Calculate Hawking temperature of a black hole from its mass. Find event horizon radius, evaporation time, luminosity, and entropy using black hole thermodynamics.
The **Black Hole Temperature Calculator** computes the Hawking temperature of a black hole — the thermal radiation predicted by Stephen Hawking in 1974. This groundbreaking result links quantum mechanics, general relativity, and thermodynamics in one of the most profound equations in physics: T = ℏc³/(8πGMk_B).
Surprisingly, black holes are not entirely black. Quantum effects near the event horizon cause them to emit thermal radiation with a characteristic temperature inversely proportional to their mass. A stellar-mass black hole of 10 solar masses has a temperature of only ~6×10⁻⁹ K — far colder than the cosmic microwave background. But a microscopic black hole of 10¹² kg would blaze at ~10¹¹ K, hotter than any star.
This calculator computes Hawking temperature along with the Schwarzschild radius, event horizon area, Bekenstein-Hawking entropy, luminosity, and evaporation time. Explore the exotic thermodynamics of black holes from primordial micro-holes to supermassive galactic cores. Check the example with realistic values before reporting.
Exploring black hole thermodynamics is essential for students of general relativity, quantum gravity, and astrophysics. This calculator lets you instantly compute Hawking temperatures for any mass — from primordial micro-holes to supermassive galactic centers.
It is also a powerful teaching tool, demonstrating the counterintuitive inverse relationship between mass and temperature, the staggering evaporation timescales, and the deep connections between gravity, quantum mechanics, and thermodynamics.
Hawking Temperature: T = ℏc³ / (8πGMk_B) Where: - ℏ = reduced Planck constant = 1.0546 × 10⁻³⁴ J·s - c = speed of light = 2.998 × 10⁸ m/s - G = gravitational constant = 6.674 × 10⁻¹¹ m³/(kg·s²) - M = black hole mass (kg) - k_B = Boltzmann constant = 1.381 × 10⁻²³ J/K Schwarzschild Radius: rₛ = 2GM/c² Evaporation Time: t = 5120πG²M³/(ℏc⁴)
Result: 6.17 × 10⁻⁹ K
A 10 solar mass black hole (M = 1.989 × 10³¹ kg) has a Hawking temperature of about 6.17 nanokelvin — incredibly cold, far below the 2.7 K cosmic microwave background. Its Schwarzschild radius is about 29.5 km.
The four laws of black hole thermodynamics parallel the four laws of classical thermodynamics. The zeroth law states that the surface gravity of a stationary black hole is constant over the event horizon (analogous to temperature equilibrium). The first law relates changes in mass, area, and angular momentum (analogous to energy conservation). The second law — Hawking's area theorem — states that the total event horizon area never decreases (analogous to entropy increase). The third law states that the surface gravity cannot be reduced to zero in a finite process.
If a black hole completely evaporates via Hawking radiation, what happens to the information about everything that fell in? Hawking radiation is purely thermal — it carries no information about the black hole is interior. This creates a fundamental conflict with quantum mechanics, which requires information to be preserved. This "information paradox" remains one of the biggest open problems in theoretical physics, with proposed solutions including complementarity, firewalls, and soft hair.
While direct detection of Hawking radiation from astrophysical black holes is far beyond current technology, primordial black holes (formed in the early universe) with the right initial mass could be evaporating today. Their final moments would produce a burst of gamma rays — searches for such bursts by telescopes like Fermi-LAT could provide indirect evidence for Hawking radiation and constrain the abundance of primordial black holes.
Hawking radiation is thermal radiation predicted to be emitted by black holes due to quantum effects near the event horizon. Virtual particle pairs near the horizon can be separated, with one falling in and the other escaping as real radiation.
Yes — Hawking proved that black holes emit radiation with a perfect black-body spectrum at a specific temperature. For astrophysical black holes, this temperature is extraordinarily low (nanokelvin range), but it is theoretically real.
Temperature is inversely proportional to mass. Smaller event horizons have higher surface gravity and stronger tidal forces, producing more energetic virtual particle pairs and higher-temperature radiation.
The evaporation time for a solar-mass black hole is ~10⁶⁷ years — vastly longer than the current age of the universe (1.38 × 10¹⁰ years). Only tiny primordial black holes could have evaporated by now.
It is the thermodynamic entropy of a black hole, proportional to the event horizon area (not volume). This was surprising and led to the holographic principle — the idea that information content of a region is encoded on its boundary.
Not directly from an actual black hole — the radiation is far too faint. However, analog experiments using sonic black holes in Bose-Einstein condensates have observed effects consistent with Hawking radiation.