Convert Electronvolt to Kilowatt-Hour (eV → kWh)
The electronvolt is the standard energy unit in atomic physics, particle physics, and semiconductor band-gap analysis.
Electronvolt to Kilowatt-Hour Conversion Table
10 common values| Electronvolt | Kilowatt-Hour |
|---|---|
| 1 eV | 4.45 × 10^-26 kWh |
| 10 eV | 4.45 × 10^-25 kWh |
| 100 eV | 4.45 × 10^-24 kWh |
| 500 eV | 2.225 × 10^-23 kWh |
| 1,000 eV | 4.45 × 10^-23 kWh |
| 5,000 eV | 2.225 × 10^-22 kWh |
| 10,000 eV | 4.45 × 10^-22 kWh |
| 50,000 eV | 2.225 × 10^-21 kWh |
| 100,000 eV | 4.45 × 10^-21 kWh |
| 500,000 eV | 2.225 × 10^-20 kWh |
How to Convert Electronvolt to Kilowatt-Hour Manually
Step by StepConverting electronvolts to kilowatt-hours is straightforward: multiply by the conversion factor. Follow these three steps to do it by hand or in your head.
- 1Take your value in electronvoltsStart with the number of electronvolts (eV) you want to convert.
- 2Multiply by 4.45 × 10^-26The conversion factor from eV to kWh is 4.45 × 10^-26. Multiply your value by this number.
- 3Read the result in kilowatt-hoursThe result is your value in kilowatt-hours (kWh).
Formula
Multiply the value in electronvolts by 4.45 × 10^-26. For the reverse direction, multiply by 2.247 × 10^25.
kWh = eV × 4.45 × 10^-26eV = kWh × 2.247 × 10^25Tips
Use these in everyday conversions- 1 eV ≈ 1.602 × 10⁻¹⁹ J.
- Particle physics scales: eV → keV → MeV → GeV → TeV (1000× each).
- Photon energy (eV) × wavelength (nm) ≈ 1240.
Common Mistakes
Avoid these- Confusing eV with V (volt) — eV is energy, V is electric potential.
- Mixing scales: treating MeV as twice eV — it's a million times larger.
- Using eV for macroscopic energy — unwieldy numbers.
About Electronvolt and Kilowatt-Hour
What is the Electronvolt?
The electronvolt equals approximately 1.602176634 × 10⁻¹⁹ joules (a tiny amount of energy) and is the standard unit in atomic physics, particle physics, and semiconductor electronics. Defined as the energy gained by an electron accelerated through a potential difference of 1 volt, the eV is the natural scale for atomic and molecular energies. The energy required to ionize a hydrogen atom is 13.6 eV, the band gap of silicon (relevant for transistors and solar cells) is 1.12 eV, and visible light photons carry 1.6–3.3 eV per photon. Particle physicists routinely use MeV (million eV), GeV (billion eV), and TeV (trillion eV): the Large Hadron Collider accelerates protons to 6.5 TeV. The eV relates to the joule (1 eV ≈ 1.602 × 10⁻¹⁹ J), the kilojoule per mole (96.485 kJ/mol per eV), and atomic mass units via E = mc². It is the universal energy unit in physics literature.
- Particle physics (TeV, GeV, MeV)
- Atomic and molecular physics
- Semiconductor band gaps
Silicon band gap: 1.12 eV. Hydrogen ionization: 13.6 eV. LHC proton: 7 TeV. Photon wavelength 500 nm = 2.5 eV.
What is the Kilowatt-Hour?
The kilowatt-hour equals 1,000 watt-hours (3.6 megajoules) and is the universal billing unit for residential electricity consumption around the world. A typical US household uses about 800–1,000 kWh per month; a refrigerator consumes 1–2 kWh per day, an LED bulb at 10 W for 10 hours uses 0.1 kWh, and a Tesla Model 3 has a 75 kWh battery (about 250–350 miles of range). Electric utility rates are quoted in cents per kWh — typical US residential rates are 11–25 ¢/kWh, while industrial rates are lower. The kilowatt-hour is essential in renewable-energy planning: solar panel output, wind farm production, and grid-scale storage are all rated in kWh or MWh (megawatt-hours). It relates to the watt-hour (1,000 Wh = 1 kWh), the joule (1 kWh = 3.6 MJ), the BTU (1 kWh ≈ 3,412 BTU), and the megawatt-hour (1,000 kWh = 1 MWh).
- Electricity billing globally
- EV battery capacity specifications
- Home solar and battery storage
UK home: ~2900 kWh/year. Tesla Model 3 battery: 60–80 kWh. Typical EV efficiency: 15–20 kWh/100 km.