Millimeter Mercury to Pound per Square Foot

Clinical medicine is deeply conservative about units because misreadings kill people. Doctors, nurses, and patients worldwide have memorized "120/80 is normal" in mmHg. Converting to kPa (16.0/10.7) would require retraining millions of clinicians and rewriting every guideline. The WHO considered the switch and decided the risk of transcription errors during transition outweighed the elegance of SI compliance. So mmHg stays — likely for decades more.

The top number (systolic) is the peak pressure when the heart contracts and pushes blood into the arteries — typically 90–120 mmHg. The bottom number (diastolic) is the lowest pressure between beats when the heart relaxes — typically 60–80 mmHg. A reading of 140/90 mmHg or above is classified as hypertension. The gap between the two (pulse pressure) also matters: a wide gap above 60 mmHg may signal stiff arteries.

In 1643, Evangelista Torricelli filled a glass tube with mercury, inverted it into a dish of mercury, and watched the column drop to about 760 mm. The empty space above was the first laboratory vacuum. The height of the mercury column became the measurement of atmospheric pressure — 760 mmHg at sea level. Nearly 400 years later, we still use his column height as a pressure unit in medicine and vacuum science.

For all practical purposes, they are identical — 1 torr = 1/760 atm ≈ 133.322 Pa, and 1 mmHg ≈ 133.322 Pa. The difference is about 0.00015% and arises from the torr being defined from the atmosphere while mmHg is defined from mercury density. Medicine uses mmHg; vacuum physics uses torr. They are interchangeable in any real-world measurement.

Intraocular pressure (glaucoma screening): normal is 10–21 mmHg, above 21 is suspicious. Partial pressure of oxygen in arterial blood (PaO₂): normal is 80–100 mmHg. Central venous pressure: 2–6 mmHg. Intracranial pressure: normal below 15 mmHg, dangerous above 20 mmHg. Carbon dioxide in blood (PaCO₂): 35–45 mmHg. The unit pervades clinical monitoring far beyond the blood pressure cuff.

Because building loads — snow, wind, furniture, people — are naturally distributed over large floor and wall areas measured in square feet. A residential floor designed for 40 psf live load makes intuitive sense: imagine 40 pounds sitting on each square foot of carpet. Converting to psi (0.278 psi) gives a fraction that obscures the physical picture. The US International Building Code specifies all loads in psf for this reason.

Residential living areas: 40 psf. Office floors: 50 psf. Retail stores: 75–100 psf. Library stack rooms: 150 psf. Heavy manufacturing: 250+ psf. Balconies and decks: 60 psf minimum. Roofs must handle snow load (varies by region — 20 psf in Atlanta, 50+ psf in Minnesota) plus a minimum 20 psf construction live load. These values have decades of structural failure data baked into them.

1 psf = 1/144 psi ≈ 0.00694 psi = 47.88 Pa. To go from psi to psf, multiply by 144 (since 1 ft² = 144 in²). Standard atmospheric pressure is about 2,116 psf — which demonstrates why the unit is sized for building loads, not gas pressures. For international projects, multiply psf by 47.88 to get pascals, or by roughly 4.88 to get kgf/m².

Wind pressure scales with the square of wind speed. At 70 mph: about 12 psf. At 100 mph: ~25 psf. At 150 mph (Category 4 hurricane): ~56 psf. Building codes apply additional factors for height, exposure, and shape — a tall building in open terrain sees higher effective psf than a squat building sheltered by trees. Cladding and windows are tested against these design pressures before installation.

Rarely. Most countries use kilopascals (kPa) or kilonewtons per square meter (kN/m²) for structural loads — both are SI-compatible and numerically equivalent (1 kPa = 1 kN/m²). The psf is essentially a US-only unit, found in IBC (International Building Code, despite the name) and ASCE 7 load standards. Engineers working on international projects routinely convert psf to kPa by multiplying by 0.04788.