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प्रश्न
Explain the formation of H2 molecule on the basis of valence bond theory.
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उत्तर १
Let us consider the combination between atoms of hydrogen HA and HB and eA and eB be their respective electrons.
As they tend to come closer, two different forces operate between the nucleus and the electron of the other and vice versa. The nuclei of the atoms as well as their electrons repel each other. Energy is needed to overcome the force of repulsion. Although the number of new attractive and repulsive forces is the same, but the magnitude of the attractive forces is more. Thus, when two hydrogen atoms approach each other, the overall potential energy of the system decreases. Thus, a stable molecule of hydrogen is formed.
उत्तर २
Let us assume that two hydrogen atoms (A and B) with nuclei (NA and NB) and electrons (eA and eB) are taken to undergo a reaction to form a hydrogen molecule.
When A and B are at a large distance, there is no interaction between them. As they begin to approach each other, the attractive and repulsive forces start operating.
- Attractive force arises between:
- Nucleus of one atom and its own electron i.e., NA – eA and NB – eB.
- Nucleus of one atom and electron of another atom i.e., NA – eB and NB – eA.
- Repulsive force arises between:
- Electrons of two atoms i.e., eA – eB.
- Nuclei of two atoms i.e., NA – NB.
The force of attraction brings the two atoms together, whereas the force of repulsion tends to push them apart.
The magnitude of the attractive forces is more than that of the repulsive forces. Hence, the two atoms approach each other. As a result, the potential energy decreases. Finally, a state is reached when the attractive forces balance the repulsive forces and the system acquires minimum energy. This leads to the formation of a dihydrogen molecule.
संबंधित प्रश्न
Draw an orbital diagram of Fluorine molecule
Distinguish between sigma and pi bond.
Give a reason for carbon is tetravalent in nature.
Complete the following Table.
| Molecule | Type of Hybridization | Type of bonds | Geometry | Bond angle |
| CH4 | - | 4C-H 4σ bonds |
Tetrahedral | - |
| NH3 | sp3 | 3N-H 3σ bonds 1 lone pair |
- | - |
| H2O | - | - | angular | 104.5° |
| BF3 | sp2 | - | - | 120° |
| C2H4 | - | - | - | 120° |
| BeF2 | - | 2 Be-F | Linear | - |
| C2H2 | sp | (3σ+2π) 1C-C σ 2C-H σ 2C-C π |
- | - |
Give the type of overlap by which the pi (π) bond is formed.
Mention the steps involved in Hybridization.
Which one of the following is the likely bond angles of sulphur tetrafluoride molecule?
In ClF3, NF3 and BF3 molecules the chlorine, nitrogen and boron atoms are ______.
When ones and three p orbitals hybridise,
Which of these represents the correct order of their increasing bond order.
What is a pi - bond?
Which bond is stronger σ or π? Why?
Considering x-axis as the molecular axis which out of the following will form a sigma bond.
2px and 2py
Considering x-axis as the molecular axis which out of the following will form a sigma bond.
2px and 2pz
The number of sigma bonds in vanillin is ____________.
The overlap of orbitals involved in the formation of C - Br bond in vinyl bromide is ______.
Why does type of overlap given in the following figure not result in bond formation?
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Briefly describe the valence bond theory of covalent bond formation by taking an example of hydrogen. How can you interpret energy changes taking place in the formation of dihydrogen?
