# 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/subatomic-particles-properties Source: https://raw.githubusercontent.com/nakafaai/nakafa.com/refs/heads/main/packages/contents/material/lesson/chemistry/structure-matter/subatomic-particles-properties/en.mdx Learn the charge, mass, and location of protons, neutrons, and electrons so atomic symbols become easier to read. --- ## Three Properties to Read We already know the three particles that make up atoms: **protons**, **neutrons**, and **electrons**. Now the focus is not “who discovered them,” but **which properties make them different**. Three properties matter most for reading simple atoms: - **charge**, the electric sign of the particle - **mass**, how much the particle contributes to atomic mass - **location**, the part of the atom where the particle is usually discussed The Atomic Structure and Symbolism section from OpenStax gives a table of subatomic particle charge, mass, and location. The source table can be opened through [OpenStax's Properties of Subatomic Particles](https://openstax.org/books/chemistry-atoms-first-2e/pages/2-3-atomic-structure-and-symbolism). For more precise constants, NIST publishes CODATA recommended values. The summary can be opened through [NIST's CODATA 2022 wall chart](https://physics.nist.gov/cuu/pdf/wall_2022.pdf). ## Particle Property Mini Lab Switch the mode below. First watch the big pattern: direction of bending, mass comparison height, and particle location inside the atom. Component: SubatomicParticlePropertiesLab Props: - title: Subatomic Particle Property Map - description: One visual for reading the charge, mass, and location of protons, neutrons, and electrons. - labels: { chooseMode: "Choose a subatomic particle property", scene: { electron: "Electron", electronRegion: "Electron region", negativePlate: "Negative plate", neutron: "Neutron", nucleus: "Nucleus", positivePlate: "Positive plate", proton: "Proton", }, modes: { charge: { tab: "Charge", summary: ( <> Protons are positive, electrons are negative, and neutrons are neutral. In an electric field, charge sign controls the bending direction. ), facts: [ { label: "Proton", value: "+1", math: true }, { label: "Neutron", value: "0", math: true }, { label: "Electron", value: "-1", math: true }, ], }, mass: { tab: "Mass", summary: ( <> Protons and neutrons have almost the same mass. The electron bar is enlarged because electrons are much lighter. ), facts: [ { label: "Proton", value: "1.0073\\ \\text{u}", math: true }, { label: "Neutron", value: "1.0087\\ \\text{u}", math: true }, { label: "Electron", value: "0.00055\\ \\text{u}", math: true }, ], }, location: { tab: "Location", summary: ( <> Protons and neutrons are in the nucleus. Electrons occupy the space around the nucleus, not fixed railway-like paths. ), facts: [ { label: "Nucleus", value: "p^+ + n^0", math: true }, { label: "Outs ... [truncated; 1311 chars] ## Charge Decides the Direction of Bending Electric charge can be read as a particle's “interaction sign.” A proton is positive, an electron is negative, and a neutron has no total charge. The proton and electron have the same charge magnitude, but opposite signs: ```math e = 1.602176634 \times 10^{-19}\ \text{C} ``` That means: - a proton has charge $$+e$$ - an electron has charge $$-e$$ - a neutron has charge $$0$$ Visible text: - a proton has charge - an electron has charge - a neutron has charge In an electric field, a charged particle feels a force. The short way to read it is: ```math F = qE ``` The symbol $$q$$ is the particle charge, and $$E$$ is the electric field. If $$q$$ is positive, the force points with the field. If $$q$$ is negative, the force points the opposite way. If $$q = 0$$, the particle is not bent by a simple electric field. Visible text: The symbol is the particle charge, and is the electric field. If is positive, the force points with the field. If is negative, the force points the opposite way. If , the particle is not bent by a simple electric field. An electric field can be pictured like wind that only charged objects feel. Protons and electrons both feel the push, but in opposite directions. A neutron is neutral, so in this simple model it goes straight. ## Mass Changes How Strongly Motion Changes Subatomic particle masses are tiny, so we often use the **unified atomic mass unit**, written $$\text{u}$$. It is defined from the mass of a $${}^{12}_{6}\mathrm{C}$$ atom. Visible text: Subatomic particle masses are tiny, so we often use the **unified atomic mass unit**, written . It is defined from the mass of a atom. | Particle | Relative charge | Relative mass | Absolute mass | Main location | | :------- | :-------------- | :------------ | :------------ | :------------ | | Proton | $$+1$$ | $$1.0073\ \text{u}$$ | $$1.67262 \times 10^{-24}\ \text{g}$$ | Nucleus | | Neutron | $$0$$ | $$1.0087\ \text{u}$$ | $$1.67493 \times 10^{-24}\ \text{g}$$ | Nucleus | | Electron | $$-1$$ | $$0.00055\ \text{u}$$ | $$9.10939 \times 10^{-28}\ \text{g}$$ | Space around the nucleus | Visible text: | Particle | Relative charge | Relative mass | Absolute mass | Main location | | :------- | :-------------- | :------------ | :------------ | :------------ | | Proton | | | | Nucleus | | Neutron | | | | Nucleus | | Electron | | | | Space around the nucleus | The table shows two important ideas. First, protons and neutrons are almost equally heavy. Second, electrons are extremely light compared with protons and neutrons. A simple comparison is: ```math \frac{m_p}{m_e} \approx 1836 ``` So one proton has about the same mass as $$1836$$ electrons. That is why almost all atomic mass comes from the nucleus, not from the electrons. Visible text: So one proton has about the same mass as electrons. That is why almost all atomic mass comes from the nucleus, not from the electrons. If two objects receive the same push, a tennis ball changes motion more easily than a bowling ball. This is only a mass comparison, not the shape of a particle. In an atom, an electron is much lighter, so a force can change its motion much more than it changes a proton's motion. ## Location Gives Each Particle Its Role Particle location gives each particle a different role. | Particle | Location | Common role in chemistry | | :------- | :------- | :----------------------- | | Proton | Nucleus | Determines element identity. | | Neutron | Nucleus | Adds mass and distinguishes isotopes. | | Electron | Space around the nucleus | Strongly affects reactions and ion formation. | The number of protons determines the element. For example, an atom with $$6$$ protons is carbon. If the neutron number changes, the element is still carbon, but the isotope is different. If the electron number changes, the atom becomes an ion. Visible text: The number of protons determines the element. For example, an atom with protons is carbon. If the neutron number changes, the element is still carbon, but the isotope is different. If the electron number changes, the atom becomes an ion. For a neutral atom, the number of protons and electrons is the same: ```math \text{neutral atom} \Rightarrow p^+ = e^- ``` That sentence does not mean protons and electrons have the same mass. It means the total positive and negative charges balance. ## Ready for Atomic Symbols Atomic symbols use three important pieces of information. On [Atomic Symbols](/en/subjects/chemistry/structure-matter/atom-symbol), that information is written around the element symbol. Subatomic particle properties tell us how to read it: - the number of protons is read as the **atomic number** - the number of protons plus neutrons is read as the **mass number** - the difference between protons and electrons is read as the **ion charge** So do not memorize the table as disconnected numbers. Read the main relationship: **protons give identity**, **neutrons add mass**, and **electrons control the atom's outer charge**.