Periodic Table of Elements

The periodic table of elements contains in a limited space the very essense of our knowledge for chemistry today. If one know how to read the table he/she can extract some very useful information to use in many fields of chemistry and physics.

I. History

The periodic table of the chemical elements (also known as Mendeleev’s table, periodic table of the elements or just periodic table) is a tabular display of the chemical elements. Although precursors to this table exist, its invention is generally credited to Russian chemist Dmitri Mendeleev in 1869, who intended the table to illustrate recurring (“periodic”) trends in the propertiesof the elements. The layout of the table has been refined and extended over time, as new elements have been discovered, and new theoretical models have been developed to explain chemical behavior. [1] [2]

II. The Periodic Table of Elements

You can see the Periodic Table of Elements in the picture below.

Periodic Table [source 1=”IUPAC,” 2=”last” 3=”updated:” 4=”2012-06-01″ language=”:”][/source]

There are also some other forms of the table but this is the most common. Here elements are listed in order of increasing atomic number (i.e., the number of protons in the atomic nucleus). Rows are arranged so that elements with similar properties fall into the same columns.

III. Analysis: How to read the table

As mentioned above, the Periodic Table is organized in rows and columns called Periods and Groups respectively. You can see those coloured in the following picture. What is important is to know how to read the table and understand the meaning behind that categorization. [3] [4]

Periodic Table of Elements with Periods and Groups coloured [1]

The organization of the elements in this ways is directly linked to the way our chemistry views the inner structure of the elements: as atoms having a nucleus and electrons moving around it. It all starts with the Hydrogen, which has only one proton in its nucleus and one electron spinning around that core. Then the table moves over to Helium with an atomic number equal to 2 etc.

1. Scientific meaning of Periods

According to quantum mechanical theories of electron configuration within atoms, each row (period) in the table corresponds to the filling of a quantum shell of electrons. You can imagine a “shell” as an area around the nucleus able to have a specific maximum number of electrons. There is a standard notation for these areas around the atom nucleus: the inner shell (the orbital closer to the atom’s nucleus / core) is called “1s” and then we move on to shells like {2s, 2p}, {3s, 3p, 3d} etc.

Electronic orbitals [7]

Electrons in an atoms fill in the first (inner) orbital first, which is 1s. Each orbital can have up to 2n2 electrones, where “n” is a number starting from 1 for 1s orbital and increasing as we go on further away from the core. That means that 1s orbital can contain up to 2 electones. When that area if filled with the maximum number of electrones, we move on to the next one which is 2s and so on.  In each period of the table a different “team” of orbitals is “completed” with electrons, as the following table illustrates.

2. Scientific meaning of Groups

The modern explanation of the pattern of the table is that the elements in a group have similar configurations of the outermost electron shells of their atoms (most chemical properties are dominated by the orbital location of the outermost electron). That can be seen in the following table.

The electon configuration of elements related to the grouping in the Periodic Table of Elements [5]

In the above table one can see that the atoms in the first column have one (1) electon in their outermost orbital. Similarly atoms in the second group have two (2) electons in the outermost orbital.

Z

Element

No. of electrons/shell

4

Beryllium

2, 2

12

Magnesium

2, 8, 2

20

Calcium

2, 8, 8, 2

38

Strontium

2, 8, 18, 8, 2

56

Barium

2, 8, 18, 18, 8, 2

88

Radium

2, 8, 18, 32, 18, 8, 2

Example of similar number of elentrons in the outermost orbital for the 2nd Group atoms

The above table clearly indicates that all those elements have 2 electrons in their external electron orbital. That is something of great importance as one can see from the next section of the article.

3. The importance of Groups for Chemistry

Each atom has the inherent tendency to get into a more stable condition. That is the way things go around in nature, that is the reason behind any spontaneous chemical reaction: everything want to become as stable as it can get. How can atoms get stable? By filling in their outermost orbital with 8 electons (or 2 if the outermost orbital is the 1s). That can happen via chemical bonds with other elements, which have the necessary electrons for something like that to happen. So oxygene (which has 6 electrons in its outermost shell) needs to connect with two hydrogen atoms (everyone of which has 1 electron in the outermost orbital) in a bond called “covalent bond”, so as to form a single molecule of water. A simple look at the table of elements can help us predict the possible reactions an element can participate in.

The water molecule: Oxygene takes the 2 electrons it needs to fill in its outermost orbital from the two hydrogen atoms with which it bonds

IV. The official Table of Elements from IUPAC

The Table of Elements constantly changes as new elements are discovered (or should we say… “discovered” ?)

One can find the IUPAC (International Union of Pure and Applied Chemistry) official table of elements at http://old.iupac.org/reports/periodic_table/index.html. At that site you can even download for free a printable PDF version of the Periodic Table of Elements. [6]

References

  1. http://en.wikipedia.org/wiki/Periodic_table 
  2. http://www.wou.edu/las/physci/ch412/perhist.htm 
  3. MIT University – Periodic Table of elements 
  4. Cambridge University – Periodic Table of Elements 
  5. http://en.wikipedia.org/wiki/Electron_configuration 
  6. IUPAC official Periodic Table of Elements

Author: skakos

Spiros Kakos is a thinker located in Greece. He has been Chief Editor of Harmonia Philosophica since its inception. In the past he has worked as a senior technical advisor for many years. In his free time he develops software solutions and contributes to the open source community. He has also worked as a phD researcher in the Advanced Materials sector related to the PCB industry. He likes reading and writting, not only philosophy but also in general. He believes that science and religion are two sides of the same coin and is profoundly interested in Religion and Science philosophy. His philosophical work is mainly concentrated on an effort to free thinking of "logic" and reconcile all philosophical opinions under the umbrella of the "One" that Parmenides - one of the first thinkers - visualized. The "Harmonia Philosophica" articles program is the tool that will accomplish that. Life's purpose is to be defeated by greater things. And the most important things in life are illogical. We must fight the dogmatic belief in "logic" if we are to stay humans... Credo quia absurdum!

6 thoughts on “Periodic Table of Elements”

  1. As a chemical engineer… — are you of the opinion that Hydrogen should be classed as a metal instead of a non metal? Under pressure it is magnetic and conductes electricity and when it reacts with a non metal it surrenders it electron like metal instead of sharing it like a non metal.

    1. Untitled — Classification of elements is a matter of how people see things. You can see things differently. The fact is that one way of “seeing” things has dominated chemistry and others are more or less required to follow the same way…

  2. Beautiful. — After reading your knol I got an idea how to explain the brain in a new way! Thanks for such a clear cut description of the periodic table.

    1. Untitled — I have not written anything yet but I got thinking. Thinking is the first step. It will gestate for some time. Just imagine a tiny difference in the number of electrons/protons yet look at the vast differences in the properties of the elements. Differences from looks, to softness, to malleability to all kinds of properties. Thus it is clear that perhaps food and what we put into the brain matters far more than we can ever imagine. Perhaps after all we can develop a pill for say knowing Italian. It is one more evidence that the physical brain is the foundation that sprouts the emotional brain.Just observe Oxygen is 8 and nitrogen is 7. Such a tiny difference and yet look at the vast differences between the two elements. Imagine a glass of water in which we drop 7 sugar cubes and then add one more sugar cube. Imagine the amazement if the extra cube transforms the sweetened water into an entirely new entity!Also another question to be asked is are the electrons/protons of say gold exactly the same as that of say iron. But lets take two elements that have just one electron difference between them yet look at the vast difference in their very physical nature. It would be interesting to research how this magical transformation of properties takes place. Whether the qualities /properties of the gold proton and the iron proton are the same or even these get transformed? There is not much original in these observations but just think what if basic emotions are the electrons of our personalities. Then my quote, “Love brings the side effects of wisdom and hate brings the side effects of ignorance” has a much deeper significance… Love is no longer just a moral electron. Love is an essential physical electron that transforms all the other electrons physically!!! This can be the first step to a couple of original knols!’This knol is inspired by SKS’s Periodic table knol.’ I have just posted this knol.

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