Five Ways to Differentiate Density from Specific Gravity

Density and specific gravity are two properties of matter that have many similarities, but also some differences. To begin with, both are intensive properties of matter that do not depend on the extent of the system but only on its composition. Additionally, both represent a way to determine, between two substances, which is heavier when we compare them in equal volumes.

However, despite their similarities, density and specific gravity are not the same. Next, we will discuss the main differences between these two important properties of matter.

Difference 1: They are represented with different symbols

The first difference between these two intensive properties of matter is that they are both represented by different symbols. Depending on the context in which it is used, density is usually represented either by the letter d or by the Greek letter ρ (ro), the second being the most commonly used in physics and in the different branches of engineering.

Instead, specific gravity is represented by the symbol SG (for its acronym in English), although sometimes GE is used in Spanish and in other cases it is simply represented by S.

Difference 2: They are calculated by means of different formulas

The most important difference between density and specific gravity is that they are defined differently.

On the one hand, density is defined as the relationship between the mass of a substance and the volume it occupies in space . In this sense, it represents the mass of a unit volume of substance. In mathematical form, density is defined as:

Where ρ is the density of the substance, m is its mass, and V represents the corresponding volume of said mass of substance.

On the other hand, specific gravity, also called specific density or relative density, is defined as the ratio between the density of a substance and the density of another substance used as a reference standard . Similarly, it can also be defined as the ratio between the specific weight of a substance and the specific weight of another reference substance.

In the case of substances in condensed states (solid or liquid), the reference substance is usually pure water at a temperature of 4 °C and a pressure of 1 atm, conditions under which water has a density of 1000 kg. /m ³ . On the other hand, in the case of gaseous substances, the reference density is usually air. Therefore, specific gravity can be defined mathematically by one of the following formulas:

Where both numerators refer to the substance whose specific gravity is being calculated, the denominators refer to the reference substance, in this case water (w refers to water) at a temperature of 4°C and 1 atm depression. As before, ρ indicates density, while γ represents specific weight.

As you can see, both properties are calculated by means of very different formulas.

Difference 3: They are measured on different types of scales

Density is an absolute magnitude. That is, the determination and calculation of the density are not made in relation to a reference point. We can measure the density of a substance directly by determining its mass and volume and then using the formula mentioned above.

Instead, specific gravity is a relative quantity. This means that the specific gravity values ​​of a substance alone are of no use to us if we do not know the reference material or substance.

For example, if we say that the specific gravity of a material is 1.53, we cannot come to any conclusion about the density or specific gravity of the substance until we know what the reference substance is. The number alone tells us that the density of our substance is 1.53 times greater than the density of the reference substance, and we could also conclude that our substance would surely sink into the reference substance (ie, not float). However, we would still have no idea how dense or heavy the material actually is.

It could be a gas 1.53 times denser than air, or it could be a substance 1.53 times denser than water, representing two very different scenarios.

Difference 4: They do not have the same units

The units of density are units of mass over units of volume ([ρ] = [m]/[V] or [m].[V] ^–1 ). Some common units for density are:

• kg/m ³ or kg.m ^–3
• g/cm ³ or g.cm ^–3
• g/mL or g.mL ^–1
• g/L or gL ^–1

On the other hand, the fact that the relative density or specific gravity is a relationship between two densities or between two specific weights causes the units of the numerator and denominator to cancel. Therefore, specific gravity is a dimensionless quantity (that is, it has no units).

Difference 5: Measurement

Density is determined experimentally indirectly by determining the mass of a substance or material and then measuring or calculating its volume, to finally apply the density formula. To obtain very accurate measurements of the density of liquids, a pycnometer is usually used.

Instead, specific gravity can be measured directly by means of a suitably calibrated hydrometer or digital specific gravity balance.

Summary of Differences Between Density and Specific Gravity

The following table summarizes the four differences between density and specific gravity explained in the previous sections:

References

Bowles, J.E. (2000). SPECIFIC GRAVITY OF SOILS (PYCNOMETER) . National University of Engineering. http://www.lms.uni.edu.pe/labsuelos/MODOS%20OPERATIVOS/Determinacion%20de%20la%20gravedad%20especifica.pdf

González, A. (2021, June 2). Specific Gravity . lifer. https://www.lifeder.com/specific-gravity/

Mettler-Toledo International Inc. (2021, October 28). What is density? https://www.mt.com/mx/es/home/applications/Application_Browse_Laboratory_Analytics/Density/density-measurement.html

Ruff, B., MA. (2019, November 28). How to measure the specific gravity of liquids . wikiHow. https://es.wikihow.com/medir-la-gravedad-espec%C3%ADfica-de-los-l%C3%ADquidos