Petawatt to Kilowatt

It's a time trick. A petawatt laser concentrates a modest amount of energy (maybe 100–500 joules) into a pulse lasting 10–100 femtoseconds. Dividing a few hundred joules by 10⁻¹⁴ seconds gives you 10¹⁵–10¹⁶ watts — surpassing the Sun's 3.8 × 10²⁶ W is still far off, but these lasers do exceed total human power consumption by 100,000×. The catch: the total energy delivered is only enough to heat a cup of coffee.

Primarily for nuclear fusion research (compressing fuel pellets), particle acceleration (laser wakefield acceleration can produce electron beams rivalling billion-dollar synchrotrons), medical isotope production, and probing extreme states of matter found in stellar cores. The ELI (Extreme Light Infrastructure) project in Europe uses petawatt lasers to recreate conditions found in supernovae, helping astrophysicists study cosmic explosions in a lab.

Solar flares can briefly release 10–100 PW of electromagnetic radiation. The Chicxulub asteroid impact (the one that killed the dinosaurs) delivered roughly 4 × 10²³ watts during the few seconds of impact — about 100 million petawatts. Gamma-ray bursts top everything at 10²⁵–10²⁶ PW, briefly outshining the entire observable universe. Even supernovae "only" sustain about 10³⁶ PW for a few seconds at peak.

Building one costs $50–500 million. Operating costs are surprisingly modest per shot — each pulse uses only a few hundred joules (less than lifting an apple one meter), but the capacitor banks and cooling systems draw megawatts of continuous power. The NIF facility costs about $350 million per year to operate. Individual shots are "cheap" in energy terms but the infrastructure to achieve them is staggering.

In theory yes, but in practice current petawatt lasers are terrible weapons. They fire one pulse every few minutes to hours, require warehouse-sized buildings of equipment, and deliver total energy equivalent to a firecracker. Military-grade laser weapons focus on sustained power (100–300 kW continuous beams), not ultrashort pulses. A petawatt laser is a precision scientific scalpel, not a blunt instrument — brilliant for physics, useless for destruction.

A typical Western household draws 1–5 kW on average, but peak demand can spike to 10–15 kW when the oven, dryer, AC, and water heater all run simultaneously. This peak is why electrical panels are sized at 100–200 amps (24–48 kW capacity). Adding an EV charger at 7–11 kW can push some older homes past their panel limits, requiring an upgrade.

EU directive 80/181/EEC mandated kilowatts as the official unit for engine power, making kW the legally required figure on vehicle documents since 2010. Manufacturers still advertise in PS (metric horsepower) because consumers are used to it, but the official registration papers always list kW. One kW equals about 1.36 PS, so a 100 kW engine is roughly 136 PS.

Home Level 2 chargers draw 7–22 kW, adding 30–130 km of range per hour. Public DC fast chargers range from 50 kW (older units) to 350 kW (latest ultra-rapid chargers). Tesla Superchargers V3 peak at 250 kW. A 350 kW charger can add 300 km of range in about 15 minutes on compatible vehicles — but your home wiring cannot deliver anywhere near that without industrial-grade supply.

When power returns after an outage, everything turns on simultaneously — fridges, AC compressors, water heaters, furnaces — creating an "inrush" spike 3–5× normal draw. A home that normally peaks at 10 kW might briefly pull 30–40 kW. This is why utilities restore grids in stages (rolling reconnection) rather than all at once: if an entire neighborhood surges simultaneously, transformers can overload and blow, causing a cascading failure that extends the blackout. Some smart thermostats now stagger restart to reduce this risk.

With modern 400 W residential panels, you need just 2.5 panels (so 3 in practice) for 1 kW of peak capacity. A decade ago, when panels were 250 W each, you needed 4. That 1 kW of panels produces roughly 1,000–1,600 kWh per year depending on location — enough to power a large refrigerator for a full year. A typical home installation is 4–10 kW (10–25 panels).