High School Chemistry/Lanthanides and Actinides

• Define the lanthanides and actinides.
• Place the lanthanides and actinides in the periodic table.
• Explain the importance of both the lanthanides and actinides.
• Write electron configurations for lanthanides and actinides.

There is one group that we have neglected to mention throughout this chapter. This group belongs to a special group found almost disjointed, if you like, from the Periodic Table. They are given the names the Lanthanide Series and the Actinide Series or the lanthanides and the actinides. The lanthanides are an important group of elements. Most of them are formed when uranium and plutonium undergo nuclear reactions. The elements of the lanthanide series are also known as the rare earth elements. Both the lanthanides and the actinides make up what are known as the inner transition series. The f block is given this name because if the f block were placed in its proper numerical position in the Periodic Table, it would be in the transition metals between groups 2 and 3.

The lanthanide series includes elements from number 58 to 71, which is 14 elements. The f sub-level contains seven orbitals and each orbital will hold two electrons. Therefore, it is possible to place 14 electrons in the 4f sub-level.

The lanthanide series fills the 4f sublevel as you move from cerium (Ce) to lutetium (Lu). The same holds for the actinide series that runs from atomic number 90 through to number 103, again 14 elements. Thus, as you move from thorium (Th) at element number 90, you begin to fill up the 5f sublevel and continue to fill up the 5f sublevel until you finish the actinide series at lawrencium (Lr).

The lanthanides and the actinides make up the f block of the Periodic Table. The lanthanides are the elements produced as the 4f sublevel is filled with electrons and the actinides are formed while filling the 5f sublevel. Generally speaking, the lanthanides have electron configurations that follow the Aufbau rule. There are some variations, however, in a few of the lanthanide elements. We will expand a tiny portion of the Periodic Table below to show what happens to some of the electron configurations in the lanthanide and actinide series.

Lanthanides	58 Ce 140	59 Pr 141	60 Nd 144	61 Pm 145	62 Sm 150	63 Eu 152	64 Gd 157	65 Tb 159	66 Dy 163	67 Ho 165	68 Er 167	69 Tm 169	70 Yb 173	71 Lu 175
Actinides	90 Th 232	91 Pa 231	92 U 238	93 Np 237	94 Pu 244	95 Am 243	96 Cm 247	97 Bk 247	98 Cf 251	99 Es 252	100 Fm 257	101 Md 258	102 No 259	103 Lr 260

Look, for example, at the electron configuration for cerium, the first element of the lanthanide series. Cerium, Ce, is element number 58.

₅₈Ce: 1s²2s²2p⁶3s²3p⁶4s²3d¹⁰4p⁶5s²4d¹⁰5p⁶6s²5d¹4f¹

or

₅₈Ce: [Xe]6s²5d¹4f¹

Now look at the electronic configuration for praseodymium, an element used in the making of aircraft engines but also in lighting for making movies. Praseodymium, Pr, is element number 59 and has the following electron configuration.

₅₉Pr: 1s²2s²2p⁶3s²3p⁶4s²3d¹⁰4p⁶5s²4d¹⁰5p⁶6s²4f³

or

₅₉Pr: [Xe]6s²4f³

Notice the d electron is no longer a part of the electron configuration. There are three lanthanide metals that have properties similar to the d block. These are cerium, Ce, lutetium, Lu, and gadolinium, Gd. All of these metals contain a d electron in their electron configuration. The rest, like praseodymium, simply fill the 4f sublevel as the atomic number increases.

Unlike the lanthanide family members, most of the actinide series are radioactive. Most of the elements in the actinide series have the same properties as the d block. Members of the actinide series can lose multiple numbers of electrons to form a variety of different ions. Table 9.14 shows the noble gas electron configuration for the elements of the actinide series.

• The lanthanide and actinide series make up the inner transition metals.
• The lanthanide series fill up the 4f sublevel and the actinide series fill up the 5f sublevel.
• The first, middle, and last member of the lanthanide series have properties of the f block and the d block.
• Many of the actinide series have properties of both the d block and the f block elements.

1. Why are the f block elements referred to by some as inner transition elements?
2. What do europium and americium have in common as far as their electron configuration?
3. What is the electron configuration for Berkelium?

   (a) [Xe]7s²5f⁹

   (b) [Xe]7s²5f⁹6'd¹

   (c) [Rn]7s²5f⁹

   (d) [Rn]7s²5f⁹6d¹

4. How many f electrons are there in the electron configuration for einsteinium?

   (a) 0

   (b) 11

   (c) 14

   (d) 25

5. Write the electron configuration for Ytterbium, Yb.
6. What are the valence electrons for Ytterbium, Yb? What periods and sublevels are they in?
7. Write the noble gas electronic configuration for uranium, U.
8. What are the valence electrons for uranium, U? What periods and sublevels are they in?
9. Write the electron configurations for neptunium and then for plutonium. Now write an explanation for what seems to be happening.

actinides

The elements found in the second period of the f block. These elements fill up the 5f sublevel.

lanthanides

The rare earth elements found in the first period of the f block. These elements fill up the 4f sublevel.

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This material was adapted from the original CK-12 book that can be found here. This work is licensed under the Creative Commons Attribution-Share Alike 3.0 United States License