# Nakafa Learning Content > For AI agents: use [llms.txt](https://nakafa.com/llms.txt) for the site index. Markdown versions are available by appending `.md` to content URLs or sending `Accept: text/markdown`. URL: https://nakafa.com/en/subjects/chemistry/structure-matter/isotope Source: https://raw.githubusercontent.com/nakafaai/nakafa.com/refs/heads/main/packages/contents/material/lesson/chemistry/structure-matter/isotope/en.mdx Learn isotopes as atoms of the same element with the same number of protons, but different numbers of neutrons and mass numbers. --- ## Same Element, Different Mass Hydrogen in the Sun, carbon in our bodies, and oxygen in water do not always appear as only one mass version. One element can have several atoms with the same number of protons but different numbers of neutrons. Those atoms are called **isotopes**. The Atomic Structure and Symbolism section from OpenStax explains that isotopes are atoms of the same element with the same atomic number but different mass numbers. The source can be opened through [OpenStax's Atomic Structure and Symbolism](https://openstax.org/books/chemistry-atoms-first-2e/pages/2-3-atomic-structure-and-symbolism). The IUPAC Gold Book emphasizes the same idea: isotopes have the same atomic number but different mass numbers. The term reference can be opened through [IUPAC Gold Book's isotope entry](https://goldbook.iupac.org/terms/view/I03331). Read the pattern like this: ```math \text{isotopes} \Rightarrow Z\ \text{same},\ n^0\ \text{different},\ A\ \text{different} ``` The symbol $$Z$$ is the atomic number, which equals the number of protons. The symbol $$A$$ is the mass number, which equals protons plus neutrons. If $$Z$$ is the same, the element is the same. If $$n^0$$ is different, the mass number also changes. Visible text: The symbol is the atomic number, which equals the number of protons. The symbol is the mass number, which equals protons plus neutrons. If is the same, the element is the same. If is different, the mass number also changes. So isotopes are mass versions of the same element, not new elements. The key stays the proton count. Neutrons only change the mass number. ## Isotope Mini Lab Choose an isotope below. First notice what does not change: the number of protons. Then compare the neutron count. Component: IsotopeLab Props: - title: Isotope Reader - description: Compare hydrogen and carbon isotopes. The element stays the same when the atomic number stays the same, but the mass number changes when neutrons change. - labels: { chooseIsotope: "Choose an isotope example", atomicNumber: "Atomic number", massNumber: "Mass number", protons: "Protons", neutrons: "Neutrons", electrons: "Neutral electrons", abundance: "Natural abundance", samples: { "hydrogen-1": { tab: $${}^{1}\mathrm{H}$$, ariaName: "Hydrogen-1", name: $${}^{1}_{1}\mathrm{H}$$, abundance: <>About $$99.9885\%$$, note: <>Has no neutrons., }, deuterium: { tab: $${}^{2}\mathrm{H}$$, ariaName: "Deuterium, H-2", name: <>Deuterium $${}^{2}_{1}\mathrm{H}$$, abundance: <>About $$0.0115\%$$, note: <>Has $$1$$ neutron., }, tritium: { tab: $${}^{3}\mathrm{H}$$, ariaName: "Tritium, H-3", name: <>Tritium $${}^{3}_{1}\mathrm{H}$$, abundance: <>Extremely small in nature, note: <>Has $$2$$ neutrons., }, "carbon-12": { tab: $${}^{12}\mathrm{C}$$, ariaName: "Carbon-12", name: $${}^{12}_{6}\mathrm{C}$$, abundance: <>About $$98.93\%$$, note: <>Has $$6$$ neutrons., }, "carbon-13": { tab: $${}^{13}\mathrm{C}$$, ariaName: "Carbon-13", name: $${}^{13}_{6}\mathrm{C}$$, abundance: <>About $$1.07\%$$, note: <>Has $$7$$ neutrons., }, "carbon-14": { tab: $${}^{14}\mathrm{C}$$, ariaName: "Carbon-14", name: $${}^{14}_{6}\mathrm{C}$$, abu ... [truncated; 1285 chars] Visible text: { chooseIsotope: "Choose an isotope example", atomicNumber: "Atomic number", massNumber: "Mass number", protons: "Protons", neutrons: "Neutrons", electrons: "Neutral electrons", abundance: "Natural abundance", samples: { "hydrogen-1": { tab: , ariaName: "Hydrogen-1", name: , abundance: <>About , note: <>Has no neutrons., }, deuterium: { tab: , ariaName: "Deuterium, H-2", name: <>Deuterium , abundance: <>About , note: <>Has neutron., }, tritium: { tab: , ariaName: "Tritium, H-3", name: <>Tritium , abundance: <>Extremely small in nature, note: <>Has neutrons., }, "carbon-12": { tab: , ariaName: "Carbon-12", name: , abundance: <>About , note: <>Has neutrons., }, "carbon-13": { tab: , ariaName: "Carbon-13", name: , abundance: <>About , note: <>Has neutrons., }, "carbon-14": { tab: , ariaName: "Carbon-14", name: , abu ... [truncated; 1285 chars] ## Hydrogen Has Three Important Examples All hydrogen isotopes have $$1$$ proton. Because their proton count is $$1$$, they are still hydrogen. The difference is their neutron count. Visible text: All hydrogen isotopes have proton. Because their proton count is , they are still hydrogen. The difference is their neutron count. | Hydrogen isotope | Symbol | Protons | Neutral electrons | Neutrons | | :--------------- | :----- | :------ | :---------------- | :------- | | Light hydrogen | $${}^{1}_{1}\mathrm{H}$$ | $$1$$ | $$1$$ | $$0$$ | | Deuterium | $${}^{2}_{1}\mathrm{H}$$ | $$1$$ | $$1$$ | $$1$$ | | Tritium | $${}^{3}_{1}\mathrm{H}$$ | $$1$$ | $$1$$ | $$2$$ | Visible text: | Hydrogen isotope | Symbol | Protons | Neutral electrons | Neutrons | | :--------------- | :----- | :------ | :---------------- | :------- | | Light hydrogen | | | | | | Deuterium | | | | | | Tritium | | | | | Deuterium is sometimes written as $$\mathrm{D}$$, and tritium is sometimes written as $$\mathrm{T}$$. Those shortcuts do not mean new elements. Deuterium and tritium are still hydrogen because their proton count is still $$1$$. Visible text: Deuterium is sometimes written as , and tritium is sometimes written as . Those shortcuts do not mean new elements. Deuterium and tritium are still hydrogen because their proton count is still . ## Carbon Shows the Role of Neutrons Carbon always has $$6$$ protons. In $${}^{12}_{6}\mathrm{C}$$, $${}^{13}_{6}\mathrm{C}$$, and $${}^{14}_{6}\mathrm{C}$$, the neutron count increases. Visible text: Carbon always has protons. In , , and , the neutron count increases. ```math \begin{aligned} {}^{12}_{6}\mathrm{C} &: n^0 = 12 - 6 = 6 \\ {}^{13}_{6}\mathrm{C} &: n^0 = 13 - 6 = 7 \\ {}^{14}_{6}\mathrm{C} &: n^0 = 14 - 6 = 8 \end{aligned} ``` $${}^{12}_{6}\mathrm{C}$$ and $${}^{13}_{6}\mathrm{C}$$ are stable. $${}^{14}_{6}\mathrm{C}$$ is radioactive, so its amount in nature is extremely small. Because $${}^{14}_{6}\mathrm{C}$$ decays over time, scientists can use it to estimate the age of objects that once came from living things, such as old wood or bone. Visible text: and are stable. is radioactive, so its amount in nature is extremely small. Because decays over time, scientists can use it to estimate the age of objects that once came from living things, such as old wood or bone. ## Do Not Mix It Up with Ions Ions and isotopes both change numbers in an atom, but the changing part is different. | Concept | What changes | What locks the element | | :------ | :----------- | :--------------------- | | Ion | Electrons | Protons | | Isotope | Neutrons | Protons | For example, $$\mathrm{C}^{2-}$$ is a carbon ion because its electrons changed. In contrast, $${}^{14}_{6}\mathrm{C}$$ is a carbon isotope because its neutron count is different from $${}^{12}_{6}\mathrm{C}$$. Visible text: For example, is a carbon ion because its electrons changed. In contrast, is a carbon isotope because its neutron count is different from . If the atom is neutral, electrons still equal protons: ```math \text{neutral atom} \Rightarrow e^- = p^+ ``` So neutral $${}^{14}_{6}\mathrm{C}$$ has $$6$$ protons, $$6$$ electrons, and $$8$$ neutrons. Visible text: So neutral has protons, electrons, and neutrons. ## Uses of Isotopes Isotopes do not only differ in tables. Different neutron counts can make some isotopes useful for research, energy, or age estimation. Deuterium and tritium, two hydrogen isotopes, are widely discussed in nuclear fusion research. The Department of Energy explains deuterium-tritium fuel as an important isotope pair in fusion energy development. The reference can be opened through [DOE's Deuterium-Tritium Fusion Fuel](https://www.energy.gov/science/doe-explainsdeuterium-tritium-fusion-fuel). $${}^{14}_{6}\mathrm{C}$$ is used in radiocarbon dating to estimate the age of organic materials, meaning materials that once came from living things. The University of Chicago explains that $${}^{14}_{6}\mathrm{C}$$ dating can determine the age of organic materials up to about $$60\,000$$ years. The reference can be opened through [the University of Chicago explainer](https://news.uchicago.edu/explainer/what-is-carbon-14-dating). Visible text: is used in radiocarbon dating to estimate the age of organic materials, meaning materials that once came from living things. The University of Chicago explains that dating can determine the age of organic materials up to about years. The reference can be opened through [the University of Chicago explainer](https://news.uchicago.edu/explainer/what-is-carbon-14-dating). The important note is that isotope uses must be read together with stability, meaning whether the nucleus tends to decay. Radioactive isotopes such as tritium and $${}^{14}_{6}\mathrm{C}$$ are not materials for casual experiments, so their use requires safety rules. Visible text: The important note is that isotope uses must be read together with stability, meaning whether the nucleus tends to decay. Radioactive isotopes such as tritium and are not materials for casual experiments, so their use requires safety rules. ## From Isotopes to Average Atomic Mass On the periodic table, relative atomic mass is often a decimal. That number is not the mass number of one isotope. It is a weighted average of the isotopes found in nature. NIST explains that an element's relative atomic mass is calculated from isotope masses and isotopic composition. The column notes can be opened through [NIST's Atomic Weights and Isotopic Compositions](https://www.nist.gov/pml/atomic-weights-and-isotopic-compositions-column-descriptions). Carbon is an easy example: | Carbon isotope | Mass number | Natural abundance | | :------------- | :---------- | :---------------- | | $${}^{12}_{6}\mathrm{C}$$ | $$12$$ | About $$98.93\%$$ | | $${}^{13}_{6}\mathrm{C}$$ | $$13$$ | About $$1.07\%$$ | | $${}^{14}_{6}\mathrm{C}$$ | $$14$$ | Extremely small | Visible text: | Carbon isotope | Mass number | Natural abundance | | :------------- | :---------- | :---------------- | | | | About | | | | About | | | | Extremely small | Because $${}^{12}_{6}\mathrm{C}$$ is the most abundant carbon isotope, carbon's relative atomic mass on the periodic table is close to $$12$$, but not exactly $$12$$. Visible text: Because is the most abundant carbon isotope, carbon's relative atomic mass on the periodic table is close to , but not exactly . ## Distinguishing Isotopes by Atomic and Mass Numbers Use these three questions whenever you read an isotope: - How many protons are there? - What is the mass number? - How many neutrons come from $$A - Z$$? Visible text: - How many protons are there? - What is the mass number? - How many neutrons come from ? For $${}^{92}_{40}\mathrm{Zr}$$: Visible text: For : ```math \begin{aligned} n^0 &= A - Z \\ &= 92 - 40 \\ &= 52 \end{aligned} ``` So $${}^{92}_{40}\mathrm{Zr}$$ has $$52$$ neutrons. This method is safer than memorizing tables because you can calculate any isotope when the atomic number and mass number are known. Visible text: So has neutrons. This method is safer than memorizing tables because you can calculate any isotope when the atomic number and mass number are known.