Chapter 5 Periodic Law
SECTION 1 History of the Periodic Table
Mendeleev and Chemical Periodicity When the Russian chemist Dmitri Mendeleev heard about the new atomic masses he decided to include the new values in a chemistry textbook that he was writing Mendeleev hoped to organize the elements according to their properties
He placed the name of each known element on a card, together with the atomic mass of the element and a list of its observed physical and chemical properties He then arranged the cards according to various properties and looked for trends or patterns
Mendeleev noticed that when the elements were arranged in order of increasing atomic mass, certain similarities in their chemical properties appeared at regular intervals Such a repeating pattern is referred to as periodic
Mendeleev’s procedure left several empty spaces in his periodic table In 1871, he predicted the existence and properties of the elements that would fill three of the spaces By 1886, all three elements had been discovered scandium, Sc, gallium, Ga, and germanium, Ge Their properties are very similar to those predicted by Mendeleev
Success of Mendeleev’s predictions persuaded most chemists to accept his periodic table and earned him credit as the discoverer of the periodic law Two questions remained (1) Why could most of the elements be arranged in the order of increasing atomic mass but a few could not? (2) What was the reason for chemical periodicity?
Moseley and the Periodic Law In 1911 English scientist Henry Moseley examined the spectra of 38 different metals Moseley discovered a previously unknown pattern
The elements in the periodic table fit into patterns better when they were arranged in increasing order according to nuclear charge, or the number of protons in the nucleus Moseley’s work led to both the modern definition of atomic number and the recognition that atomic number, not atomic mass, is the basis for the organization of the periodic table
SECTION 2 Electron Configuration and the Periodic Table
The Modern Periodic Table “Periodic” - Repeating patterns Listed in order of increasing number of protons (atomic #) Properties of elements repeat Periodic Law- Periodic Law- “the physical and chemical properties of the elements are periodic functions of their atomic numbers.”
Periods and Blocks of the Periodic Table Elements are arranged vertically in the periodic table in groups that share similar chemical properties They are also organized horizontally in rows, or periods The length of each period is determined by the number of electrons that can occupy the sublevels being filled in that period
main group elements
Metals Most solids (Hg is liquid) Luster – shiny. Ductile – drawn into thin wires. Malleable – hammered into sheets. Conductors of heat and electricity. Include transition metals – “bridge” between elements on left & right of table
Non-Metals Properties are generally opposite of metals Poor conductors of heat and electricity Low boiling points Many are gases at room temperature Solid, non-metals are brittle (break easily) Chemical properties vary
Metalloids stair-step pattern Have properties similar to metals and non-metals Ability to conduct heat and electricity varies with temp Better than non-metals but not metals semiconductors
Group 1 – The Alkali Metals The elements of Group 1 of the periodic table (lithium, sodium, potassium, rubidium, cesium, and francium) are known as the alkali metals In their pure state, all of the alkali metals have a silvery appearance and are soft enough to cut with a knife
Because they are so reactive, alkali metals are not found in nature as free elements They combine strongly with most nonmetals And they react strongly with water to produce hydrogen gas and aqueous solutions of substances known as alkalis Because of their extreme reactivity with air or moisture, alkali metals are usually stored in kerosene or oil
Group 2 – The Alkaline-Earth Metals The elements of Group 2 of the periodic table are called the alkaline- earth metals Atoms of alkaline- earth metals contain a pair of electrons in their outermost s sublevel
Group 2 metals are harder, denser, and stronger than the alkali metals They also have higher melting points Less reactive than the alkali metals, but also too reactive to be found in nature as free elements
Transition Elements Good conductors of electricity and have a high luster They are typically less reactive than the alkali metals and the alkaline-earth metals Some are so unreactive that they do not easily form compounds, existing in nature as free elements
TungstenMercury Vanadium
Rare Earth Elements Lanthanide series (period 6) Actinide Series (period 7) Some radioactive Separated from table to make easy to read/print silver, silvery-white, or gray metals. Conduct electricity uranium
Halogen Family (“salt-former”) -7 Valence Electrons -most active nonmetals -never found pure in nature -react with alkali metals easily (forms salts) -F most active halogen
Halogens cont… F compounds in toothpaste Cl kills bacteria I keeps thyroid gland working properly bromine
The Noble Gases (Inert Gases) - non-reactive - outermost e- shell is full (8 VE) - In “neon” lights -in earth’s atmosphere (less than 1%) Neon
Section 5.3 Electron Configuration and Periodic Properties
Periodic Trends In periodic table, there is a DECREASE in atomic radii across the periods from left to right Caused by increasing positive charge of nucleus (more protons = more positive charge)
Group Trends Radii of elements decrease as you go UP a group Electrons occupy sublevels in consecutively higher main energy levels (located further away from nucleus) In general, the atomic radii of the main- groups elements decrease from the bottom to the top of a group
2. Ionization Energy Electrons can be removed from an atom if enough energy is supplied Using A as a symbol for an atom of ANY element, the process can be expressed as follows: A + energy A + + e -
A + represents an ion of element A with single positive charge (a 1 + ion) Ion an atom or group of bonded atoms that have a positive or negative charge Ionization any process that results in the formation of an ion
Period Trends In general, ionization energies of the main-group elements INCREASE across each period Caused by increasing nuclear charge Higher charge more strongly attracts electrons in same energy level
Group Trends Ionization energies generally INCREASE going UP a group Electrons going down in group are in higher energy levels, so further away from the nucleus Removed more easily Also more electrons between outermost electrons and the nucleus (shields them from attraction to positive nucleus)
What are Valence electrons? outermost e-’s Responsible for chem props Elements in same group… same # of VE ALL atoms want full outer energy level (usually 8 VE) To get full outer energy level, some elements: lose e- (metals) gain e- (non-metals) share electrons (some non-metals & metalloids)
Main-group elements – valence e- are in outermost s and p sublevels Inner e- held too tightly by nucleus to be involved in compound formation
6. Electronegativity Valence e- hold atoms together in compounds In many compounds, negative charge centered around one atom more than another Uneven distribution of charge has effect on compound’s properties Useful to have measurement of how strongly one atom attracts e- of another atom
Electronegativity measure of the ability of an atom in a chemical compound to attract electrons Most e-neg element (fluorine) – randomly assigned value of 4 Other values calculated in relation to F
Period Trends e-negs tend to INCREASE across each period There are exceptions (of course) Alkali and alkaline-earth metals are least e- neg In compounds, their atoms have low attraction for e-
Group Trends Electronegativities tend to INCREASE going UP a group or stay the same At higher energy levels electrons being added are further away from the nucleus Therefore, less attraction to the nucleus Also more electrons between outermost electrons and the nucleus (shields them from attraction to positive nucleus)