Density: Difference between revisions

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	The density of a solid material can be ambiguous, depending on exactly how its volume is defined, and this may cause confusion in measurement. A common example is sand: if it is gently poured into a container, the density will be low; if the same sand is compacted into the same container, it will occupy less volume and consequently exhibit a greater density. This is because sand, like all powders and granular solids, contains a lot of air space in between individual grains. The density of the material including the air spaces is the ], which differs significantly from the density of an individual grain of sand with no air included.		The density of a solid material can be ambiguous, depending on exactly how its volume is defined, and this may cause confusion in measurement. A common example is sand: if it is gently poured into a container, the density will be low; if the same sand is compacted into the same container, it will occupy less volume and consequently exhibit a greater density. This is because sand, like all powders and granular solids, contains a lot of air space in between individual grains. The density of the material including the air spaces is the ], which differs significantly from the density of an individual grain of sand with no air included.

	== Formal definition ==
	Density is defined as '''mass per unit volume'''. A concise statement of what this means may be obtained by considering a small box in a ], with dimensions <math>\Delta x</math>, <math>\Delta y</math>, <math>\Delta z</math>. If the mass is represented by a net mass function, then the density at some point <math>(x,y,z)</math> is:
	:<math>\begin{align}
	\rho(x,y,z) & = \lim_{Volume \to 0}\frac{\mbox{mass of box}}{\mbox{volume of box}} \\
	& = \lim_{\Delta x, \Delta y, \Delta z \to 0}\left(\frac{
	m(x + \Delta x, y + \Delta y, z + \Delta z) - m(x, y, z)}{\Delta x \Delta y \Delta z}\right) \\
	& = \frac{d m}{d V}\\
	\end{align}\,</math>

	For a homogeneous substance, this ] is equal to the net mass divided by the net volume. For a nonhomogeneous substance, <math>m</math> is a nonconstant function of position: <math>m = m(x, y, z)</math>.
	<!-- In this case, the ] can be used to expand the derivative:
	:<math>\rho = \frac{1}{L_x^2} \frac{\partial m}{\partial x} + \frac{1}{L_y^2} \frac{\partial m}{\partial y} + \frac{1}{L_z^2} \frac{\partial m}{\partial z}\,</math>.

	where <math>L_x</math>, <math>L_y</math>, <math>L_z</math> are the scales of the axes (]s, for example).

	-->

	== Common units ==		== Common units ==

Revision as of 21:51, 4 December 2009

This article is about volumetric mass density. For other uses, see Density (disambiguation).

The density of a material is defined as its mass per unit volume. The symbol of density is ρ (the Greek letter rho).

Formula

Mathematically:

\rho ={\frac {m}{V}}\,

where:

\rho

(rho) is the density,

m

is the mass,

V

is the volume.

Different materials usually have different densities, so density is an important concept regarding buoyancy, metal purity and packaging.

In some cases density is expressed as the dimensionless quantities specific gravity (SG) or relative density (RD), in which case it is expressed in multiples of the density of some other standard material, usually water or air/gas.

History

In a well-known tale, Archimedes was given the task of determining whether King Hiero's goldsmith was embezzling gold during the manufacture of a wreath dedicated to the gods and replacing it with another, cheaper alloy.

Archimedes knew that the irregularly shaped wreath could be crushed into a cube whose volume could be calculated easily and compared with the weight; but the king did not approve of this.

Baffled, Archimedes took a relaxing immersion bath and observed from the rise of the warm water upon entering that he could calculate the volume of the gold crown through the displacement of the water. Allegedly, upon this discovery, he went running naked through the streets shouting, "Eureka! Eureka!" (Εύρηκα! Greek "I found it"). As a result, the term "eureka" entered common parlance and is used today to indicate a moment of enlightenment.

This story first appeared in written form in Vitruvius' books of architecture, two centuries after it supposedly took place. Some scholars have doubted the accuracy of this tale, saying among other things that the method would have required precise measurements that would have been difficult to make at the time.

Measurement of density

For a homogeneous object, the mass divided by the volume gives the density. The mass is normally measured with an appropriate scale or balance; the volume may be measured directly (from the geometry of the object) or by the displacement of a fluid. Hydrostatic weighing is a method that combines these two.

If the body is not homogeneous, then the density is a function of the position: $\rho ({\vec {r}})=dm/dv$ , where $dv$ is an elementary volume at position ${\vec {r}}$ . The mass of the body then can be expressed as

m=\int _{V}\rho ({\vec {r}})dV

The density of a solid material can be ambiguous, depending on exactly how its volume is defined, and this may cause confusion in measurement. A common example is sand: if it is gently poured into a container, the density will be low; if the same sand is compacted into the same container, it will occupy less volume and consequently exhibit a greater density. This is because sand, like all powders and granular solids, contains a lot of air space in between individual grains. The density of the material including the air spaces is the bulk density, which differs significantly from the density of an individual grain of sand with no air included.

Common units

The SI unit for density is:

kilograms per cubic metre (kg/m³)

The following non-SI metric units all have exactly the same numerical value, one thousandth of the SI value in (kg/m³). Liquid water has a density of about 1kg/L (exactly 1.000 kg/L by definition at 4 °C), making any of these units numerically convenient to use as most solids and liquids have densities between 0.1 and 20 kg/L.; density is usually given in these units rather than the SI unit.

kilograms per litre (kg/L).
kilograms per cubic decimeter (kg/dm³),
grams per millilitre (g/mL),
grams per cubic centimeter (g/cc, gm/cc or g/cm³).

In U.S. customary units density can be stated in:

Avoirdupois ounces per cubic inch (oz/cu in)
Avoirdupois pounds per cubic inch (lb/cu in)
pounds per cubic foot (lb/cu ft)
pounds per cubic yard (lb/cu yd)
pounds per U.S. liquid gallon or per U.S. dry gallon (lb/gal)
pounds per U.S. bushel (lb/bu)
slugs per cubic foot.

In principle there are Imperial units different from the above as the Imperial gallon and bushel differ from the U.S. units, but in practice they are no longer used, though found in older documents. The density of precious metals could conceivably be based on Troy ounces and pounds, a possible cause of confusion.

Changes of density

In general, density can be changed by changing either the pressure or the temperature. Increasing the pressure will always increase the density of a material. Increasing the temperature generally decreases the density, but there are notable exceptions to this generalisation. For example, the density of water increases between its melting point at 0 °C and 4 °C; similar behaviour is observed in silicon at low temperatures.

The effect of pressure and temperature on the densities of liquids and solids is small. The compressibility for a typical liquid or solid is 10 bar (1 bar=0.1 MPa) and a typical thermal expansivity is 10 K.

In contrast, the density of gases is strongly affected by pressure. The density of an ideal gas is

\rho ={\frac {MP}{RT}}\,

where $R$ is the universal gas constant, $P$ is the pressure, $M$ is the molar mass, and $T$ is the absolute temperature. This means that the density of an ideal gas can be doubled by doubling the pressure, or by halving the absolute temperature.

Osmium is the densest known substance at standard conditions for temperature and pressure.

Density of water

See also: Water density

Temp (°C)	Density (kg/m)
100	958.4
80	971.8
60	983.2
40	992.2
30	995.6502
25	997.0479
22	997.7735
20	998.2071
15	999.1026
10	999.7026
4	999.9720
0	999.8395
−10	998.117
−20	993.547
−30	983.854
The density of water in kilograms per cubic meter (SI unit) at various temperatures in degrees Celsius. The values below 0 °C refer to supercooled water.

Density of air

T in °C	ρ in kg/m (at 1 atm)
–25	1.423
–20	1.395
–15	1.368
–10	1.342
–5	1.316
0	1.293
5	1.269
10	1.247
15	1.225
20	1.204
25	1.184
30	1.164
35	1.146

Density of solutions

The density of a solution is the sum of the mass (massic) concentrations of the components of that solution.
Mass (massic) concentration of a given component ρ_i in a solution can be called partial density of that component.

Density of composite material

ASTM specification D792-00 describes the steps to measure the density of a composite material. $\rho ={\frac {W_{a}}{W_{a}+W_{w}-W_{b}}}\left(0.9975\right)\,$

where:

\rho

is the density of the composite material, in g/cm

and

W_{a}

is the weight of the specimen when hung in the air

W_{w}

is the weight of the partly immersed wire holding the specimen

W_{b}

is the weight of the specimen when immersed fully in distilled water, along with the partly immersed wire holding the specimen

0.9975

is the density in g/cm of the distilled water at 23°C

Densities of various materials

Material	ρ in kg/m	Notes
Interstellar medium	10 − 10	Assuming 90% H, 10% He; variable T
Earth's atmosphere	1.2	At sea level
Aerogel	1 − 2
Styrofoam	30 − 120	From
Cork	220 − 260	From
Water	1000	At STP
Plastics	850 − 1400	For polypropylene and PETE/PVC
Glycerol	1261
The Earth	5515.3	Mean density
Copper	8920 − 8960	Near room temperature
Lead	11340	Near room temperature
Tungsten	19250	Near room temperature
Gold	19300	Near room temperature
The Inner Core of the Earth	~13000	As listed in Earth
Uranium	19100	Near room temperature
Iridium	22500	Near room temperature
Osmium	22610	Near room temperature
The core of the Sun	~150000
White dwarf star	1 × 10
Atomic nuclei	2.3 × 10	Does not depend strongly on size of nucleus
Neutron star	8.4 × 10 — 1 × 10
Black hole	4 × 10	Mean density inside the Schwarzschild radius of an earth-mass black hole (theoretical)

References

Archimedes, A Gold Thief and Buoyancy - by Larry "Harris" Taylor, Ph.D.
Vitruvius on Architecture, Book IX, paragraphs 9-12, translated into English and in the original Latin.
The first Eureka moment, Science 305: 1219, August 2004.
Fact or Fiction?: Archimedes Coined the Term "Eureka!" in the Bath, Scientific American, December 2006.
(2004). Test Methods for Density and Specific Gravity (Relative Density) of Plastics by Displacement. ASTM Standard D792-00. Vol 81.01. American Society for Testing and Materials. West Conshohocken. PA.
glycerol composition at physics.nist.gov
Glycerol density at answers.com
Extreme Stars: White Dwarfs & Neutron Stars, Jennifer Johnson, lecture notes, Astronomy 162, Ohio State University. Accessed on line May 3, 2007.
Nuclear Size and Density, HyperPhysics, Georgia State University. Accessed on line June 26, 2009.

External links

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