Horsepower (International) to Petawatt

By the mid-20th century, at least five different horsepower definitions existed: British mechanical, metric (PS), electric, boiler, and water. International trade required a single reference. The 1956 agreement standardized the mechanical/British value (745.699872 W) as the international benchmark. This didn't eliminate the others — metric PS persists in Europe, electric hp in US motors — but it gave engineers a common reference when precision matters or when "hp" appears without qualification.

SAE J1349 specifies measuring net horsepower with all production accessories (alternator, water pump, AC compressor) attached, at standard atmospheric conditions. Before 1972, US manufacturers used gross hp (engine on a test stand with minimal accessories), which inflated numbers by 15–25%. The switch to SAE net ratings famously caused "overnight" power drops: a Corvette went from "350 hp" (gross) to "255 hp" (net) in 1972 — same engine, honest measurement.

Japan officially uses metric PS (called 馬力, "horse power," abbreviated PS after the German). Japanese car specs list PS, and JIS standards define power in PS. However, for international export, Japanese manufacturers convert to international hp or kW depending on the destination market. A Nissan GT-R produces 570 PS for the Japanese market and 565 hp for the US market — the same engine, different unit systems, and the ~1% gap occasionally causes forum arguments.

The Wärtsilä-Sulzer RTA96-C, a marine diesel engine used in the largest container ships, produces about 109,000 hp (international) — 80,080 kW from 14 cylinders each the size of a small apartment. It's 13.5 meters tall and weighs 2,300 tonnes. At 102 RPM, it turns propellers the size of houses. For comparison, a Saturn V rocket's five F-1 engines produced about 217 million hp combined, but only for 2.5 minutes.

Probably, but slowly. The EU already legally requires kW; China uses kW; scientific and engineering communities prefer kW. But cultural inertia is powerful — Americans have been buying cars by horsepower for over a century, and "how many horses under the hood" is deeply embedded in car culture. The transition to EVs may accelerate the shift, since electric motors are naturally rated in kW. Give it 20–30 years, and hp may join the furlong and the gill in the museum of obsolete units.

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.