F Block Elements

F block elements are divided into two series, namely lanthanoids and actinoids. This block of elements are often referred to as inner transition metals because they provide a transition in the 6th and 7th row of the periodic table, which separates the s block and the d block elements.

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Classification
Inner Transition Elements
Properties
Difference between Lanthanides and Actinides
FAQs

What Are F Block Elements?

Elements whose f orbital gets filled up by electrons are called f block elements. These elements have electrons (1 to 14) in the f orbital, (0 to 1) in the d orbital of the penultimate energy level and in the outermost orbital.

There are two series in the f block corresponding to the filling up of 4f and 5f orbitals. The elements are the 4f series of Ce to Lu and the 5f series of Th to Lw. There are 14 elements filling up the ‘f’ orbital in each series.

F Block Elements

The position of F block elements in the periodic table: F block elements are placed separately at the bottom of the periodic table. They are a subset of the 6th and 7th periods.

Classification of F Block Elements

The elements belonging to the f block are further classified into lanthanides and actinides.

The first series of elements are called lanthanides and include elements with atomic numbers beginning from 57 and ending at 71. These elements are non-radioactive (except for promethium, which is radioactive).
The second series of elements are called actinides and include elements with atomic numbers beginning from 89 and ending at 103. These elements generally have a radioactive nature.

The list of all the f block elements is provided below. The row beginning with lanthanum is the row containing all the lanthanides, whereas the row beginning with actinium is the row that contains all the actinides.

F block Elements as Inner Transition Elements

Since the f orbital lies much inside than the d orbital, in relation to the transition metals naming, f block elements are called inner transition elements.

Properties of F block Elements

They have electrons added to the ‘f’ sub-orbitals of (n-2) level
They are placed between (n-1)d and ns block elements in the periodic table.
Properties are similar to d-block elements.

Properties of Lanthanides

Lanthanides are soft metals with a silvery-white colour.
Their colour dulls, and their brightness reduces rapidly when exposed to air.
They have melting points ranging from 1000K to 1200K (Except Samarium, 1623K).
Lanthanides are good conductors of heat and electricity.
They are non-radioactive in nature except the promethium
A decrease in atomic and ionic radii from lanthanum to lutetium is observed. This is called the lanthanoid contraction.

Properties of Actinides

The Actinide elements appear to be silvery.
These elements have a radioactive nature.
These metals are highly reactive, and their reactivity increases when they are finely divided.
A decrease in atomic and ionic radii from Actinium to Lawrencium is observed. This is called the actinoid contraction.
They generally exhibit an oxidation state of +3. However, elements belonging to the first half of the series are known to exhibit higher oxidation states quite frequently.

Difference between Lanthanides and Actinides

Lanthanoids are involved in the filling of 4f orbitals, whereas actinoids are involved in the filling of 5f orbitals. The binding energy of 4f electrons is comparatively less than that of 5f electrons. The shielding effect of 5f electrons is less effective as compared to that of 4f electrons.
The paramagnetic properties of lanthanoids can be easily explained, but this explanation is difficult in the case of actinoids.
Lanthanides are non-radioactive in nature except promethium, whereas all actinide series elements are radioactive.
Lanthanides do not have a tendency to form oxo-cations, but several oxo-cations of actinide series exist. The compounds formed by lanthanides are less basic; on the other hand, the compounds of actinides are highly basic.

Similarities between Lanthanides and Actinides

The elements of lanthanide and actinide series are characterised by filling of (n-2) f subshell. They possess almost similar outermost electronic configurations and hence have similar properties. The following are the significant similarities:

Both have a prominent oxidation state of +3.
They are involved in the filling of (n-2) f orbitals.
They are highly electropositive and very reactive in nature.
With an increase in atomic number, there is a decrease in atomic and ionic size.
Both show magnetic properties.

Frequently Asked Questions

What metals are in the F block?
Why are F block elements placed separately?
Are all F block elements radioactive?
What is the last element of the F block?
What are the characteristics of F block elements?
What is the electronic configuration of F block elements?
What are lanthanides and actinides called?
Why are F block elements called inner transition elements?

D and F block Elements – Oxidation States

15 Important Questions on D Block and F Block Elements

Alloy Formation of d & f Block Elements

Colour of ions in d and f block elements

Frequently Asked Questions (FAQs)

Name two metals in F block elements that are colourless.

Lanthanum and Cerium are colourless metals in the F block series.

Are all F block elements radioactive?

No, F block elements are not radioactive except for the element Promethium (Pm).

Which is the last element of F block elements?

Lawrencium (Lr) is the last element of the F block series.

What is the general electronic configuration of F-block elements?

The general electronic configuration of F-Block elements is (n-2)f^0-1(n-1)d^(0-1)ns².

Why are F block elements called inner transition elements?

F block elements are called inner transition elements because the last electron enters the anti-penultimate shell, which is inner to the penultimate shell in which the last electron of d-block elements enters. Thus, D block elements are called transition elements, and F block elements are called inner transition elements.

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