Atoms & Elements

Introduction to Atoms and Elements

Atoms are the fundamental building blocks of matter, and elements are pure substances composed of only one type of atom. Understanding their structure and properties is essential for studying chemistry, especially in the context of the periodic table.

• Atom: The smallest unit of an element that retains the properties of that element.

• Element: A substance made up of only one kind of atom, defined by its atomic number (number of protons).

• Atomic Theory: All matter is composed of atoms, which are indivisible in chemical processes.

Classification of Elements

Metals, Nonmetals, and Metalloids

The periodic table organizes elements based on their properties. Elements are broadly classified as metals, nonmetals, or metalloids, separated by a bold stair-step line on the table.

• Metals: Located on the left side of the stair-step line.

• Nonmetals: Located on the right side of the stair-step line.

• Metalloids (Semimetals): Found along the stair-step line and display mixed properties.

Properties of Metals

• Lose electrons to form cations (positively charged ions).

• Conduct heat and electricity efficiently.

• Malleable: Can be hammered into thin sheets.

• Ductile: Can be drawn into wires.

• Shiny (lustrous) appearance.

Examples: Iron, tin, copper, gold.

Properties of Nonmetals

• Gain electrons to form anions (negatively charged ions).

• Poor conductors of heat and electricity (insulators).

• Brittle (break easily).

• Non-ductile and dull in appearance.

Examples: Phosphorus, chlorine, sulfur, carbon.

Properties of Metalloids

• Display mixed properties of both metals and nonmetals.

• Often semiconductors (important in electronics).

The Periodic Table

Structure and Organization

The periodic table arranges elements in rows and columns based on increasing atomic number and recurring chemical properties.

• Periods (Rows): Horizontal rows numbered from 1 to 7.

• Groups (Columns or Families): Vertical columns numbered from 1 to 18. Elements in the same group often display similar properties.

• Lanthanides: Row 6 (elements 57-71).

• Actinides: Row 7 (elements 89-103).

Group Names to Memorize

Note: Hydrogen (H) is not an alkali metal or halogen; it belongs to no family.

Chemical Groups (Families)

Elements in the same group (vertical column) often display similar reactivity and chemical properties due to having the same number of valence electrons.

• Example: Alkali metals (Group 1) react vigorously with water.

Atomic Structure

Dalton's Atomic Theory (Summary)

• All matter is made of indivisible atoms.

• All atoms of a given element are identical in mass and properties.

• Atoms of different elements have different masses and properties.

• Compounds are formed by the combination of atoms of different elements.

Additional info: Modern atomic theory has modified some of Dalton's postulates, recognizing the existence of subatomic particles and isotopes.

Subatomic Particles

• Proton (p+): Positively charged particle in the nucleus; defines the atomic number.

• Neutron (n0): Neutral particle in the nucleus; contributes to atomic mass.

• Electron (e-): Negatively charged particle in orbitals around the nucleus.

Nuclear Model of the Atom

The nuclear model describes the atom as having a small, dense nucleus containing protons and neutrons, surrounded by electrons in mostly empty space.

Isotopes

Isotopes are atoms of the same element (same number of protons) but with different numbers of neutrons, resulting in different mass numbers.

• Isotope Notation: AZX, where X is the element symbol, A is the mass number (protons + neutrons), and Z is the atomic number (protons).

• Example: Neon has three isotopes: 20Ne, 21Ne, 22Ne.

Calculating Subatomic Particles

• Number of protons: Equal to the atomic number (Z).

• Number of neutrons:

• Number of electrons: For a neutral atom, equal to the number of protons.

Valence Electrons and Electron Dot Symbols

Valence Electrons

Valence electrons are the outermost electrons of an atom and determine its chemical reactivity.

• For main group elements, the group number indicates the number of valence electrons (e.g., Group 1 = 1 valence electron).

• For groups numbered above 12, use the last digit to determine valence electrons (e.g., Group 14 = 4 valence electrons).

Electron Dot Symbols (Lewis Dot Structures)

• Represent valence electrons as dots around the element symbol.

• No more than two dots per side; placement of dots is flexible.

• Helps visualize bonding and reactivity.

Periodic Trends

Atomic Size (Atomic Radius)

The atomic radius is the average distance from the nucleus to the outermost electron. It varies predictably across the periodic table.

• Increases down a group (column).

• Decreases across a period (row) from left to right.

Ionization Energy (IE)

Ionization energy is the energy required to remove an electron from a gaseous atom.

• Increases up a group and across a period from left to right.

• Decreases down a group.

Metallic Character

Metallic character refers to how readily an atom can lose electrons to form positive ions (cations).

• Increases down a group.

• Decreases across a period from left to right.

Summary Table: Periodic Trends

Key Formulas and Notations

• Mass Number:

• Number of Neutrons:

• Isotope Notation:

Additional info: These foundational concepts are essential for understanding chemical bonding, reactions, and the behavior of elements in various contexts.