoidal wave travelling in the +x direction — the fundamental solution of the wave equation.

Electromagnetism

Ohm's Law — V = IR — Voltage equals current times resistance — an empirical law holding for ohmic materials, with resistance arising from electron scattering.
Drift Velocity — I = nqv_d A — Current equals the product of carrier density, charge, drift velocity, and cross-section — drift is slow (mm/s), but the field propagates at ~c.
Temperature Dependence of Resistivity — ρ = ρ₀(1 + αΔT) — Resistivity increases linearly with temperature for metals (more scattering), decreases for semiconductors (more carriers), and vanishes for superconductors.
Magnetic Field of a Solenoid — B = μ₀nI — Inside an ideal solenoid the field is perfectly uniform — the magnetic analogue of a parallel-plate capacitor's uniform electric field.
Motional EMF — ε = BLv — A conductor moving through a magnetic field develops an EMF across its ends — the microscopic origin of generator action.
Self-Inductance (Solenoid) — L = μ₀n²V — Inductance measures flux produced per unit current — a solenoid's inductance scales as turns density squared times volume.

Optics

Snell's Law — n₁sin(θ₁) = n₂sin(θ₂) — Light bends at an interface between two media — the fundamental law governing all lenses, prisms, and fibre optics.
Double Slit Bright Fringes — d·sin(θ) = mλ — Young's double-slit experiment — constructive interference occurs where path difference equals a whole number of wavelengths.
Single Slit Dark Fringes — a·sin(θ) = mλ — Diffraction minima from a single slit of width a — the bending of waves around an aperture.
Diffraction Grating — d·sin(θ) = mλ — A diffraction grating with N slits produces extremely sharp principal maxima — the basis of spectroscopy.
Thin Film Interference (no inversion) — 2nt = mλ — Constructive interference in a thin film when both reflections are phase-inverted or neither is — net phase shift zero from reflections.
Malus's Law — I = I₀·cos²(θ) — Intensity of polarised light transmitted through a polariser at angle θ to the polarisation direction.

Relativity

Time Dilation — Δt = γ·Δt₀ — Moving clocks run slow — a clock in motion runs slower by factor γ relative to a stationary observer.
Rest Energy — E₀ = mc² — Mass is energy — a particle at rest has energy mc², the most famous equation in physics.
Relativistic Kinetic Energy — KE = (γ − 1)mc² — Kinetic energy of a relativistic particle — reduces to ½mv² at low speeds, diverges as v → c.
Energy-Momentum Relation — E² = (pc)² + (mc²)² — The relativistic energy-momentum relation — a Lorentz invariant that holds for all particles, massless or massive.

Quantum Mechanics

Probability Density — P(x) = |Ψ(x,t)|² — The squared modulus of the wavefunction gives the probability density of finding the particle at position x.
Angular Momentum z-Component — Lz = mₗℏ — The projection of orbital angular momentum onto the z-axis takes 2l+1 discrete values, from −lℏ to +lℏ in steps of ℏ.
Pauli Exclusion Principle — Ψ(1,2) = −Ψ(2,1) — No two fermions can occupy the same quantum state simultaneously. Fermionic wavefunctions are antisymmetric under particle exchange — if two particles share the same state, the wavefunction vanishes identically.
Electric Dipole Selection Rules — Δl = ±1, Δmₗ = 0, ±1 — For an atom to emit or absorb a photon via electric dipole radiation, the orbital angular momentum quantum number must change by exactly ±1 and the magnetic quantum number by 0 or ±1.
Electron g-factor — gₑ ≈ 2.00232 — The electron's magnetic moment is slightly more than twice the value predicted by classical theory. The deviation from 2 arises entirely from quantum electrodynamics.

Nuclear & Particle

Particle Physics & QFT

Dirac Equation — (iγ^μ ∂_μ − m)ψ = 0 — The relativistic wave equation for a spin-1/2 particle (fermion). Predicts spin, antiparticles, the electron magnetic moment gₑ = 2, and the fine structure of hydrogen — all from first principles.
QED Covariant Derivative — D_μ = ∂_μ + ieA_μ — The covariant derivative replaces the ordinary partial derivative to make the electron Lagrangian invariant under local U(1) gauge transformations. Its introduction forces the existence of the photon and completely determines the electron-photon coupling.
Weinberg Angle — sin²θ_W ≈ 0.231 — The electroweak mixing angle — the single parameter that controls how the SU(2) gauge field W³_μ and the U(1) gauge field B_μ mix to produce the physical photon and Z boson. It determines the ratio of W and Z masses, the neutral current coupling strengths, and the ratio of the two electroweak gauge coupling constants.

Astrophysics & Cosmology

Stellar Luminosity — L = 4πR²σT⁴ — The total power radiated by a star of radius R and surface temperature T, treating it as a perfect blackbody. The T⁴ dependence makes temperature the dominant factor — doubling T increases luminosity 16-fold.
Hubble's Law — v = H₀ d — Galaxies recede with velocity proportional to their distance. H₀ ≈ 70 km/s/Mpc is the Hubble constant. The law encodes the expansion of the universe — not an explosion from a centre, but a uniform stretching of space itself, so every observer in every galaxy sees every other galaxy receding.

Fluid Mechanics

Hydrostatic Pressure — P = P₀ + ρgh — The pressure at depth h in a static fluid of density ρ, with surface pressure P₀, increases linearly with depth. Each metre of water adds approximately ρgh ≈ 9800 Pa ≈ 0.097 atm. Pressure depends only on depth, not on the shape of the container.
Continuity Equation — A₁v₁ = A₂v₂ — For steady, incompressible flow through a pipe, the volume flow rate Q = Av is constant at every cross-section. Where a pipe narrows (A decreases), the fluid velocity must increase proportionally. This is mass conservation applied to fluid flow.

Solid State & Condensed Matter Physics

Bragg's Law — 2d·sinθ = nλ — X-rays of wavelength λ diffract from crystal planes of spacing d at glancing angle θ. Constructive interference — a sharp diffraction peak — occurs only when the extra path length 2d sinθ equals an integer multiple n of the wavelength. The foundation of X-ray crystallography.

Mathematical Physics & Key Constants

Physical Constants — Complete Reference

Speed of Light in Vacuum (symbol: c) — value: 2.998 × 10
Planck Constant (symbol: h) — value: 6.626 × 10
Reduced Planck Constant (symbol: ħ) — value: 1.055 × 10
Elementary Charge (symbol: e) — value: 1.602 × 10
Boltzmann Constant (symbol: k) — value: 1.381 × 10
Avogadro Constant (symbol: N_A) — value: 6.022 × 10
Luminous Efficacy (symbol: K_cd) — value: 683
Caesium Hyperfine Frequency (symbol: Δν_Cs) — value: 9,192,631,770
Vacuum Electric Permittivity (symbol: ε₀) — value: 8.854 × 10
Vacuum Magnetic Permeability (symbol: μ₀) — value: 1.257 × 10
Characteristic Impedance of Vacuum (symbol: Z₀) — value: 376.730
Josephson Constant (symbol: K_J) — value: 4.836 × 10
Von Klitzing Constant (symbol: R_K) — value: 25812.807
Magnetic Flux Quantum (symbol: Φ₀) — value: 2.068 × 10
Conductance Quantum (symbol: G₀) — value: 7.748 × 10
Faraday Constant (symbol: F) — value: 96,485.332
Fine-Structure Constant (symbol: α) — value: 7.297 × 10
Rydberg Constant (symbol: R_∞) — value: 1.097 × 10
Bohr Radius (symbol: a₀) — value: 5.292 × 10
Hartree Energy (symbol: E_h) — value: 4.360 × 10
Bohr Magneton (symbol: μ_B) — value: 9.274 × 10
Nuclear Magneton (symbol: μ_N) — value: 5.051 × 10
Electron Mass (symbol: m_e) — value: 9.109 × 10
Electron g-factor (symbol: g_e) — value: −2.002319304
Proton Mass (symbol: m_p) — value: 1.673 × 10
Proton g-factor (symbol: g_p) — value: 5.586
Neutron Mass (symbol: m_n) — value: 1.675 × 10
Neutron Magnetic Moment (symbol: μ_n) — value: −9.662 × 10
Muon Mass (symbol: m_μ) — value: 1.884 × 10
Muon Anomalous Magnetic Moment (symbol: a_μ) — value: 0.0011659
Tau Lepton Mass (symbol: m_τ) — value: 3.168 × 10
Molar Gas Constant (symbol: R) — value: 8.314
Stefan-Boltzmann Constant (symbol: σ) — value: 5.670 × 10
Wien Displacement Constant (symbol: b) — value: 2.898 × 10
Gravitational Constant (symbol: G) — value: 6.674 × 10
Fermi Coupling Constant (symbol: G_F) — value: 1.166 × 10
Weak Mixing Angle (symbol: sin²θ_W) — value: 0.2229
Quantum of Circulation (symbol: κ) — value: 3.637 × 10
Thomson Cross Section (symbol: σ_T) — value: 6.652 × 10
Electron Charge-to-Mass Ratio (symbol: −e/m_e) — value: −1.759 × 10
Electron Molar Mass (symbol: M(e)) — value: 5.486 × 10
Electron-Proton Mass Ratio (symbol: m_e/m_p) — value: 5.446 × 10
Proton Charge-to-Mass Ratio (symbol: e/m_p) — value: 9.579 × 10
Proton Molar Mass (symbol: M(p)) — value: 1.007 × 10
Neutron-Electron Mass Ratio (symbol: m_n/m_e) — value: 1838.68
Neutron-Proton Mass Ratio (symbol: m_n/m_p) — value: 1.00138
Neutron g-factor (symbol: g_n) — value: −3.826
Neutron Molar Mass (symbol: M(n)) — value: 1.00866 × 10
Neutron Compton Wavelength (symbol: λ_Cn) — value: 1.320 × 10
Muon Compton Wavelength (symbol: λ_Cμ) — value: 1.173 × 10
Muon g-factor (symbol: g_μ) — value: −2.00233
Deuteron Mass (symbol: m_d) — value: 3.344 × 10
Deuteron Magnetic Moment (symbol: μ_d) — value: 4.331 × 10
Deuteron g-factor (symbol: g_d) — value: 0.8574
Helion Mass (symbol: m_h) — value: 5.006 × 10
Alpha Particle Mass (symbol: m_α) — value: 6.645 × 10
Atomic Mass Constant (symbol: m_u) — value: 1.661 × 10
Molar Mass Constant (symbol: M_u) — value: 1.000 × 10
Molar Planck Constant (symbol: N_Ah) — value: 3.990 × 10
Molar Volume of Ideal Gas (STP) (symbol: V_m) — value: 22.414 × 10
Loschmidt Constant (symbol: n₀) — value: 2.687 × 10
Molar Volume of Silicon (symbol: V_m,Si) — value: 1.206 × 10
Molar Mass of Carbon-12 (symbol: M(¹²C)) — value: 12.000 × 10
First Radiation Constant (symbol: c₁) — value: 3.742 × 10
First Radiation Constant for Spectral Radiance (symbol: c_1L) — value: 1.191 × 10
Second Radiation Constant (symbol: c₂) — value: 1.439 × 10
Standard Acceleration of Gravity (symbol: g) — value: 9.807
a.u. of Length (symbol: a₀) — value: 5.292 × 10
a.u. of Mass (symbol: m_e) — value: 9.109 × 10
a.u. of Time (symbol: t_au) — value: 2.419 × 10
a.u. of Energy (symbol: E_h) — value: 4.360 × 10
a.u. of Charge (symbol: e) — value: 1.602 × 10
a.u. of Velocity (symbol: v_au) — value: 2.188 × 10
a.u. of Momentum (symbol: p_au) — value: 1.993 × 10
a.u. of Force (symbol: F_au) — value: 8.239 × 10
a.u. of Electric Field (symbol: E_au) — value: 5.142 × 10
a.u. of Magnetic Flux Density (symbol: B_au) — value: 2.351 × 10
a.u. of Permittivity (symbol: ε_au) — value: 1.113 × 10
a.u. of Magnetizability (symbol: χ_au) — value: 7.891 × 10

Physics Symbols Reference

Phyansy covers 51 physics symbols including the full Greek alphabet (alpha α, beta β, gamma γ, delta δ, epsilon ε, zeta ζ, eta η, theta θ, iota ι, kappa κ, lambda λ, mu μ, nu ν, xi ξ, omicron ο, pi π, rho ρ, sigma σ, tau τ, upsilon υ, phi φ, chi χ, psi ψ, omega ω) and mathematical notation (nabla ∇, Laplacian ∇², partial derivative ∂, integral ∫, line integral ∮, summation Σ, product Π, Dirac bra-ket ⟨ψ|, tensor product ⊗, cross product ×, dot product ·, h-bar ħ, plus-or-minus ±, dagger † hermitian conjugate, magnitude |·|, hat notation, for-all ∀, there-exists ∃, element-of ∈, direct-sum ⊕, maps-to →, not-equal ≠, approximately-equal ≈, proportional-to ∝, infinity ∞, identically-equal ≡).

SI Units and Measurement

Phyansy covers all 7 SI base units: metre (m) for length, kilogram (kg) for mass, second (s) for time, ampere (A) for electric current, kelvin (K) for thermodynamic temperature, mole (mol) for amount of substance, candela (cd) for luminous intensity. Derived units include: newton (N = kg·m/s²), joule (J = N·m), watt (W = J/s), pascal (Pa = N/m²), coulomb (C = A·s), volt (V = J/C), ohm (Ω = V/A), farad (F = C/V), tesla (T = kg/(A·s²)), hertz (Hz = s⁻¹), weber (Wb = V·s), henry (H = Wb/A), siemens (S = Ω⁻¹), becquerel (Bq = s⁻¹), gray (Gy = J/kg), sievert (Sv = J/kg), lumen (lm = cd·sr), lux (lx = lm/m²). Non-SI units in physics: electron-volt (eV = 1.602×10⁻¹⁹ J), atomic mass unit (u = 1.661×10⁻²⁷ kg), light-year (ly ≈ 9.461×10¹⁵ m), parsec (pc ≈ 3.086×10¹⁶ m), angstrom (Å = 10⁻¹⁰ m), barn (b = 10⁻²⁸ m²). Metric prefixes: yocto (y, 10⁻²⁴), zepto (z, 10⁻²¹), atto (a, 10⁻¹⁸), femto (f, 10⁻¹⁵), pico (p, 10⁻¹²), nano (n, 10⁻⁹), micro (μ, 10⁻⁶), milli (m, 10⁻³), centi (c, 10⁻²), deci (d, 10⁻¹), deca (da, 10¹), hecto (h, 10²), kilo (k, 10³), mega (M, 10⁶), giga (G, 10⁹), tera (T, 10¹²), peta (P, 10¹⁵), exa (E, 10¹⁸), zetta (Z, 10²¹), yotta (Y, 10²⁴).