Calculate density from mass and volume with extensive unit conversions. Material database with 23+ substances for identification and comparison.
Density (ρ = m/V) is one of the most fundamental physical properties, relating the mass of an object to the space it occupies. Measured in kilograms per cubic meter (kg/m³) or grams per cubic centimeter (g/cm³), density determines whether objects float or sink, helps identify unknown materials, and is essential in engineering calculations from structural design to fluid dynamics.
Every material has a characteristic density: water is 1000 kg/m³, steel about 7850 kg/m³, and gold 19320 kg/m³. These values change slightly with temperature and pressure, but for most practical purposes they serve as reliable fingerprints for material identification. Compare a measured density against known values, and you can determine what a sample is made of without any chemical analysis.
This general-purpose density calculator handles seven volume units and four mass units, automatically converting everything to SI before computing density. A database of 23+ common materials provides instant identification of the closest matching substance, while the visual density scale puts your result in context against the full range of everyday materials.
This all-in-one density calculator handles the unit conversions that cause errors in manual calculations. Whether you are a student checking homework, a jeweler verifying gold purity, an engineer sizing a component, or a geologist classifying rock samples, the immediate material identification feature saves time and prevents mistakes.
The comprehensive material database and visual comparison tools make this calculator useful beyond simple ρ = m/V arithmetic—it is a material reference tool in its own right.
Density: ρ = m / V. Specific Gravity: SG = ρ / ρ_water (where ρ_water = 999.97 kg/m³ at 4 °C). Unit conversions: 1 g/cm³ = 1000 kg/m³ = 62.43 lb/ft³.
Result: 7850 kg/m³ (7.850 g/cm³) — Steel
Mass = 7.85 g = 0.00785 kg. Volume = 1 cm³ = 1×10⁻⁶ m³. Density = 0.00785 / 1e-6 = 7850 kg/m³, matching steel.
Density explains everyday phenomena: oil floats on water (oil ≈ 900 vs water ≈ 1000 kg/m³), helium balloons rise (helium ≈ 0.164 vs air ≈ 1.225 kg/m³), and ships float despite being made of steel (because the hull encloses a large air-filled volume, making average density less than water).
| Method | Best For | Accuracy | |---|---|---| | Weigh + measure dimensions | Regular shapes (cubes, cylinders) | ± 0.5–2% | | Water displacement | Irregular solid objects | ± 0.1–0.5% | | Pycnometer | Liquids and fine powders | ± 0.01% | | Hydrometer | Liquids (quick field test) | ± 0.5% | | Gas pycnometer | True density of porous solids | ± 0.01% |
An object floats when its average density is less than the surrounding fluid. A steel ship floats because the average density of the hull + enclosed air is well below 1000 kg/m³. A submarine adjusts its average density by flooding or emptying ballast tanks to sink, hover, or surface.
Osmium at 22,590 kg/m³ is the densest naturally occurring element. Among engineering materials, tungsten (19,250 kg/m³) and gold (19,320 kg/m³) are near the top.
Water has an unusual property: it expands when freezing, making ice (917 kg/m³) less dense than liquid water (1000 kg/m³). This anomalous expansion is due to hydrogen bonding forming an open crystal structure.
Specific gravity is the ratio of a material's density to water's density. It is dimensionless. Numerically, specific gravity equals density in g/cm³ (since water ≈ 1 g/cm³).
For gases, dramatically—density halves when temperature doubles (at constant pressure). For liquids, the effect is 0.01–0.1% per °C. For solids, changes are typically under 0.01% per °C.
Yes—Archimedes' method. Submerge the object in water and measure the displaced volume. This works for any shape and avoids dimensional measurement errors, but the object must be waterproof.
Bulk density includes air spaces between particles (e.g., in a pile of sand), while true density is the density of the solid material itself. Bulk density is always lower than true density.