Convert between wavelength, frequency, and photon energy using E = hc/λ. Supports eV, Joules, kJ/mol, and wave number for the full electromagnetic spectrum.
The wavelength to energy calculator converts between the three fundamental properties of electromagnetic radiation — wavelength, frequency, and photon energy — using the Planck-Einstein relation E = hf = hc/λ. Every photon in the universe, from radio waves to gamma rays, has its energy completely determined by its wavelength.
This relationship is the foundation of spectroscopy, quantum mechanics, and photonics. When a chemist identifies a compound by its absorption spectrum, they're measuring which photon energies (wavelengths) the molecule absorbs. When an astronomer determines a star's temperature from its color, they're using the wavelength-energy relationship. When an engineer designs a solar cell, they need to know which photon energies exceed the semiconductor bandgap.
This calculator supports multiple unit systems — nm, µm, Å for wavelength; Hz through PHz for frequency; eV, keV, MeV, J, and kJ/mol for energy — and includes wave number (cm⁻¹) used in infrared spectroscopy. Built-in presets cover common wavelengths from gamma rays to microwaves, with visible-light color display and full EM spectrum classification.
Converting between wavelength, frequency, and photon energy is one of the most common calculations in spectroscopy, quantum physics, photonics, and chemistry. Whether you're identifying spectral lines, designing optical filters, calculating semiconductor bandgap thresholds, or comparing bond dissociation energies to photon energies, this calculator provides instant conversion with proper unit handling.
The built-in EM spectrum classification and visible-light color display make it an ideal quick-reference tool for anyone working with electromagnetic radiation across the full spectrum from radio waves to gamma rays.
Planck-Einstein relation: E = hf = hc/λ Where: • E = photon energy (J or eV) • h = 6.626 × 10⁻³⁴ J·s (Planck's constant) • f = frequency (Hz) • c = 2.998 × 10⁸ m/s (speed of light) • λ = wavelength (m) Derived: • Wave number: ν̃ = 1/λ (cm⁻¹) • Momentum: p = h/λ (kg·m/s) • Per mole: E_mol = E × Nₐ (where Nₐ = 6.022 × 10²³)
Result: Photon energy = 2.48 eV (3.97 × 10⁻¹⁹ J)
Green light at 500 nm: E = hc/λ = (6.626×10⁻³⁴ × 2.998×10⁸) / (500×10⁻⁹) = 3.97×10⁻¹⁹ J = 2.48 eV. This energy exceeds the 1.1 eV bandgap of silicon, meaning silicon solar cells can absorb green light.
Max Planck's 1900 hypothesis that energy comes in discrete quanta E = hf was the birth of quantum mechanics. Einstein extended this in 1905, showing that light itself consists of particles (photons) each carrying this quantized energy. The relation E = hc/λ connects the wave property (wavelength) to the particle property (energy) of light, bridging the wave-particle duality.
This equation has stood unchanged for over a century and remains one of the most precisely verified relationships in physics. Planck's constant h = 6.62607015 × 10⁻³⁴ J·s is now defined exactly (as of 2019), making the wavelength-energy conversion exact by definition.
In chemistry, the Planck-Einstein relation explains why UV light can break chemical bonds while visible light cannot. A C-C single bond has a dissociation energy of about 350 kJ/mol (3.6 eV), requiring photons with λ < 345 nm. This is why sunlight causes photochemical damage — its UV component carries enough energy per photon to disrupt molecular bonds.
In astronomy, Wien's displacement law (λ_max = b/T) combined with E = hc/λ tells us a star's surface temperature from its color. The Sun peaks at ~500 nm (~2.5 eV), our bodies emit at ~10 µm (~0.12 eV), and the cosmic microwave background at 1.06 mm (~0.001 eV) reveals the universe's 2.7 K temperature.
Different fields prefer different energy units, and converting between them is a constant need. Atomic physics uses eV (electron volts), chemistry uses kJ/mol (kilojoules per mole), spectroscopy uses cm⁻¹ (wave numbers), and high-energy physics uses keV or MeV. The key conversions: 1 eV = 1.602 × 10⁻¹⁹ J = 96.49 kJ/mol = 8066 cm⁻¹ = 1240 nm wavelength.
The angstrom (Å = 10⁻¹⁰ m) remains popular in crystallography despite not being an SI unit, because atomic bonds and X-ray wavelengths are conveniently ~1-2 Å. The wave number cm⁻¹ persists in infrared spectroscopy because it's linearly proportional to energy, making spectrum interpretation intuitive.
E = hc/λ means shorter wavelengths carry more energy per photon. This is because shorter wavelengths correspond to higher frequencies (f = c/λ), and energy is directly proportional to frequency (E = hf). A UV photon at 250 nm has twice the energy of a visible photon at 500 nm.
eV (electron volt) is the energy of a single photon — useful in physics and electronics. kJ/mol is the energy of one mole (6.022×10²³) of photons — useful in chemistry for comparing to bond energies. Conversion: 1 eV per photon = 96.49 kJ/mol.
Wave number ν̃ = 1/λ (in cm⁻¹) is directly proportional to energy, making it convenient for infrared spectroscopy. Chemists prefer it because absorption peaks at higher wave numbers mean higher energy, and the scale is linear with energy. The C=O stretch at ~1700 cm⁻¹ has higher energy than C-H bending at ~1400 cm⁻¹.
E = hf applies to any quantum, but E = hc/λ is specific to photons traveling at the speed of light. For matter waves (electrons, neutrons), the de Broglie relation λ = h/p gives wavelength from momentum, but the energy-wavelength relationship is different: E = p²/(2m) = h²/(2mλ²).
The ionization energy of hydrogen is 13.6 eV, corresponding to a wavelength of 91.2 nm (extreme ultraviolet). Any photon with λ < 91.2 nm can ionize hydrogen from its ground state. This is the Lyman limit, important in astrophysics.
A 1 mW green laser (532 nm, 2.33 eV per photon) emits about 2.68 × 10¹⁵ photons per second: N = P/E = 0.001 / (3.74×10⁻¹⁹) ≈ 2.68×10¹⁵. Enter the photon count in the calculator to verify total beam energy.