DO NOW Grab packet and periodic table 1 DO NOW Grab packet and periodic table 1. Study these ions with a partner: acetate, bromate, chlorate, chlorite, cyanide, bicarbonate AGENDA Get to know periodic table and history Make your own periodic table REMINDERS ION Quiz friday
Chemistry Chapter 5 The Periodic Law
Mendeleev’s Periodic Table Dmitri Mendeleev
Mendeleev – organized periodic table Tried to organize periodic table according to properties Vertical columns in atomic mass order Made some exceptions to place elements in rows with similar properties (Tellurium and Iodine) Horizontal rows have similar chemical properties Gaps for “yet to be discovered” elements Left questions: why didn’t some elements fit in order of increasing mass? Why did some elements exhibit periodic behavior?
Henry Moseley Discovered that periodic table was in atomic number order, not atomic mass order Explained the Te-I anomaly
Periodic Law Physical and chemical properties of the elements are periodic functions of their atomic numbers
Modern Periodic Table Discovery of noble gases yields new family (Group 18 – aka inert gases) Lanthanides (#58 - #71) Actinides (#90 – #103)
Periods and Blocks of the Periodic Table Periods – horizontal rows Corresponds to highest principal quantum number Groups/Families – vertical columns; these elements share similar chemical properties (they have the same number of valence electrons) Blocks – periodic table can be broken into blocks corresponding to s, p, d, f sublevels
Orbital filling table
s block S block includes groups 1 and 2 Group1 – “The alkali metals” One s electron in outer shell Soft, silvery metals of low density and low melting points Highly reactive, never found pure in nature
s block Group 2 – “Alkaline Earth Metals” 2 s electrons in outer shell Denser, harder, stronger, less reactive than Group 1 Too reactive to be found pure in nature
Periodic Table with Group Names
The Properties of a Group: the Alkali Metals Easily lose valence electron (Reducing agents) React violently with water React with halogens to form salts
d block Groups 3 -12 Metals with typical metallic properties Referred to as transition metals Group number = sum of outermost s and d electrons
p block Groups 13-18 Properties vary greatly – metals, metalloids, and nonmetals Group 17 – halogens are most reactive of non metals Group 18 – noble gases are NOT reactive
f block Lanthanides – shiny metals similar to group 2 Actinides – all are radioactive; plutonium – lawrencium are man-made
Make your own periodic table! 1. Number the groups (18) 2. Number the periods (7) 3. Draw a heavy lack line between the metals and nonmetals. 4. Write the symbol of each element that exists as a gas at ordinary conditions in RED. 5. Write the symbol of each element that is a solid at ordinary conditions in BLACK. 6. Write the symbol of each element that is a liquid at ordinary condition in BLUE. 7. Write the symbol of each element that is a man-made element as an outline. 8. Place the atomic number for each element above the symbol. 9. Color each of these a different color and make a key at the bottom: Halogen (group 17) Noble gases (group 18) Alkali metals (group 1) Alkaline earth metals (group 2) Transition elements (group 3-12) Lanthanides Actinides Metalloids Post-transition metals Other non-metals 10. Outline the symbol’s box in dark green if it is RADIOACTIVE in its most common form.
Properties of Metals Metals: good conductors of heat and electricity Malleable Ductile Have high tensile strength luster
Examples of Metals Potassium, K reacts with water and must be stored in kerosene Copper, Cu, is a relatively soft metal, and a very good electrical conductor. Mercury, Hg, is the only metal that exists as a liquid at room temperature Zinc, Zn, is more stable than potassium
Properties of Nonmetals Carbon, the graphite in “pencil lead” is a great example of a nonmetallic element. Nonmetals are: poor conductors of heat and electricity brittle Many are gases at room temperature
Examples of Nonmetals Microspheres of phosphorus, P, a reactive nonmetal Sulfur, S, was once known as “brimstone” Graphite is not the only pure form of carbon, C. Diamond is also carbon; the color comes from impurities caught within the crystal structure
Properties of Metalloids Metalloids straddle the border between metals and nonmetals on the periodic table. They have properties of both metals and nonmetals. Metalloids are more brittle than metals, less brittle than most nonmetallic solids Metalloids are semiconductors of electricity Many used in computer parts Some metalloids possess metallic luster
Silicon, Si – A Metalloid Silicon has metallic luster Silicon is brittle like a nonmetal Silicon is a semiconductor of electricity Other metalloids include: Boron, B Germanium, Ge Arsenic, As Antimony, Sb Tellurium, Te
Determination of Atomic Radius: Half of the distance between nuclei in covalently bonded diatomic molecule "covalent atomic radii" Periodic Trends in Atomic Radius Radius decreases across a period Increased effective nuclear charge due to decreased shielding Radius increases down a group Addition of principal quantum levels
Table of Atomic Radii
Increases for successive electrons taken from Ionization Energy - the energy required to remove an electron from an atom Increases for successive electrons taken from the same atom Tends to increase across a period Electrons in the same quantum level do not shield as effectively as electrons in inner levels Irregularities at half filled and filled sublevels due to extra repulsion of electrons paired in orbitals, making them easier to remove Tends to decrease down a group Outer electrons are farther from the nucleus
Ionization of Magnesium Mg + 738 kJ Mg+ + e- Mg+ + 1451 kJ Mg2+ + e- Mg2+ + 7733 kJ Mg3+ + e-
Table of 1st Ionization Energies
Another Way to Look at Ionization Energy
Ionic Radii Cations Anions Positively charged ions Smaller than the corresponding atom Anions Negatively charged ions Larger than the corresponding atom
Table of Ion Sizes
Electronegativity A measure of the ability of an atom in a chemical compound to attract electrons Electronegativities tend to increase across a period * more nuclear charge, more power to attract electrons Electronegativities tend to decrease down a group or remain the same * additional energy levels result in less attraction to the nucleus
Periodic Table of Electronegativities