1. Classification of Matter
Matter is anything that has volume and mass.
All matter is made of substances called elements.
An element is a substance that cannot be broken down into simpler substances by physical or chemical means.
Elements are made up of atoms.

2. Atoms
All atoms consist of even smaller particles—protons, neutrons, and electrons.
The center of an atom is called the nucleus, which is made up of protons and neutrons.
A proton is a tiny particle that has mass and a positive electric charge.
A neutron is a tiny particle with approximately the same mass as a proton, but it has no electrical charge
Surrounding the nucleus of an atom are electrons, smaller particles that are in constant motion.
An electron has little mass, but it has a negative electric charge that is exactly the same magnitude as the positive charge of a proton.

3. In this representation of an atom, the fuzzy area surrounding the nucleus is referred to as an electron cloud.

4. Periodic Table
The periodic table of the elements is arranged so that a great deal of information about all of the known elements is provided in a small space.

6. Periodic Table Symbols
Generally, each element is identified by a one-, two-, or three-letter abbreviation known as a chemical symbol.
All elements are classified and arranged according to their chemical properties in the periodic table of the elements.

7. Mass Number
The number of protons in an atom’s nucleus is its atomic number.
The sum of the protons and the neutrons in an atom’s nucleus is its mass number.
This diagram of the element chlorine explains how atomic numbers and atomic mass are listed in the periodic table of the elements.

8. Isotopes
All atoms of an element have the same number of protons. However, the number of neutrons of an element’s atoms can vary.
Atoms of the same element that have different mass numbers are called isotopes.
The atomic mass of an element is the average of the mass numbers of the isotopes of an element.

9. Radioactive Isotopes
Radioactive decay is the spontaneous process through which unstable nuclei emit radiation.
In the process of radioactive decay, a nucleus can lose protons and neutrons, change a proton to a neutron, or change a neutron to a proton.
Because the number of protons in a nucleus identifies an element, decay can change the identity of an element.

10. Ions
An atom that gains or loses one or more electrons from its outermost energy level has a net electric charge and is called an ion.
Positive ions – atoms that lose electrons
Negative ions – atoms that gain electrons

11. What elements are most abundant?
The two most abundant elements in the universe are hydrogen and helium. However, the two most abundant elements in Earth’s crust are oxygen and silicon.

12. Compounds
A compound is a substance that is composed of atoms of two or more different elements that are chemically combined. Compounds have different properties from the elements of which they are composed. Compounds are represented by chemical formulas that include the symbol for each element followed by a subscript number showing the number of atoms of that element in the compound. (ex. MgCl2)

13. Making Compounds
A state of stability is achieved by some elements by forming chemical bonds. A chemical bond is the force that holds together the elements in a compound.
Three types of bonds
covalent – share electrons
ionic – transfer electrons
metallic – sea of electrons

14. Chemical Reactions
The change of one or more compounds into other compounds is called a chemical reaction.
Chemical reactions are described by chemical equations.
Example
Water is formed by the chemical reaction between hydrogen gas (H2) and oxygen gas (O2).

15. Mixtures and Solutions
A mixture is a combination of two or more components that retain their identities. When a mixture’s components are easily recognizable, it is called a heterogeneous mixture. In a homogeneous mixture, also called a solution, the component particles cannot be distinguished, even though they still retain their original properties. A solution can be liquid, gaseous, or solid

16. States of Matter: Solids
Solids are substances with densely packed particles, which can be ions, atoms, or molecules.
Most solids are crystalline structures because the particles of a solid are arranged in regular geometric patterns, giving solids definite shape and volume.

17. States of Matter: Liquids
An increase in temperature increases the thermal vibrations of atoms in a solid.
When thermal vibrations become vigorous enough to break the forces holding the solid together, the particles can slide past each other, and the substance becomes liquid.
Liquids take the shape of the container they are placed in, but they do have a definite volume.

18. States of Matter: Gases
Some vibrating particles can gain sufficient thermal energy to escape a liquid.
This process of change from a liquid to a gas at temperatures below the boiling point is called evaporation.
Gases, like liquids, have no definite shape. Gases also have no definite volume unless they are restrained by a container or a force such as gravity.

19. Changes of State

20. Conservation of Energy
The fundamental fact that matter cannot be created or destroyed is called the law of conservation of matter.
Like matter, energy cannot be created or destroyed, but it can be changed from one form to another.
This law, called the conservation of energy, is also known as the first law of thermodynamics.