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The Periodic Table of the Elements

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Title: The Periodic Table of the Elements


1
The Periodic Table of the Elements
2
Classification of Elements
  • Pure substances are either compounds or elements.
  • Compounds can be broken down into simpler
    substances, but elements cannot because they are
    made of only one kind of atom.
  • In the last three centuries, new technologies led
    scientists to try to identify all of the existing
    elements and group them into similar categories.
  • Currently, scientists have identified 112
    different elements. 92 of them occur naturally,
    and 20 are man-made. Scientists build
    super-heavy atoms to test the limits of atomic
    structure.
  • During the eighteenth and nineteenth centuries,
    scientists noticed that some elements behaved
    like other elements.
  • By comparing the behaviors of elements,
    scientists identified several groups of elements.
  • Other scientists of that time were able to
    determine the relative atomic masses of
    different elements.
  • These discoveries led to the development of the
    Periodic Table of the Elements, which is an
    important tool of chemists.

3
The First Periodic Table
  • Dmitri Mendeleev is known as the father of the
    Periodic Table.
  • He was born in Russia in 1834. As were many
    other scientists of the time, Mendeleev was
    interested in discovering if a pattern existed
    relating the known elements.
  • Mendeleev discovered that the physical and
    chemical properties of the elements occurred in a
    regular repeating patternthe Periodic Law.
  • He published his Periodic Table of the Elements
    in 1869, the first table that successfully
    summarized the relationships between the
    elements.
  • In this table, he arranged the known elements in
    ascending order according to their relative
    atomic masses, beginning with Hydrogen.
  • Mendeleev also arranged the elements in columns
    according to their physical and chemical
    properties.
  • Mendeleevs table pointed out some errors in
    accepted atomic weights, and also predicted the
    existence and properties of elements not yet
    discovered.
  • Mendeleevs table did not include any of the
    noble gases, because none of them had been
    discovered.

4
Revision of Mendeleevs Table
  • In Mendeleevs table, there were some elements
    that appeared to be in the wrong group if
    arranged strictly by increasing atomic weight.
    As more elements were discovered after
    Mendeleevs death, a few more misplaced
    elements appeared.
  • Some elements, such as Ni, were placed in the
    wrong groups because of multiple valence numbers
    or errors in the calculation of their atomic
    weights.
  • In 1914, Henry Moseley discovered the
    significance of atomic number, the number of
    protons in the nucleus of an atom.
  • When the Periodic Table was revised, arranging
    the elements by ascending atomic number, the
    inconsistencies and errors in the table vanished.
  • The Modern Periodic Table of the Elements has
    been modified so that the elements are now
    arranged by atomic number, rather than atomic
    weight.
  • The Table has seven horizontal rows, called
    periods, and a number of vertical columns called
    groups or families.
  • Elements in the same period have the same number
    of occupied energy levels.
  • Elements in the same group or family have similar
    properties.

5
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6
Metals, Nonmetals, and Metalloids
  • There are 92 naturally occurring and 13 man-made
    elements listed on the Periodic Table, with space
    left for future creations.
  • These elements can be divided into three basic
    types, according to their chemical and physical
    properties metals, nonmetals, and metalloids.
  • Most of the elements are metals. Characteristics
    of metals include high luster, high
    malleability, high ductility, good conductivity
    of heat and electricity, and have high melting
    and boiling points. Metals tend to lose
    electrons in chemical bonding, forming positive
    ions.
  • Metals are found on the left side of the Periodic
    Table.
  • Nonmetals are found on the right side of the
    Periodic Table.
  • Nonmetals are generally dull, brittle,
    non-malleable, non-ductile, with low melting and
    boiling points. Many are gases at room
    temperature. They are non-conductors of heat and
    electricity.
  • Nonmetals form negative ions because they tend to
    gain electrons during chemical bonding.
  • Metalloids have some of the properties of metals
    and some properties of nonmetals. They are found
    between metals and nonmetals in the Periodic
    Table, next to the zigzag line.

7
The Alkali Metals Group IA
  • The Alkali Metals are found in the first group of
    the Periodic Table. They are a group of elements
    that are so reactive that they are always found
    combined with other elements in nature.
  • The reason that these elements are so reactive is
    that they only have one electron in their outer
    shell, which they lose when bonding with other
    elements, to get a full outer shell of electrons.
    The alkali metals form 1 ions.
  • Alkali Metals are malleable and ductile, good
    conductors of heat and electricity, but are very
    soft.
  • The alkali metals include Lithium, Sodium,
    Potassium, Rubidium, Cesium, and Francium.
  • Alkali metals can explode when in contact with
    water.
  • Cesium and Francium are the most reactive in this
    group.
  • Francium is the most reactive of all metals.
  • Although Hydrogen is a nonmetal, it is often
    listed with this group because it has one
    electron in its only energy level. Hydrogen is
    highly reactive but only forms covalent bonds.

8
The Alkaline Earth Metals
  • The Alkaline Earth Elements are found in the
    second group of the Periodic Table.
  • Even though they are not as reactive as the
    alkali metals, the alkaline earth metals are
    highly reactive, and are not found in the
    elemental state in nature.
  • Each of the alkaline earth metals has two
    electrons in its outer energy level. Alkaline
    earth metals lose their two valence electrons and
    form 2 ions when bonding.
  • The alkaline earth elements include Beryllium,
    Magnesium, Calcium, Strontium, Barium, and Radium.

9
The Boron Family
  • The Boron Family is the third group on the
    Periodic Table. The members of this family have
    three electrons in their outer shell. Although
    Boron is never found uncombined in nature, some
    of the other members of this family sometimes
    are.
  • Members of the Boron Family tend to lose three
    electrons and form 3 ions.
  • Boron is a metalloid, and all other group members
    are metals.
  • Aluminum is found in this group. It is the most
    abundant metal on Earth. It is generally found
    in nature as aluminum oxide.
  • Other elements found in this family are Gallium,
    Indium, and Thallium.
  • Although Boron is a metalloid, all other elements
    in this family are metals.

10
The Carbon Family
  • The Carbon family is the fourth group, and
    contains one nonmetal, two metalloids, and two
    metals. All members of the carbon family have
    four electrons in their outer energy level.
    Members of this family include Carbon, Silicon,
    Germanium, Tin, and Lead. Members of this family
    tend to form covalent bonds.
  • Carbon is the sixth most abundant element in the
    universe, but not as common on Earth.
  • Carbon exists in several bonding forms such as
    graphite and diamonds. C-14 is used in
    radiological dating of some fossils.
  • It can form four covalent bonds with other
    elements and even other carbon atoms, resulting
    in an almost infinite number of carbon-containing
    compounds. Life on earth would be impossible
    without carbon.
  • Silicon is also found in the Carbon Family. It
    is the second most abundant element in the
    Earths crust, and is used in solar-electric
    cells and semi-conductors. Germanium is also
    used in electronic devices. Tin and lead have a
    number of uses.

11
The Nitrogen Family
  • The Nitrogen Family is the fifth group and
    contains two nonmetals, two metalloids, and only
    one metal. They all have five electrons in their
    outer energy level. They tend to gain three
    electrons when forming ionic bonds, and form -3
    ions.
  • Nitrogen makes up about 4/5 of the Earths
    atmosphere, and is a colorless, odorless gas at
    room temperature. It is a nonmetal. Nitrogen
    forms many compounds with oxygen, such as NO2 and
    N2O.
  • Phosphorus occurs naturally in solid form as red
    phosphorus or white phosphorus. It is highly
    reactive and will burst into flame in the
    presence of air. It is stored under water.
  • Arsenic is a metalloid, and is used in the
    semiconductor industry and in manufacturing. It
    is highly poisonous and is used in weed killer
    and rat poison.
  • Antimony is a hard brittle metalloid used in
    electronics. It is, like arsenic, highly
    poisonous.
  • Bismuth is the heaviest naturally occurring
    element that is not radioactive. It has a
    variety of uses from Pepto-Bismol to paint
    pigments, to electrical solder and the heads of
    fire sprinkler systems.

12
The Oxygen Family
  • Members of the Oxygen Family all have six
    electrons in their outermost energy level. The
    Oxygen Family is the sixth group on the Periodic
    Table and contains three nonmetals and two
    metalloids. There are no metals in the Oxygen
    Family.
  • Members of the Oxygen Family tend to gain two
    electrons and form -2 ions, when bonding
    ionically.
  • Oxygen is the most common element in the Earths
    crust and makes up 1/5 of the Earths atmosphere.
    It is a colorless, odorless gas at room
    temperature. All elements except the noble gases
    can form compounds with oxygen.
  • Sulfur is a yellow solid at room temperature.
    Sulfur is in sulfuric acid and also in acid rain.
    It is in the gas H2S, which smells like rotten
    eggs.
  • Selenium is a semiconductor that is sensitive to
    light, so it is often used in light sensors.
  • Tellurium is a brittle metalloid used in blasting
    caps.
  • Polonium is radioactive and was discovered by
    Marie Curie. It has few commercial uses.

13
The Halogens
  • All members of the Halogen Group have seven
    electrons in their outer energy level. They are
    the seventh group on the Periodic Table. This
    group contains four nonmetals and one metalloid.
    There are no metals among the halogens.
  • Because they only need one electron to complete
    their outer energy level, they are the most
    reactive of the nonmetals. They gain one
    electron and form -1 ions when bonding ionically.
  • Fluorine is the most reactive nonmetal and is
    never found alone in nature. It is a poisonous
    greenish-yellow gas at room temperature.
    Fluorine compounds are added to many water
    systems because they prevent tooth decay. Teflon
    is a fluorocarbon compound.
  • Chlorine is not as reactive as fluorine, but is
    also a reactive poisonous greenish-yellow gas.
    One of its most common compounds is NaCl, table
    salt.
  • Bromine is a reddish-brown liquid at room
    temperature. It is often used to disinfect hot
    tubs.
  • Iodine is a solid at room temperature that turns
    to a purple gas when heated. It is needed in
    your diet to keep your thyroid gland functioning
    properly.
  • Astatine is a radioactive metalloid, but not much
    is known about its properties.

14
The Noble Gases
  • The noble gases are the eighth group on the
    Periodic Table, and all of the members of this
    group are unreactive because their outer electron
    shell is already full.
  • Helium is the second lightest and second most
    abundant gas in the universe, but is relatively
    rare on Earth. Helium has two electrons in its
    only energy level. No compounds of Helium are
    known. It is used in balloons and blimps.
  • Neon is the best known of the noble gases because
    of its use in decorative lighting fixtures. It
    forms no compounds.
  • Argon is used to fill incandescent light bulbs to
    keep the filament from burning up. It is also
    used in welding.
  • Krypton is not a green solid that hurts Superman.
    It is an unreactive gas used in bright strobe
    lights and airport runway lights.
  • Xenon is a gas that is also used in strobe
    lights. It can be forced to react with fluorine,
    but is ordinarily unreactive.
  • Radon is a glowing yellow radioactive noble gas
    that is considered to be a health hazard if
    breathed in large amounts. It is used in cancer
    treatments.

15
The Transition Metals
  • The Transition Metals are the elements found on
    the Periodic Table between the Alkaline Earth
    Metals and the Boron Family.
  • While the Transition Metals all have no more than
    2 electrons in their outer energy level, their
    next energy level is incompletely filled.
  • The properties of the Transition Metals depend on
    the electron configuration of the outer two
    energy levels.
  • Transition elements form alloys easily. A
    copper-tin alloy is for mirrors and copper-zinc
    makes brass. Except for copper, the transition
    metals are all shiny and white, with high melting
    points and high densities.
  • Many of the most commonly known metals, such as
    gold, silver, mercury, iron, copper and nickel
    are in this group.

16
The Rare Earth Elements
  • There are 30 Rare Earth Elements. They are all
    metals, and they are divided into two sets The
    Lanthanide Series begins with element 57,
    Lanthanum and ends with element 71 Lutetium.
    The Actinide Series begins with element 89
    Actinium and ends with element 103 Lawrencium.
  • One element of the Lanthanide Series and most of
    the elements of the Actinide series are man-made.
    Many are radioactive.
  • All of the Rare Earth elements are found in Group
    3 of the Periodic Table in the sixth and seventh
    periods.

La Ce Pr Nd Pm Sm Eu Gd Tb
Dy Ho Er Tm Yb Lu
Lanthanide Series
Ac Th Pa U Np Pu Am Cm Bk
Cf Es Fm Md No Lr
Actinide Series
17
A Representative Block on the Periodic Table
  • Each block on the Periodic Table contains
    valuable information about the element listed.
  • The name of the element is often (but not always)
    listed.
  • The elements chemical symbol is always listed.
    This is either one or two letters. The first is
    always capitalized and the second (if there is
    one) is never capitalized.
  • The Atomic Number tells how many protons are in
    the nucleus of an atom of that element.
  • The Atomic Mass tells the average mass of one
    atom of that element in atomic mass units. It
    can be rounded off to determine the elements
    mass number.

Atomic Number
ChemicalSymbol
Name of Element
Atomic Mass
18
Periods, Families, and Electron Configuration
  • There are seven periods on the modern Periodic
    Table.
  • If an element appears in the third period (like
    Magnesium), this means that in its lowest energy
    state, the atoms electrons are in the first
    three periods.
  • Being located in the third period also means that
    the atoms first two energy levels are full.
  • The first energy level can hold 2 electrons. The
    second energy level can hold eight electrons.
  • Magnesium appears in the Alkaline Earth Family,
    in the IIA column of the Table. All elements in
    the IIA column have 2 electrons in their
    outermost energy level.
  • Elements in the IA column have 1 electron in
    their outside energy level, elements in the VA
    column have 5 electrons in their outside energy
    level, and so forth.
  • Elements in Column VIIIA are inert. Their
    outside energy levels are full, so they have no
    need to react to form compounds with other
    elements.
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