Only elements 1 to 92 (hydrogen to uranium) occur naturally, the others have been made during nuclear reactions where heavy nuclei are made to interact with each other in particle accelerators. Early in the 19th Century, Johann Döbereiner started to attempt to classify the known elements on the basis of their properties. He created several groups of three elements (his triads) with similar properties. It was a good start and we see his triads in the modern periodic table. He also noticed that the middle element had an atomic weight that was close to the mean of the other two. The first... Show more

Only elements 1 to 92 (hydrogen to uranium) occur naturally, the others have been made during nuclear reactions where heavy nuclei are made to interact with each other in particle accelerators.

Early in the 19th Century, Johann Döbereiner started to attempt to classify the known elements on the basis of their properties. He created several groups of three elements (his triads) with similar properties. It was a good start and we see his triads in the modern periodic table. He also noticed that the middle element had an atomic weight that was close to the mean of the other two.

The first person to notice the periodicity of the elements was Alexandre-Emile Béguyer de Chancourtois. He arranged the elements in order of atomic weight in a spiral drawn on a cylinder. He spotted that similar elements lined up vertically. However, his work wasn't recognised until after Mendeleev had published his findings. By the 1860s, John Newlands had arranged the sixty-two known elements into groups of eight with similar peoperties - his 'octaves'. His work was originally ridiculed but it wasn't until the 20th Century that the significance of his work was recognised.

The periodic table as we know it now is based on the work of Dimitri Mendeleev. He also arranged the known elements in groups of 8 horizontally, but with similar properties occuring in the vertical columns. His leap of genius was to leave gaps for elements that he believed had not been discovered and to reverse the order of certain elements where they didn't fit the patterns. There were still many shortcomings of this table, such as where to place hydrogen. His periodic table was widely accepted because he was able to use it to predict the properties of the missing elements. When the noble gases were discovered, they were added as 'group 0' without disturbing the rest of the table. In the 20th century, knowledge of atomic structure enabled scientists to make more and more sense of how the elements should be arranged, leading to the periodic table that you use in your lessons today.

Everyone has adopted the official IUPAC numbering system. The old version using groups 1 - 8 (or alternatively groups 1 - 7 plus group 0 for the noble gases) is much better as a teaching tool, allowing average students to cope more easily with the concepts of electronic structure and chemical bonding. Even at A-level, exam boards tend to give preference to the pre-1988 periodic table numbering system.

Related Tests:

GCSE Chemistry Practice Test: Periodic Table - Element Groups and Periods

GCSE Chemistry Practice Test: Periodic Table - Trends and Patterns

GCSE Chemistry Practice Test: Periodic Table - Transition Metal Elements 

GCSE Chemistry Practice Test: Periodic Table - Elements in Group Seven 

GCSE Chemistry Practice Test: Periodic Table - Elements in Group One 

Show less