There is a certain grouping elements according to their similar properties and these include alkali metals, alkaline earth metals, transition metals (lanthanides, rare earth metals and actinides), nonmetals, metalloids, noble gases, halogens and basic metals. Period table has a mix of metals, non-metals and metalloids (semimetals). Hydrogen does not follow the octet rule and so is helium although it is stable and part of the noble gases. All other elements strive to achieve the octet rule. The octet rule of 8 electrons in the outer shell applies perfectly to the noble gases. They are non-reactive with any other elements. Group 18, for example, is referred to as noble gases. The elements within a group share chemical or physical properties. For instance, the first group is known as the lithium family (alkali metals), group 2 the beryllium family (alkaline earth metals, group 3 the scandium family, group 4 the titanium family, group 5 the vanadium family, group 6 the chromium family, group 7 the manganese family, group 8 the iron family, group 9 the cobalt family, group 10 the nickel family, group 11 the copper family (coinage metals), group 12 the zinc family (volatile metals), group 13 the boron family (icoasagens), group 14 carbon family (crystallogens, tetrels), group 15 the nitrogen family (pentels), group 16 the oxygen family (chalcogens), group 17 the fluorine family (halogens), and group 18 the helium or neon family (noble gases). The US style uses As and Bs.Įach of the 18 groups bears a name. The European naming style ꟷ now adopted as the IUPAC naming style, is used to name the groups from 1 through to 18. Electron affinity also increases as more electrons are added thus increasing a strong force of attraction with the nucleus.Īs you count down from top to bottom along the columns, you are counting the groups. Also, electronegativity increases as you move from left to right across the period. The nuclear charge increase across the periodic table. This increases the attraction in the nucleus and it will become relatively hard to remove an electron. Atoms within a period increase in atomic numbers as more protons are increasingly added. The other characteristic that the elements within a period shares is an increase in ionization energy. The lanthanides include the elements from 58 through to 71 while the actinides include the elements from 89 through to 103. These separated elements are inner transition metals and they fill the f-block in the atomic orbitals. The periodic would be large if the actinides and lanthanides were not removed. This explains why the periodic table is shortened by removing part of period 6 and 7 and displaying right below the periodic table. Periods 6 and 7 are the exceptions as they contain 32 elements in total. The periodic table has, in total, 18 groups as per the IUPAC naming system. The second and the third periods have 8 elements each. Notice that the first period has only two elements. For example, hydrogen and helium are in the same group and have one electron in the outer shell. Within a period, the elements share the outer shell (valence) electrons. This trend holds true for all other elements. Lithium (Li), for instance, has two energy shells because it is in period 2 while potassium (K) has four energy shells since it is in period 4. This means the electrons of the element will be represented on a specific number of energy levels in line with the periodic label. From hydrogen down to francium in period 7, the elements increase in atomic orbitals. There are typically 7 periods in a periodic table and each period denotes a new energy shell. The article unfolds further differences between the periods and groups.Ĭounting from left to the far right on the periodic table, it is the period. The elements were arranged into groups and periods based on certain characteristics such as chemical/physical properties for groups and electron configurations for the periods. Periods are the horizontal rows while the groups, also called families, are the vertical columns. Periods and groups are the two important classifications that ancient chemists used to organize the iconic periodic table into columns and rows.
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