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Both the pure hydrogen and hydrogen bromide is held by weak intermolecular forces of attaction between molecules. Bromide has larger size of electron cloud than Hydrogen, leading to a greater extent of polarisation of the electron cloud. This results in stronger van der Waals' forces of attraction in hydrogen bromide compared to the pure hydrogen. More energy is required to break the stronger bonds in hydrogen bromide than pure hydrogen, leading to a higher boiling point in hydrogen bromide. Thus, pure hydrogen has a lower boiling point.

Explanation:

the strength of intermolecular forces of attraction rely on the size of the electron cloud. the greater the atomic number, the greater the size of the electron cloud and thus, the stronger the forces of attraction.

When asnwering a qn, you want to first state the structure and bonding of the compound, then compare the size of their electron clouds.

Answer structure:

greater size of electron clouds -> greater extent of polarisation of electron cloud -> stronger van der Waals' forces of attraction -> more energy required to overcome the bonds -> higher boiling point

Pure hydrogen has a lower boiling point than hydrogen bromide due to weak intermolecular forces.

What are intermolecular forces?

Intermolecular forces are those forces which binds different molecules all together.

Bromide's electron cloud is larger than Hydrogen's, resulting in more polarisation of the electron cloud. In comparison to pure hydrogen, hydrogen bromide has greater van der Waals forces of attraction. Because the stronger bonds in hydrogen bromide need more energy to break than pure hydrogen, it has a higher boiling point. Pure hydrogen has a lower boiling point as a result.

Hence due to less intermolecular forces hydrogen bromide has a lower boiling point.

To know more about intermolecular forces, visit the below link:
https://brainly.com/question/13588164

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