The Atom, The History, and The Periodic Table (Chemical Naming and Formula Writing) Unit #3 Part I Chemistry
Theories Involving Matter and Atoms Democritus Greek 400 B.C. – Greeks: “all matter is composed of 4 fundamental substances” Earth, air (wind), water & fire Democritus: “matter is composed of small, indivisible parts,” (Greek – “atomos”) No experiments to test; no definitive conclusion First scientist to discover the idea of an atom
Alchemy (next 2000 years) Mixture of science and mysticism. Lab procedures were developed, but alchemists did not perform controlled experiments like true scientists.
Theories cont. Aristotle Greek Rejected the idea of atoms Expanded on idea of 4 elements Reasoning from logic & observation Also in line with religion
Theories cont. Lavoisier French chemist “Father of Modern Chemistry” Experimented and measured the masses of reactants and products of various reactions Law of Conservation of Matter
Theories cont. Proust French chemist Showed that a given compound always contains the same proportion of elements by mass Law of Definite Proportions
Theories cont. John Dalton (1803) English schoolteacher Thought about atoms as particles that might compose elements Billiard Ball Model atom is a uniform, solid sphere Elements combine in the ratio of small whole numbers Law of Multiple Proportions
John Dalton Dalton’s Four Postulates 1. Elements are composed of small indivisible particles called atoms. 2. Atoms of the same element are identical. Atoms of different elements are different. 3. Atoms of different elements combine together in simple proportions to create a compound. 4. In a chemical reaction, atoms are rearranged, but not changed.
Henri Becquerel (1896) Discovered radioactivity Three types: spontaneous emission of radiation from the nucleus Three types: alpha () - positive beta () - negative gamma () - neutral
J. J. Thomson (1903) Cathode Ray Tube Experiments Discovered Electrons beam of negative particles Discovered Electrons negative particles within the atom Plum-pudding Model
J. J. Thomson (1903) Plum-pudding Model positive sphere (pudding) with negative electrons (plums) dispersed throughout
Ernest Rutherford (1911) Gold Foil Experiment Discovered the nucleus dense, positive charge in the center of the atom Nuclear Model
Ernest Rutherford (1911) Nuclear Model dense, positive nucleus surrounded by negative electrons
Niels Bohr (1913) Bright-Line Spectrum Energy Levels Planetary Model tried to explain presence of specific colors in hydrogen’s spectrum Energy Levels electrons can only exist in specific energy states Planetary Model
Niels Bohr (1913) Bright-line spectrum Planetary Model electrons move in circular orbits within specific energy levels
Erwin Schrödinger (1926) Quantum mechanics Electron cloud model electrons can only exist in specified energy states Electron cloud model orbital: region around the nucleus where e- are likely to be found
Electron Cloud Model (orbital) Erwin Schrödinger (1926) Electron Cloud Model (orbital) dots represent probability of finding an e- not actual electrons
James Chadwick (1932) Discovered neutrons Joliot-Curie Experiments neutral particles in the nucleus of an atom Joliot-Curie Experiments based his theory on their experimental evidence
revision of Rutherford’s Nuclear Model James Chadwick (1932) Neutron Model revision of Rutherford’s Nuclear Model
Atoms Best current representation of the atom is a charged-cloud Smallest particle of an element that retains its properties Electrically neutral; # Protons = # electrons Parts of an atom Nucleus (contains both protons and neutrons) Electron Cloud (contains electrons)
Parts of an Atom Nucleus Small, dense center of positive charge. Protons Positively charged particles within the nucleus Neutrons Particles within the nucleus with no charge About the same mass as protons
Parts of an Atom cont. Electron Cloud Empty Space Holds electrons, which are densely packed Negatively charged particles found outside the nucleus Much smaller than protons and neutrons Proton/neutron mass = 1.67 x 10-24 g Electron mass = 9.11 x 10-28 g More about electron behavior later
Picture of an atom e- Electrons Neutrons p+ Nucleus Protons no
Atoms and Elements What is the difference between an element and an atom? An atom is a single example of an element. An element is the collective term for many atoms of a single substance.
Periodic Table of Elements Structure Listed in order of inc. atomic # Columns = Families or GROUPS Have similar chemical properties Referred to by the number and letter (A or B) over the column Many have special names Rows = PERIODS Contains info on physical properties (i.e. mp, bp, density, physical states, etc)
Element Characteristic Each square usually contains Element name Element symbol Atomic number The number of protons Symbolized at “Z” Atomic mass or mass number Atomic mass: decimal mole weight = to the average mass numbers of all isotopes Mass number: rounded mole weight Mass number: The sum of the number of the protons and the number of neutrons State of matter (usually)
Short Handing Element Characteristics Symbolizing AzX A = mass # (NO DECIMALS!) Z = atomic # (# of protons & electrons) X = symbol of the element
Isotopes Isotopes Atoms with the same number of protons but a different number of neutrons Atoms of the same element have the same atomic number but different mass numbers
Isotopes cont. Potassium-39 Potassium-40 Potassium-41 Protons 19 Neutrons 20 21 22 Electrons
Isotopes cont.
Isotopes cont. The diagram shows three oxygen isotopes. Each nucleus has eight protons (gray) and eight, nine, or ten neutrons (green).
Oxidation Numbers Indicate the charge on the ion Found on the periodic table Common oxidation numbers are given in additional table Note: Group 8 elements do not form ions; No ox # Transition metals have multiple ox #’s
Valence Electrons Electrons in the outer most shell The electrons on an atom that can be gained or lost in a chemical reaction More on this to come with Electron Configurations….
Alkali Metals Group IA (except H) Li, Na, K, Rb, Cs, Fr Soft, gray metals Very reactive Especially with water React with water to form bases “Alkali” = basic
Alkali Metals cont. Why are they so reactive? One electron in their outer shell Only 1 electron away from a full outer shell Want to lose that electron: easily react So reactive – don’t occur as free elements
Interesting Tidbits Li – used as depression medication Cs – used in atomic clocks Fr – predicted by Mendeleev in 1870s; discovered in 1939 Less than 1 oz. of Fr exists at any given time
Alkali Earth Metals Group IIA Be, Mg, Ca, Sr, Ba, Ra Shiny, silvery-white metals Harder and denser than Group IA Distributed in rock formations Reactive but not as reactive as Group IA 2 outer electrons Want to lose 2 to have a complete outer shell +2 oxidation number
Interesting Tidbits Used in pyrotechnics and fireworks Mg – white; Sr – red; Ba – green
Calcium Widely distributed as limestone Important biologically for bones and teeth Compounds of Calcium - CaCO3 = limestone] - CaO = “lime” or “quicklime” - Ca(OH)2 = “limewater”; treat antacid
Nobel Gases He, Ne, Ar, Kr, Xe, & Rn Group VIIIA He, Ne, Ar, Kr, Xe, & Rn Aka “Inert Gases” b/c they are unreactive Aka “Rare Gases” b/c they are very rare on Earth Colorless, tasteless, odorless
Nobel Gases cont. Why are they unreactive? Their outer shells are full Recall: the outer shell electrons are the ones involved in bonding When the outer shells are full, these electrons can’t bond and, therefore, react with other elements Used in: Lighting Fill light bulbs, neon lights, black lights, flashlight bulbs, strobe lights, headlights, etc.
Halogens F, Cl, Br, I, At Non-metals Group VIIA F, Cl, Br, I, At Non-metals - Exist in all 3 states at room temperature: * Solid: I, At * Liquid: Br * Gas: F, Cl Very reactive Most often, bond with metals Diatomic (F2, Cl2, etc.)
Halogens cont. Why are the halogens diatomic? 1 electron away from a full outer shell Too reactive/unstable by itself Bonds with another atom so both have 8 Dot diagrams What is the mole weight of chlorine gas? Which is more reactive, F2 or Cl2? F2
Transition Metals Middle section of the periodic table Exhibit metallic properties Ductile Malleable Good conductors of heat and electricity Silvery luster (except Cu and Au)
Ions Atoms that have a positive or negative charge To become an ion, an atom gains or loses electrons Cation = positively charged ion; Lose electron(s) Metals form positive ions Anion = negatively charged ion; Gain electron(s)
Polyatomic Ions Def: tightly bound groups of atoms that behave as a unit and carry a charge Ion composed of more than one atom List of common polyatomic ions Ex: SO4-2 NO3-1 ** Must memorize these CO3-2 polyatomic ions! ** PO4-3 OH-1 C2H3O2-1 NH4+1