The p-block elements are arranged in groups of 13 to 18 on the periodic table’s right side. The separating electron reaches the valence p sub shell in the iotas of p-block elements. The n p subshell is gradually filled with these elements in this manner.
The electrical arrangement of group fifteen elements is ns2, np1-6 in general. Helium has a 1s2 electrical design. Despite the fact that helium lacks p orbitals, it is a p-block element since its physical and chemical characteristics are similar to those of other p-block elements in the eighteenth group. Non-metals make up the majority of the P-block elements, while metalloids and metals make up the rest.
Nitrogen is a major component of the world’s air, accounting for 78 per cent of the total volume. It is the most common member of this group and occurs naturally as a diatomic gas, N2. Indian saltpetre and Chile saltpetre are nitrogen minerals.
Proteins, nucleic acids, amino acids, and catalysts all include it as an essential element. Phosphorus is the next element in the group.In the earth’s crust, it is the tenth most prevalent element. It occurs as minerals as phosphates in the consolidated state. Fluoroapatite, Chlorapatite, and Hydroxyapatite are just a few examples.
Phosphorus is a mineral that is found in both animal and plant materials. Nucleic acids, such as DNA and RNA, are made up of phosphate groups. Phosphates make up around 60% of bones and teeth. Phosphoproteins can be found in egg yolk, milk, and bone marrow. The rest of the group’s elements, such as arsenic, antimony, and bismuth, are primarily found as sulphides. Stibnite, arsenopyrite, and bismuth glance are examples.
In group 15 elements, the separating electron enters the n p sub shell. As a result, the electronic valence shell configuration for these elements is ns2 np3. The valence shell of these elements has five electrons. The components of this group are really steady and stable due to the perfectly half-filled electrical arrangement of the ‘n p’ subshell. Under normal circumstances, dinitrogen is an inactive gas.
As the size of the nucleus grows larger, the melting point shifts from nitrogen to arsenic. Nitrogen has a low melting point due to its unique diatomic particles. Arsenic, on the other hand, has a high melting point due to its goliath layered structure, in which the layers are tightly packed together.
The melting temperatures of nuclear nuclei decrease as the size of the nuclei grows from arsenic to antimony. Due to the overall free pressing of particles, antimony has a lower melting point than arsenic, despite its layered structure.
All of the group’s fifteen elements, with the exception of bismuth, exhibit allotropy. Alpha nitrogen and beta nitrogen are the two allotropic structures of nitrogen. Phosphorus comes in a wide range of allotropic forms. The two most significant allotropic structures are red and white phosphorus.
There are three allotropic forms of arsenic: black, grey, and yellow. Antimony is also available in three allotropic forms: yellow, metallic, and explosive.
In the outermost circle of each element in group 15, there are 5 electrons. To complete their octet structure, they only require three electrons. The octet can be formed by either picking up three electrons or sharing three electrons via a covalent binding mechanism. As a result, these elements’ fundamental negative oxidation state is – 3. The likelihood of displaying a – 3 oxidation state decreases as one moves along the group. This is due to the growth of nuclear size and the metallic nature of the nucleus.
By forming covalent bonds, Group 15 elements also show positive oxidation states of +3 and +5. Because of the inert pair effect, the stability of the +5 oxidation state decreases as one moves down the group, whereas the stability of the +3 oxidation state increases.
In its valence shell, nitrogen possesses only s- and p-orbitals, but no d-orbitals. As a result, nitrogen has a covalency of 4 at its most severe. The sharing of its lone pair of electrons with another iota or particle results in a covalency of four.
Phosphorus and the other elements have a covalency of five and a most severe covalency of six, which is also known as extended covalency. This is possible because of the close proximity of vacant d-orbitals in the valence shell. Every group 15 element compound with a +5 oxidation state is covalent.
Melting point (the amount of energy required to break bonds in order to convert a solid phase material to a liquid phase substance) rises as the group progresses. The amount of energy required to break bonds and convert a liquid phase material to a gas grows as the group progresses.
The reactivity of the heavier group 15 elements, as well as the stability of their catenated compounds, declines as they go through the group. In group 15, nitrogen and phosphorus act as nonmetals, whereas arsenic and antimony act as semimetals and bismuth acts like a metal.
With increasing atomic size, the electronegativity value drops along with the group. As we advance down the group, the distance between the nucleus and the valence shell becomes longer.