Celjhon Arino

PERIODIC TABLE :

Definition of Terms

Periodic Table - is a tabular display of the chemical elements.

The History of the Modern Periodic Table

During the nineteenth century, chemists began to categorize the elements according to similarities in their physical and chemical properties.

The end result of these studies was our modern periodic table.

Johann Dobereiner

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 andCa, Sr, Ba)

Model of triads

1780 - 1849

The History of the Modern Periodic Table

William Odling

Classification of elements into two dimensions

Found a horizontal connection between the elements fluorine, oxygen, nitrogen and carbon (first element in groups 1 – 4)

The History of the Modern Periodic Table

John Newlands

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

1838 - 1898

The History of the Modern Periodic Table

Newlands' claim to see a repeating pattern was met with savage ridicule on its announcement.

His classification of the elements, he was told, was as arbitrary as putting them in alphabetical order and his paper was rejected for publication by the Chemical Society.

The History of the Modern Periodic Table

Dmitri Mendeleev

In 1869 he published a table of the elements organized by increasing atomic mass

1834 - 1907

Mendelevium

The History of the Modern Periodic Table

Lothar Meyer

At the same time, he published his own table of the elements organized by increasing atomic mass.

1830 - 1895

The History of the Modern Periodic Table

• Both Mendeleev and Meyer arranged the elements in order of increasing atomic mass.

• Both left vacant spaces where unknown elements should fit.

The History of the Modern Periodic Table

• So why is Mendeleev called the “father of the modern periodic table” and not Meyer, or both?

The History of the Modern Periodic Table

• stated that if the atomic weight of an element caused it to be placed in the wrong group, then the weight must be wrong. (He corrected the atomic masses of Be, In, and U)

• was so confident in his table that he used it to predict the physical properties of three elements that were yet unknown.

Dmitri Mendeleev…

The History of the Modern Periodic Table

After the discovery of these unknown elements between 1874 and 1885, and the fact that Mendeleev’s predictions for Sc, Ga, and Ge were amazingly close to the actual values, his table was generally accepted.

The History of the Modern Periodic Table

John Rayleigh & William Ramsay

The noble gases discovered

Experiments on nitrogen eventually led to the discovery of a new element that would not react with anything. They named it ‘Argon’(meaning inactive)Ramsay went on to discovery He, Ne, Kr, Xe

Their relative atomic masses and their lack of chemical reactivity placed them in a group called the inert gasesRn was later discovered by Friedrich Ernst Dorn

The History of the Modern Periodic Table

Henry Moseley

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.”

1887 - 1915

The History of the Modern Periodic Table

Glenn T. Seaborg

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 knownas the Actinide series.

Actinide series.

1912 - 1999

The History of the Modern Periodic Table

1912 - 1999

Glenn T. Seaborg

He is the only person to have an element named after him while still alive.

"This is the greatest honor ever bestowed upon me - even better, I think, thanwinning the Nobel Prize."

The History of the Modern Periodic Table

Key in the Periodic Table

Elements are organized on the table according to their atomic number, usually found near the top of the square.

-The atomic number refers to how many protons an atom of that element has.-For instance, hydrogen has 1 proton, so it’s atomic number is 1.-The atomic number is unique to that element. No two elements have the same atomic number.

Key in the Periodic Table

Atomic NumberThis refers to how many protons an atom of that element has.No two elements, have the same number of protons.

Wave Model

Key in the Periodic Table

Atomic Mass

Atomic Mass refers to the “weight” of the atom.It is derived at by adding the number of protons with the number of neutrons.

This is a helium atom. Its atomic mass is 4 (protons plus neutrons).

What is its atomic number?

Key in the Periodic Table

Atomic Mass and Isotopes

While most atoms have the same number of protons and neutrons, some don’t.Some atoms have more or less neutrons than protons. These are called isotopes. An atomic mass number with a decimal is the total of the number of protons plus the average number of neutrons.

Key in the Periodic Table

Atomic Mass Unit (AMU)

The unit of measurement for an atom is an AMU. It stands for atomic mass unit.One AMU is equal to the mass of one proton.

Key in the Periodic Table

Atomic Mass Unit (AMU)

There are 6 X 1023 or 600,000,000,000,000,000,000,000 amus in one gram.(Remember that electrons are 2000 times smaller than one amu).

Key in the Periodic Table

SymbolsAll elements have their own unique symbol.It can consist of a single capital letter, or a capital letter and one or two lower case letters.

Key in the Periodic Table

Valence Electrons

The number of valence electrons an atom has may also appear in a square.Valence electrons are the electrons in the outer energy level of an atom.These are the electrons that are transferred or shared when atoms bond together.

Key in the Periodic Table

Where to elements come from?

The ‘Big Bang’ theory suggests that all the fundamental particles in the universe were formed over a very short time (a few seconds or less) in a huge explosion that occurred some 15 billion years ago.

Explain the fourth state of matter – plasma.How is He formed?What is the difference between nuclear fission and nuclear fusion?

Key in the Periodic Table

Where to elements come from?

Once a star has converted a large fraction of its core mass to iron, it has almost reeached the end of its lifeThe core of the star then begins to cool, causing a violent gravitational collapse, or implosion.Eventually the star explodes, spreading its products throughout the universe.An exploding star is called a supernova A supernova can produce heavier elements up to the size of the iron nucleus by nuclear fusion reactions. Larger stars can produce heavier atoms

Periodic Table Geography

Periodic Table Geography

The horizontal rows of the periodic table are called PERIODS.

The elements in any group of the periodic table have similar physical and chemical properties.

The vertical columns of the periodic table are called GROUPS, or FAMILIES.

Periodic Table Geography

Periodic Law

When elements are arranged in order of increasing atomic number, there is a periodic pattern in their physical and chemical properties.

Periodic Table Geography

Alkali Metals

Periodic Table Geography

Alkaline Earth Metals

Periodic Table Geography

Transition Metals

Periodic Table Geography

These elements are also called the rare-earth elements.

InnerTransition Metals

Periodic Table Geography

Halogens

Periodic Table Geography

Noble Gases

Periodic Table Geography

Groups and Block

Based upon the electron configuration of the elements the table can be divided into four blocks. These blocks represent the different sublevels of electron configuration.

Group A elements are called representative elementsGroup B elements are called transition elements.

The s and p block elementsare calledREPRESENTATIVE ELEMENTS.

The d block elementsare called

TRANSITION ELEMENTS

Groups and Block

The s-block elements:Groups 1-2 Electron configuration: ns1,2 (valence electrons in the s subshell)Contains the alkali metals (Group 1), and alkaline-earth metals (Group 2) Very reactive metals; Group 1 is more reactive than Group 2, but both do not exist in nature as free elements because they are too reactive. He has a filled s subshell of the innermost K shell of the atom rendering it unreactive.

Groups and Block

The d-block elements:Groups 3-12 Electron configuration: (n-1)d1-10ns0-2 (valence electrons in the p subshell)transition elements: typical metallic properties Good Conductors of electricity and have a high luster; less reactive than the s-block elements; many exist in nature as free elements.

Groups and Block

The f-block elements:Lanthanides and Actinides Between Groups 3 and 4. Between Periods 6 and 7. 14 in each; highly similar properties; resemble Group 2 elements. f subshells progressivley filled

Groups and Block

Groups and Block

Groups and Block

Metals are good conductors of heat and electricity.Metals are shiny.Metals are ductile (can be stretched into thin wires).Metals are malleable (can be pounded into thin sheets).A chemical property of metal is its reaction with water which results in corrosion.

Properties of Metals

Non-metals are poor conductors of heat and electricity.Non-metals are not ductile or malleable.Solid non-metals are brittle and break easily.They are dull.Many non-metals are gases.

Sulfur

Properties of Non-Metals

Silicon (Si)

Metalloids (metal-like) have properties of both metals and non-metals.They are solids that can be shiny or dull.They conduct heat and electricity better than non-metals but not as well as metals.They are ductile and malleable.

Properties of Metalloids

Families

Families

Families

Families

Families

Families

Families

Families

Families

Families

HYDROGEN

The hydrogen square sits atop Family AI, but it is not a member of that family. Hydrogen is in a class of its own.It’s a gas at room temperature.It has one proton and one electron in its one and only energy level.Hydrogen only needs 2 electrons to fill up its valence shell.

Alkali Metals

The alkali family is found in the first column of the periodic table.Atoms of the alkali metals have a single electron in their outermost level, in other words, 1 valence electron.They are shiny, have the consistency of clay, and are easily cut with a knife.

Alkali Metals

They are the most reactive metals.

They react violently with water.

Alkali metals are never found as free elements in nature. They are always bonded with another element.

Alkaline Earth Metals

They are never found uncombined in nature.They have two valence electrons.Alkaline earth metals include magnesium and calcium, among others.

Transition Metals

Transition Elements include those elements in the B families.These are the metals you are probably most familiar: copper, tin, zinc, iron, nickel, gold, and silver.They are good conductors of heat and electricity.

Transition Metals

The compounds of transition metals are usually brightly colored and are often used to color paints.Transition elements have 1 or 2 valence electrons, which they lose when they form bonds with other atoms. Some transition elements can lose electrons in their next-to-outermost level.

Transition Elements

Transition elements have properties similar to one another and to other metals, but their properties do not fit in with those of any other family. Many transition metals combine chemically with oxygen to form compounds called oxides.

Boron Family

The Boron Family is named after the first element in the family.Atoms in this family have 3 valence electrons.This family includes a metalloid (boron), and the rest are metals.This family includes the most abundant metal in the earth’s crust (aluminum).

Nitrogen Family

The nitrogen family is named after the element that makes up 78% of our atmosphere.This family includes non-metals, metalloids, and metals.Atoms in the nitrogen family have 5 valence electrons. They tend to share electrons when they bond.Other elements in this family are phosphorus, arsenic, antimony, and bismuth.

Oxygen Family

Atoms of this family have 6 valence electrons.Most elements in this family share electrons when forming compounds.Oxygen is the most abundant element in the earth’s crust. It is extremely active and combines with almost all elements.

Halogen Family

The elements in this family are fluorine, chlorine, bromine, iodine, and astatine.Halogens have 7 valence electrons, which explains why they are the most active non-metals. They are never found free in nature.

Halogen atoms only need to gain 1 electron to fill their outermost energy level.They react with alkali metals to form salts.

Noble Gas

Noble Gases are colorless gases that are extremely un-reactive. One important property of the noble gases is their inactivity. They are inactive because their outermost energy level is full. Because they do not readily combine with other elements to form compounds, the noble gases are called inert.The family of noble gases includes helium, neon, argon, krypton, xenon, and radon. All the noble gases are found in small amounts in the earth's atmosphere.

Rare Earth Elements

The thirty rare earth elements are composed of the lanthanide and actinide series.One element of the lanthanide series and most of the elements in the actinide series are called trans-uranium, which means synthetic or man-made.