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The Periodic Table chapter 6 How’d They Come Up With That? Our current society takes for granted all of the hard work, research, chance, and luck that has gone into creating and discovering the materials that are used in the products we utilize every day. For example, who was the first person to set or find a random black rock (coal) on fire and discover that it provided a good, constant source of heat? Who was the first person to discover that a substance found in some rocks was capable of being the ultimate explosive (uranium)? In nature and in the lab we have discovered over 100 different elements. We’ve organized the elements into a table based on their PHYSICAL and CHEMICAL PROPERTIES It took us almost 2000 years to figure out the properties of the elements currently in the Periodic Table of Elements and arrange them. Developing the Periodic Table By the early 1800s, enough information was known about the elements that scientists wanted an easy way to categorize the Earth’s ingredients. Many methods of organization were tried before scientists found the most effective way of grouping the elements “Mayan” Periodic Table, named for its similarity to the Mayan calendar. Johann Dobereiner 1780 - 1849 In 1829, he classified some elements into groups of three, which he called triads. The elements in a triad had similar chemical properties and orderly physical properties. (ex. Cl, Br, I and Ca, Sr, Ba) Model of triads John Newlands 1838 - 1898 In 1863, he suggested that elements be arranged in “octaves” because he noticed (after arranging the elements in order of increasing atomic mass) that certain properties repeated every 8th element. Law of Octaves Dmitri Mendeleev (1834 – 1907) Russian chemist, Dmitri Mendeleev organized elements into a table based on atomic mass and similar properties. Mendeleev stated that the properties of elements are a periodic function of their atomic masses. Mendeleev’s Periodic Table Mendeleev’s Prediction Mendeleev’s table had several missing elements. When these elements were discovered, they were almost exactly as Mendeleev predicted. The following is an example of the element we know as Germanium. Germanium is located below silicon. Mendeleev predicted its properties based on this location in his table. Ekasilicon (Es) Germanium (Ge) 1. Atomic mass: 72 1. Atomic mass: 72.61 2. High melting pt. 2. Melting pt: 945° C 3. Density: 5.5g/cm3 3. Density: 5.323g/cm3 4. Dark gray metal 4. Gray metal 5. Will obtain from K2EsF6 5. Obtain from K2GeF6 6. Will form EsO2 6. Forms oxide (GeO2) However, in spite of Mendeleev’s great achievement, problems arose when new elements were discovered and more accurate atomic weights determined. By looking at our modern periodic table, can you identify what problems might have caused chemists a headache? • 18Ar, 39.95 amu and 19K, 39.10 amu • 27Co, 58.93 amu and 28Ni, 58.69 amu Modern Periodic Law Henry Moseley 1887 - 1915 In 1913, through his work with X-rays, he determined the actual nuclear charge (atomic number) of the elements*. He rearranged the elements in order of increasing atomic number. *“There is in the atom a fundamental quantity which increases by regular steps as we pass from each element to the next. This quantity can only be the charge on the central positive nucleus.” Increasing atomic number is the basis for our current periodic law. His research was halted when the British government sent him to serve as a foot soldier in WWI. He was killed in the fighting in Gallipoli by a sniper’s bullet, at the age of 28. Because of this loss, the British government later restricted its scientists to noncombatant duties during WWII. Glenn T. Seaborg 1912 - 1999 After co-discovering 10 new elements, in 1944 he moved 14 elements out of the main body of the periodic table to their current location below the Lanthanide series. These became known as the Actinide series. He is the only person to have an element named after him while still alive. 106Sg- Seaborgium "This is the greatest honor ever bestowed upon me even better, I think, than winning the Nobel Prize." Periodic Table Periodic Table Review: Rows on the periodic table are called PERIODS Columns on the periodic table are called GROUPS or FAMILIES Periodic Table Review There are 7 periods and 18 groups. Electron arrangements are repeated in periods. Elements with similar econfigurations are placed in the same group. Elements in groups are also listed in order of their increasing principal quantum numbers. Electron Configuration Sublevel / s p d f e- capacity 2 6 10 14 S – block (sublevel) Contains elements in Group 1, Group 2, and He from Group 18. Electrons are added to the s – orbitals. EX: H = 1s1 He = 1s2 Li = 1s22s1 Be = 1s22s2 P – block (sublevel) Contains elements in Group 13, Group 14, Group 15, Group 16, Group 17, and the remaining elements from Group 18 (except He) Electrons are added to the p – orbitals. Ex: B = 1s22s22p1 C = 1s22s22p2 N = 1s22s22p3 D – block (sublevel) Contains elements from the center of the periodic table. These elements are called transition metals. Electrons are added to the d – orbitals of the transitions metals as well as La and Ac of the inner transition elements (rare earth). F – block (sublevel) Contains elements from the inner transition metals (rare earth elements) Electrons are added to the f – orbitals. Ex: Ce Lu Th Lr Octet Rule Atoms with full outer levels are stable (less reactive) For elements (except He) this stable configuration would have eight e-. (two in the outer s sublevels and six in the outer p sublevels) These outer eight e- (valence electrons) are called an octet. Octet Rule Eight electrons in an outer level render an atom unreactive. This is referred to as the Octet Rule. When atoms react with one another, they do so to obtain a stable config. Some atoms gain or lose e- (ions) and some share e- (molecules). Organizing Information on the Periodic Table Use a pen to label the following: Group 1 Alkali metals Group 2 Alkaline earth metals Group 16 Chalcogens Group 17 Halogens Group 18 Noble gases Sc – Uub Transition metals La – Lu Lanthanoids Ac – Lr Actinoids Organizing Information on the Periodic Table Draw a stair step dark line starting between B and Al. Label the right side: metals Label the left side: nonmetals Write METALLOID along stair step line. Label the valence e- (outer electrons). Use colored pencils to shade each group or category a different color. Basic Properties of Metals, Nonmetals, and Metalloids Metals: 1. Dense and shiny (luster). 2. Conduct heat and electricity well. 3. Have high melting/boiling points (high densities). 4.Malleable and ductile. Nonmetals: 1. Generally gases or brittle solids. 2. If solid, dull surface. 3. Good insulators. 4. Have low melting/boiling points (low densities) Metalloids: 1. Properties of both metals and nonmetals. 2. Some semiconductors. EX: Silicon, for example, possesses a metallic luster, yet it is an inefficient conductor (semiconductor) and is brittle. Properties of Alkali Metals Group 1 metals Soft silver metals. Less dense than other metals and lower melting points. Very reactive due to large size and one loosely held valence electron. Too reactive to be found free in nature. Properties of Alkaline Earth Metals Group 2 Metals Shiny silvery-white metals Have 2 valence electrons Not as reactive as alkali metals but very reactive All found in the Earth’s crust in mineral form Too reactive to be found in free element form Properties of Halogens Group 17 nonmetals All diatomic gases at room temperature EX: F2, (Br2 -liquid at room temp) Too reactive to be found as free elements in nature Most important group to be used in industry Properties of Chalcogens Group 16 nonmetals Diverse group that includes nonmetals, metalloids, and metals Properties of Noble Gases Group 18 nonmetals Complete octet of valence electrons s2p6 Largely unreactive Monotomic gases Periodic Trends Using the Periodic Table to Predict Properties of Elements The basis of the periodic table is the atomic structures of the elements. Position on the table and properties of these elements arise from the econfigurations of the atoms. Properties such as density, atomic radius, oxidation numbers, ionization energy, and electronegativity can be predicted. Trends in Oxidation Numbers Our knowledge of e- configurations and the stability of noble gases allows us to predict oxidation numbers for elements. Oxidation numbers represent the charge an ion obtains after losing or gaining valence electrons. 1+ 2+ Tend to have more than one oxidation number 3+ 3+ or 4+ 3+ 2+ or 4+ 3- 2- 1- 0 Two hydrogen atoms are walking down the road. One said, “I think I lost an electron!”. “Really”, the other replied, “ Are you sure?”. “Yes, I’m positive”. Atomic Radius Simply put, this is a measurement of the size of an atom (it’s determined by finding ½ the bond distance between two atoms of the same element). #1. Group trends As we increase the atomic number (or go down a group). . each atom has another energy level, so the atoms get bigger #2 - Period Trends Going from left to right across a period, the size gets smaller. Electrons are in the same energy level. But, there is more Coulombic attraction. Outermost electrons are pulled closer which reduces the volume of the electron cloud. Predicting Atomic Radius General rule: atomic size increases as you move diagonally from top right corner to bottom left corner. When graphed, atomic radii demonstrates a periodic trend Radii of ions: Ions are atoms that have gained or lost e- from the outer orbitals. Cations: (+) Become smaller 1. Positive charged nucleus attracting fewer e- so pulls electron cloud in tighter. 2. Reduced the number of energy levels. Na+1 11p+ 10e- Sodium atom is much larger than the positive sodium ion. Anions: (-) Become larger 1. Positive charged nucleus attracting more e- expands electron cloud. 2. Add more energy levels. S-2 16p+ 18e- The pull on each electron is reduced expanding the electron cloud. Ionization Energy The energy required to remove an efrom an atom. The larger the atom, the less energy is required because the e- are farther from the positive center. As atoms get larger ionization energy decreases because of the shielding effect (which says that the farther an electron is from the nucleus, the less tightly the positive nucleus grabs it). Remove the most loosely held e- is first ionization energy. Measured in kilojoules per mole kJ/mol Ionization energy increases diagonally from bottom left corner to top right corner. Classification based on First Ionization Energy METAL 1. Low 1st ionization energy. 2. Located on left side of Periodic Table. 3. Form positive ions. NONMETAL 1. High 1st ionization energy. 2. Located on the right side of Periodic Table. 3. Form negative ions. Multiple Ionization Energies Additional e- can be lost from an atom and the ionization energies can be measured. IONIZATION ENERGIES (kilojoules per mole) Element 1st 2nd 3rd 4th H 1312.0 He 2372.3 Li 520.2 7300 11750 Be 899.5 1760 14850 20900 B 800.6 2420 3660 25020 5th 5220 32660 Electronegativity Electronegativity is the ability of an atom to capture an electron. The smaller the atom the stronger its ability to take electrons from other atoms. Electronegativity is a unitless value. Fluorine is highest at 3.98 Francium is the lowest at 0.7 It increases from bottom left to top right corners. Electron Affinity e- affinity is a measure of an atom’s attraction for an e-. Metals have low e- affinities. Nonmetals have high e- affinities. Chemical reactions occur between atoms with high e- affinity and those with low e- affinity. EX: Al + Br Al2Br3 (low) (high) (more stable) Review Review Based on our trends: The most reactive metal element would be Francium The most reactive nonmetal element would be Fluorine In Summary Periodic table is a chart of elements in which the elements are arranged based on their e- configurations which dictates their properties. Moving down a group in the periodic table, atomic radii becomes larger because more energy levels are needed for more e-. In Summary As the size becomes larger, the eare located farther away from the positive center. This decreases the affinity of that atom to hold on to these outer e-, thus decreasing e- affinity. Ionization energy is low because it is easy for the atom to lose these outer e-. In Summary Moving across a period in the periodic table, atomic radii becomes smaller because the energy levels of periods are the same but the positive centers of atoms increase. This pulls the e- cloud closer to the nucleus, making the atom smaller. Ionization energy and e- affinity increases for these smaller atoms. THE END