The Lanthanides consist of the elements in the f-block of period six in the periodic table. While these metals can be considered transition metals, they have properties that set them apart from the rest of the elements.
IntroductionThe Lanthanides were first discovered in 1787 when a unusual black mineral was found in Ytterby, Sweden. This mineral, now known as Gadolinite, was later separated into the various Lanthanide elements. In 1794, Professor Gadolin obtained yttria, an impure form of yttrium oxide, from the mineral. In 1803, Berzelius and Klaproth secluded the first Cerium compound. Later, Moseley used an x-ray spectra of the elements to prove that there were fourteen elements between Lanthanum and Hafnium. The rest of the elements were later separated from the same mineral.These elements were first classified as ‘rare earth’ due to the fact that obtained by reasonably rare minerals. However, this is can be misleading since the Lanthanide elements have a practically unlimited abundance. The term Lanthanides was adopted, originating from the first element of the series, Lanthanum.

Like any other series in the periodic table, such as the Alkali metals or the Halogens, the Lanthanides share many similar characteristics. These characteristics include the following:
Similarity in physical properties throughout the series
Adoption mainly of the +3 oxidation state. Usually found in crystalline compounds)
They can also have an oxidation state of +2 or +4, though some lanthanides are most stable in the +3 oxidation state.
Adoption of coordination numbers greater than 6 (usually 8-9) in compounds
Tendency to decreasing coordination number across the series
A preference for more electronegative elements (such as O or F) binding
Very small crystal-field effects
Little dependence on ligands
Ionic complexes undergo rapid ligand-exchange

Electron ConfigurationSimilarly, the Lanthanides have similarities in their electron configuration, which explains most of the physical similarities. These elements are different from the main group elements in the fact that they have electrons in the f orbital. After Lanthanum, the energy of the 4f sub-shell falls below that of the 5d sub-shell. This means that the electron start to fill the 4f sub-shell before the 5d sub-shell.
The electron configurations of these elements were primarily established through experiments. The technique used is based on the fact that each line in an emission spectrum reveals the energy change involved in the transition of an electron from one energy level to another. However, the problem with this technique with respect to the Lanthanide elements is the fact that the 4f and 5d sub-shells have very similar energy levels, which can make it hard to tell the difference between the two.
Another important feature of the Lanthanides is the Lanthanide Contraction, in which the 5s and 5p orbitals penetrate the 4f sub-shell. This means that the 4f orbital is not shielded from the increasing nuclear change, which causes the atomic radius of the atom to decrease that continues throughout the series.
Table 1: Electron Configurations of the Lanthanide Elements
Symbol Idealized Observed Symbol Idealized Observed
La 5d16s2 5d16s2 Tb 4f85d16s2 4f96s2or 4f85d16s2
Ce 4f15d16s2 4f15d16s2 Dy 4f95d16s2 4f106s2
Pr 4f25d16s2 4f36s2 Ho 4f105d16s2 4f116s2
Nd 4f35d16s2 4f46s2 Er 4f115d16s2 4f126s2
Pm 4f45d16s2 4f56s2 Tm 4f125d16s2 4f136s2
Sm 4f55d16s2 4f66s2 Yb 4f135d16s2 4f146s2
Eu 4f65d16s2 4f76s2 Lu 4f145d16s2 4f145d16s2
Gd 4f75d16s2 4f75d16s2

Properties and Chemical ReactionsOne property of the Lanthanides that affect how they will react with other elements is called the basicity. Basicity is a measure of the ease at which an atom will lose electrons. In another words, it would be the lack of attraction that a cation has for electrons or anions. In simple terms, basicity refers to have much of a base a species is. For the Lanthanides, the basicity series is the following:
La3+ > Ce3+ > Pr3+ > Nd3+ > Pm3+ > Sm3+ > Eu3+ > Gd3+ > Tb3+ > Dy3+ > Ho3+ > Er3+ > Tm3+ > Yb3+ > Lu3+
In other words, the basicity decreases as the atomic number increases. Basicity differences are shown in the solubility of the salts and the formation of the complex species. Another property of the Lanthanides is their magnetic characteristics. The major magnetic properties of any chemical species are a result of the fact that each moving electron is a micromagnet. The species are either diamagnetic, meaning they have no unpaired electrons, or paramagnetic, meaning that they do have some unpaired electrons. The diamagnetic ions are: La3+, Lu3+, Yb2+ and Ce4+.The rest of the elements are paramagnetic.
Metals and their AlloysThe metals have a silvery shine when freshly cut. However, they can tarnish quickly in air, especially Ce, La and Eu. These elements react with water slowly in cold, though that reaction can happen quickly when heated. This is due to their electropositive nature. The Lanthanides have the following reactions:
oxidize rapidly in moist air
dissolve quickly in acids
reaction with oxygen is slow at room temperature, but they can ignite around 150-200 °C
react with halogens upon heating
upon heating, react with S, H, C and N
Table 2: Properties of the Lathanides
Symbol Ionization Energy (kJ/mol) Melting Point (°C) Boiling Point(°C)
La 538 920 3469
Ce 527 795 3468
Pr 523 935 3127
Nd 529 1024 3027
Pm 536
Sm 543 1072 1900
Eu 546 826 1429
Gd 593 1312 3000
Tb 564 1356 2800
Dy 572 1407 2600
Ho 581 1461 2600
Er 589 1497 2900
Tm 597 1545 1727
Yb 603 824 1427
Lu 523 1652 3327

Periodic Trends: SizeThe size of the atomic and ionic radiiis determined by both the nuclear charge and by the number of electrons that are in the electronic shells. Within those shells, the degree of occupancy will also affect the size. In the Lanthanides, there is a decrease in atomic size from La to Lu. This decrease is known as the Lanthanide Contraction. The trend for the entire periodic table states that the atomic radius decreases as you travel from left to right. Therefore, the Lanthanides share this trend with the rest of the elements.
Table 3: Periodic Trends
Element Atomic Radius (pm) Ionic Radius (3+) Element Atomic Radius (pm) Ionic Radius (3+)
La 187.7 106.1 Tb 178.2 92.3
Ce 182 103.4 Dy 177.3 90.8
Pr 182.8 101.3 Ho 176.6 89.4
Nd 182.1 99.5 Er 175.7 88.1
Pm 181 97.9 Tm 174.6 89.4
Sm 180.2 96.4 Yb 194.0 85.8
Eu 204.2 95.0 Lu 173.4 84.8
Gd 180.2 93.8

Color and Light AbsorbanceThe color that a substance appears is the color that is reflected by the substance. This means that if a substance appears green, the green light is being reflected. The wavelength of the light determines if the light with be reflected or absorbed. Similarly, the splitting of the orbitals can affect the wavelength that can be absorbed. This is turn would be affected by the amount of unpaired electrons.
Table 4: Unpaired Electrons and Color
Ion Unpaired Electrons Color Ion Unpaired Electrons Color
La3+ 0 Colorless Tb3+ 6 Pale Pink
Ce3+ 1 Colorless Dy3+ 5 Yellow
Pr3+ 2 Green Ho3+ 4 Pink; yellow
Nd3+ 3 Reddish Er3+ 3 Reddish
Pm3+ 4 Pink; yellow Tm3+ 2 Green
Sm3+ 5 Yellow Yb3+ 1 Colorless
Eu3+ 6 Pale Pink Lu3+ 0 Colorless
Gd3+ 7 Colorless

Occurrence in NatureEach known Lanthanide mineral contains all the members of the series. However, each mineral contains different concentrations of the individual Lanthanides. The three main mineral sources are the following:
Monazite: contains mostly the lighter Lanthanides. The commercial mining of monazite sands in the United States is centered in Florida and the Carolinas
Xenotime: contains mostly the heavier Lanthanides
Euxenite: contains a fairly even distribution of the LanthanidesIn all the ores, the atoms with a even atomic number are more abundant. This allows for more nuclear stability, as explained in the Oddo-Harkins rule. The Oddo-Harkins rule simply states that the abundance of elements with an even atomic number is greater than the abundance of elements with an odd atomic number. In order to obtain these elements, the minerals must go through a separating process, known as separation chemistry. This can be done with selective reduction or oxidation. Another possibility is an ion-exchange method.
Applications
Metals and AlloysThe pure metals of the Lanthanides have little use. However, the alloys of the metals can be very useful. For example, the alloys of Cerium have been used for metallurgical applications due to their strong reducing abilities.
Non-nuclearThe Lanthanides can also be used for ceramic purposes. The almost glass-like covering of a ceramic dish can be created with the lanthanides. They are also used to improve the intensity and color balance of arc lights.
NuclearLike the Actinides, the Lanthanides can be used for nuclear purposes. The hydrides can be used as hydrogen-moderator carriers. The oxides can be used as diluents in nuclear fields. The metals are good for being used as structural components. The can also be used for structural-alloy-modifying components of reactors. It is also possible for some elements, such as Tm, to be used as portable x-ray sources. Other elements, such as Eu, can be used as radiation sources.