Section 5.2: Electron Configuration and the Periodic Table

Section 5.2: Electron Configuration and the Periodic Table

Periods and Blocks of the Periodic Table:

-Elements arranged vertically in groups/family with similar properties

-Elements in horizontal rows (period) w/ similar chemical properties

-Length of period = number of electrons occupying sublevels being filled in that period

-Periodic Table divided into 4 blocks:s,p,d,f

• Name of each block determined by whether an s,p,d, or f sublevel is being filled in successive elements of that block

-Period of element determined from element’s electron configuration

• Aresnic: [Ar]3d104s24p3
• 4 in 4p3 indicates arsenic’shighest occupied energy level is 4

The s-Block Elements: Groups 1 and 2:

-Elements of s block are chemically reactive metals (Grp1 more reactive)

-Outermost energy level in atom of each Grp 1 element contains a single s electron

• Makes Grp1 metals extremely reactive

-N = number of highest occupied energy level

• Grp 1 & 2 elements are ns1 and ns2
• E.g. Na grp configuration written as ns1 where n = 3

-Alkali Metals: elements of Group 1 of periodic table

• In pure state, have silvery appearance and are soft to cut with knife
• So reactive, not found in nature as free elements
• Combine vigorously w/ most nonmetals
• React strongly w/ water ot produce hydrogen gas & alkali solution
• Stored in kerosene because of extreme reactivity w/ air and moisture
• Group 1: lower down column, melt at lower temperatures

-Alkaline-earth metals: elements of Group 2 of the periodic table

• Atoms of alkaline-earth metals contain a pair of electrons in outermost s sublevel
• Group configuration: ns2
• Harder, denser, stronger than alkali metals
• Higher melting points than alkali
• Less reactive, but also too reactive to be free elements

Hydrogen and Helium:

-Hydrogen unique elements, not related to Group 1

-Electron configuration: 1s1 (ns1)

-Though helium has ns2 configuration, its part of Grp 18 since unreactive

The d-Block Elements: Groups 3-12

-Each d sublevel consists of five orbitals with a maximum of two electrons each, or up to 10 electrons possible in each d sublevel

-Group configuration for Group 3: (n-1)d1ns2

• E.g. atoms of Group 12 elements have 10 electrons in the d sublevel plus two electrons in the ns sublevel
• Grp config: (n-1)d10ns2

-Deviations from orderly d sublevel filling occur in grps 4-11

• E.g.: Nickel:
• [Ar]3d84s2
• Sums of outer s and d electrons is equal to group number (3+4=7)

-Transition Elements: d-block elements are metals with typical metallic properties

• good conductors of electricity and have high luster
• less reactive than alkali metals and alkaline-earth

The p-Block elements: Groups 13-18 (except Helium)

-Main-group elements: p-block elements together with the s-block elements

-Electron configuration: ns2np1

-Total number of electrons in highest occupied level = group number minus 10

• i.e.: Bromine: 17-10

-p block properties vary greatly

• right: nonmetal; left: metalloids

-Halogens: elements of group 17

• Most reactive nonmetals
• React with most metals to form salts

-Metalloids mostly brittle solids

-Metals of p block generally harder/denser than s-block alkaline-earth metals, but softer and less dense than the d-block metals

The f-block elements: Lanthanides and Actinides

-Filling of the 4f sublevel

-With seven 4f orbitals to be filled w/ 2electrons each, there are a total of 14 f-block elements

-Lanthanides are shiny metals similar to Grp 2 alkaline-earth metals

-14 f-block elements called actinides

• 5f sublevel is being filled with 14 electrons
• Actinides are all radioactive