Calculate Mass

Mass means how much matter there is in something. Matter is something you can physically touch. Generally, mass is related to size but not always. A balloon might be bigger than something else but have less mass, for example. There are ways you can measure mass.

Steps

Finding Mass from Density and Volume

  1. Look up the object's density. Density measures how tightly the matter in an object is packed together. Each material has its own density, which you can look up online or in a textbook. The scientific unit of density is kilograms per cubic meter (kg/m3), but you can use grams per cubic centimeter (g/cm3) for smaller objects.
    • Use this formula to convert between these units: 1,000 kg/m3 = 1 g/cm3
    • The density of liquids is often measured in kilograms per liter (kg/L) or grams per milliliter (g/mL) instead. These units are equivalent: 1 kg/L = 1 g/mL.
    • Example: Diamond has a density of 3.52 g/cm3.
  2. Calculate-Volume. The volume is the amount of space the object occupies. Measure the volume of solids in cubic meters (m3) or cubic centimeters (cm3), and the volume of liquids in liters (L) or milliliters (mL). The formula for volume depends on the shape of the object. Refer to Calculate-Volume for common shapes.
    • Use the same unit that appears as part of your density measurement.
    • Example: Since we measured the density of diamond in g/cm3, we should measure our diamond's volume in cm3. Let's say our diamond's volume is 5,000 cm3.
  3. Multiply the volume and density together. Multiply your two numbers together, and you'll know the mass of your object.[1] Keep track of the units as you do this, and you'll see that you end up with units of mass (kilograms or grams).
    • Example: We have a diamond with volume 5,000 cm3 and density 3.52 g/cm3. To find the diamond's mass, multiply 5,000 cm3 x 3.52 g/cm3 = 17,600 grams.

Solving for Mass in Other Science Problems

  1. Determine mass with force and acceleration. Newton's second law of motion states that force equals mass times acceleration: F = ma. If you know the net force on the object, and it's acceleration, you can rearrange this formula to find the mass: m = F / a.
    • Force is measured in N (newton), which you can also write as (kg * m)/ s2. Acceleration is measured in m/s2. When you calculate F / a, the units cancel to give you an answer in kilograms (kg).[2]
  2. Understand mass and weight. Mass is the amount of matter in an object; this does not change unless you cut off part of the object, or attach more material. Weight is a measurement of gravity's effect on mass. If you move the object to an area with different gravity (such as from the earth to the moon), it's weight will change, but it's mass will not.[3][4]
    • An object with more mass does weigh more than an object with less mass, if they're experiencing the same gravity.
  3. Calculate molar mass. If you're doing your chemistry homework, you may come across the term "molar mass." This is a related concept, but instead of measuring an object, you measure exactly one mole of a substance. Here's how to calculate it in most contexts:[5]
    • For an element: look up the atomic mass of the element or compound you are measuring. This will be in "atomic mass units" (amu). Multiply by the molar mass constant, 1 g/mol, to put it into standard molar mass units: g/mol.
    • For a compound: add the atomic masses of each atom in the compound to find the total amu of the molecule. Multiply this total by 1 g/mol.

Measuring Mass with a Balance

  1. Use a triple-beam balance. The balance is a device widely used to calculate an object's mass. The balance has three beams. These beams carry weights. [6] The weights allow you to move known masses along the beams.[7]
    • The triple beam balance is not affected by gravity. Thus, it gives a true measurement of mass. It works by comparing a known mass to an unknown mass.
    • The middle beam reads in 100g increments. The far beam reads in 10g increments. The weights will sit in a notch. The weight on the front beam can read from 0 to 10 grams.
    • You should be able to get a very precise measurement of mass with this balance. The reading error for a triple-beam balance is only 0.06 grams. Think of the triple-beam balance as operating like a teeter-totter.[8]
  2. Move the three sliders to their leftmost positions. You want to do this maneuver when the pan is empty. You want the balance to read zero.
    • If the indicator on the far right does not align with the fixed mark, you should calibrate the balance by turning the set screw that you will find on the left under the pan.
    • The reason you need to do this is because you need to make sure that the empty pan is 0.000g so its weight does not skew the mass reading you ultimately get. The weight of the container or pan is called its tare.
    • You can also set the pan to 0 by screwing the knob under the pan in or out. Again, the balance must read zero. Place the object to be measured on the pan. You are now ready to determine the object’s mass using the sliding beams.
  3. Move the sliding beams one at a time. First, move the 100-gram slider along the beam to the right first. Do this until the indicator drops below the fixed mark. The position that is to the left of this point indicates the number of hundreds of grams. You are sliding it one notch at a time.
    • Move the 10-gram slider along the beam to the right. Do this until the indicator drops below the fixed mark. The notched position immediately to the left of this point indicates the number of tens of grams.
    • The beam in the front does not have notches. You can move the slider anywhere you want on the beam. The beam’s boldface numbers are grams. The tick marks between the boldface numbers indicate tenths of grams.
  4. Calculate the mass. You are now ready to find the mass of the object you placed in the pan. To do so, you should add the numbers from the three beams.
    • Read the front scale as you would a ruler. You can read it to the nearest half tick mark.
    • For example, let's say you are trying to measure a can of soda. If the rear weight is in the notch that reads 70g, if the middle weight is in the notch reading 300g, and if the the front beam weight is 3.34g, then the can of soda weighs 373.34g.

Tips

  • The symbol for mass is m or M.
  • You can use online calculators to find the mass if you know the volume and density.[9][10]

Warnings

  • Don't use pounds and ounces to measure mass; these are units of weight, and not used in scientific contexts. Technically, in the United States, the measurement of mass is called a “slug.”[10]



Sources and Citations

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