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Atoms and the Periodic Table Atomic Models Democritus (4th century B.C.) first theorized that matter was made of particles he called the atom Atomic Models Plum Pudding Model (1904) developed by J.J. Thomson Planetary Model developed by Ernest Rutherford (1911) Newer Models Bohr’s Model (1913) Developed by Niels Bohr Electron Cloud Model (1925) Protons (p+) Positively charged particles found in nucleus of atom Have an electrical charge of +1 Mass of 1 a.m.u. Composed of quarks Discovered by Ernest Rutherford using Gold Foil Experiment Protons The number of protons in an atom determines its identity All oxygen atoms have 8 protons, all uranium atoms have 92 protons If the number of protons change the identity of the atom changes. Neutrons (n0) Neutral particles found in nucleus of atom Have no electrical charge Mass of 1 a.m.u. Composed of quarks Discovered by James Chadwick Nucleus The nucleus is the positively charged dense core in the center of the atom Houses protons and neutrons Contains 99.9% of mass of atom Extremely small compared to the entire size of the atom Electrons (e-) Negatively charged particles found in electron cloud Have an electrical charge of -1 Constantly moving around outside nucleus Have essentially no mass Discovered by J.J. Thomson during cathode ray experiment Electrons The number of electrons in a neutral atom is equal to the number of protons Neutral oxygen has 8 protons, therefore it has 8 electrons Neutral lead has 82 protons, therefore, it has 82 electrons Valence Electrons Electrons in the outermost energy level of an atom are called valence electrons These are the electrons furthest from the nucleus Symbols Elements are identified by their chemical symbols Symbols are usually either one capital letter like C for Carbon, or one capital and one lowercase letter like Ne for Neon Atomic Number (Z) Whole number shown on periodic table Periodic table is arranged by atomic number Atomic Number = # of Protons *Also gives the number of electrons if the atom is neutral Atomic Number Mass Number (A) The mass number is the sum of the total number of protons and neutrons in the atom Mass # = # p+ + # n0 The mass number is not found on the Periodic Table Isotopes Isotopes are atoms of the same element that have different numbers of neutrons All atoms are isotopes Each element has isotopes that are more common than others Nuclear Symbol Isotopes can be designated with their nuclear symbol Hyphen Notation Isotopes can also be designated using hyphen notation Carbon-16 Element Name Mass Number Write the Nuclear Symbol and Hyphen Notation for the Following Isotopes Lithium isotope with 3 protons and 4 neutrons Sulfur isotope with 17 neutrons Lead with 122 neutrons Ions Ions are atoms or groups of atoms that have a net positive or negative charge The charge results from an unequal number of electrons and protons within an atom or group of atoms Ions Anions Ions with more electrons than protons resulting in a negative charge For each extra electron the negative charge increases by one Cations Ions with less electrons than protons resulting in a positive charge For each missing electron the positive charge increases by one Ions Ions are symbolized with a positive or negative sign on the upper right side and number equal to the magnitude of the charge The number one is not included O 2- Magnitude Charge Ions F 9 protons – 10 electrons = -1 charge Ca2+ 20 protons – 18 electrons = +2 charge P3- 15 protons – 18 electrons = -3 charge Common Ions (Need to memorize these) Column 1 (Li, Na, K, Rb, Cs): +1 Column 2 (Be, Mg, Ca, Sr, Ba): +2 Column 13 (Al, Ga): +3 Column 15 (N, P, As): -3 Column 16 (O, S, Se, Te): -2 Column 17 (F, Cl, Br, I): -1 Average Atomic Mass The weighted average of the naturally occurring isotopes of an element. Found by averaging the natural abundances of its isotopes Calculating Average Atomic Mass (amu) If abundance is given as percent value: (Mass of Isotope)(% abundance) Atomic Mass 100 If abundance is given as decimal value: Atomic Mass (Mass of Isotope)(a bundance) Average Atomic Mass Rubidium has two common isotopes, Rb-85 and Rb-87. If the abundance of 85Rb is 72.2% and the abundance of 87Rb is 27.8%, what is the average atomic mass of rubidium? [(85)(72.2)] [(87)( 27.8)] 85.5 86 amu 100 Uranium has three common isotopes. If the abundance of 234U is 0.0001, the abundance of 235U is 0.0071, and the abundance of 238U is .9928, what is the average atomic mass of uranium? [( 234 .0001) (235 .0071) (238 .9928)] 238.97 238 amu Columbic Attraction There exists an attraction between oppositely charged particles The greater the distance between the particles the weaker the attraction Columbic Attraction in the Atom The electrons in the atom are attracted to the protons Electrons closest to the nucleus feel a stronger attraction force than electrons on the outermost energy level As you move in a row from left to right on the Periodic Table the number of protons in an atom increases and so the attractive force on the outermost electrons increases Columbic Attraction in the Atom As you move down a column on the periodic table the distance between the outermost electrons and the nucleus is the dominant factor determining the attractive force Energy Levels and SubLevels Niels Bohr found that electrons occupy distinct energy levels within the atom. Ex: 1, 2, 3, 4 It was later found the electrons also occupy sublevels within each energy level. Ex: s, p, d, f Ground State Orbital Diagrams Represent the electrons within energy levels and sublevels using arrows Ground State Orbital Diagrams Pauli Exclusion Principle Each orbital can hold TWO electrons with opposite spins. Sub levels Each energy level has a different amount of sublevels 1s 2 s, p 3 s, p, d 4 s, p, d, f 5 s, p, d, f 6 s, p, d 7 s, p s has 1 orbital 2 e p has 3 orbitals 6 e d has 5 orbitals 10 e f has 7 orbitals 14 e- Ground State Orbital Diagrams Aufbau Principle Electrons fill the lowest energy level first. 1s, 2s, 2p, 3s, 3p, 4s, 3d, 4p, 5s, 4d, 5p, 6s, 4f, 5d, 6p, 7s, 5f, 6d, 7p Ground State Orbital Diagrams Hund’s Rule Within a sublevel, place one e- per orbital before pairing them. The last energy level being filled may not be completely filled with arrows WRONG RIGHT B. Notation Fluorine Germanium Ground State Electron Configuration An electron configuration is a shorthand description of how electrons are arranged around the nucleus of an atom. Electrons within each energy level and sub level are represented with numbers in super script rather than arrows Ground State Electron Configuration Longhand Configuration S 16e- 1s2 2s2 2p6 3s2 3p4 Core Electrons Valence Electrons Write the orbtial diagrams and electron configurations for the following: Carbon Sulfur Strontium Iron Valence Electrons Column 1 1 valence e Columns 2-12 2 valence e Column 13 3 valence e Column 14 4 valence e- Column 15 5 valence e Column 16 6 valence e Column 17 7 valence e Column 18 8 valence e- Lewis Symbols Also called electron dot diagrams Dots represent the valence e Ex: Sodium Ex: Chlorine Lewis Diagram for Oxygen Steps to Draw Lewis Structures Steps to Draw Lewis Symbols 1. Determine how many valence are in the element. 2. Starting on the Right side of the element draw a dot to represent a valence electron. 3. Place one dot on each side of the symbol. One electron must be drawn around each side of the element before a second electron can be added to any side.