Why don't any of the isotopes of natural iron have the atomic mass of 55.85 amu, if the number listed in the periodic table is 55.85 amu?

Answer 1

Since atomic mass is the average of the isotopic masses, you shouldn't expect the atomic mass on the periodic table to match the exact isotopic masses unless there is an extremely significant abundance of one particular isotope (e.g. nearly #100%#).


For iron, the following isotopes exist, with these #%# #"Abundances"#, as well as their isotopic masses #M_I#:

  • #""^54 "Fe"#, #5.845%#, #M_(I,1) = 53.9396105_7#
  • #""^56 "Fe"#, #91.754%#, #M_(I,2) = 55.9349375_7#
  • #""^57 "Fe"#, #2.119%#, #M_(I,3) = 56.9353940_7#
  • #""^58 "Fe"#, #0.282%#, #M_(I,4) = 57.9332756_8#

Note: the subscripted digit is the last uncertain digit.

From this we can find the atomic mass listed on the periodic table by using the percent found in nature of each isotope to calculate a weighted average based on all major isotopes.

You can think of the #%# #"Abundance"# as the weight, or the relative importance.

So, the relative atomic mass #M_r#, which is what is listed on the periodic table, can be determined as follows:

#color(blue)(M_r)#

#= sum_(i)^(N) [M_(I,i)xx%"Abundance"_(i)]#

#= M_(I,1)xx%"Abundance"_1 + M_(I,2)xx%"Abundance"_2 + . . . #

#= 53.9396105_7xx0.05845 + 55.9349375_7xx0.91754 + 56.9353940_7xx0.02119 + 57.9332756_8xx0.00282#

#= 55.8451456935552#

#~~ color(blue)(55.85)# if rounded to four sig figs, but I would use #55.845# since we know the isotopic masses to so many sig figs.

And you can see on the periodic table that we indeed have #M_r = 55.845# for iron (#Z = 26#):

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Answer 2

Natural iron isotope masses vary, and the average atomic mass is approximately, but not quite, 55.85 amu because of the contribution of various isotopes with varying abundances. The atomic mass listed on the periodic table for natural iron is a weighted average of the masses of its isotopes, taking into account their abundance.

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Answer from HIX Tutor

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

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