The `HF_(2)^(Θ)` ion solid state and in liquid `HF` but not in the dilute aqueous solution
Energy of H-bond is maximum in .

The HF_(2)^(Θ) ion solid state and in liquid HF but not in the dilute aqueous solution In aqueous solution

The HF_(2)^(Θ) ion solid state and in liquid HF but not in the dilute aqueous solution HF_(2)^(Θ) exists in solid state and in liquid HF because HF_(2)^(Θ) ions are held together by .

The HF_(2)^(Θ) ion solid state and in liquid HF but not in the dilute aqueous solution At 300 K and 1.00 atm, the density of HF is 3.17 gL^(-1) We conclude that there is a .

The HF_(2)^(Θ) ion solid state and in liquid HF but not in the dilute aqueous solution Consider the following molecules . A :Anti -pyridine -2-carboxaldoxime B :syn pyridine -2-carboaxaldoxime C : nickel -dimethyl glyoximate C : nickel-dimethyl glyoximate D : o-nitrophenol intermolecular hydrogen bonding (inQ.5) is observed in .

The HF_(2)^(Θ) ion solid state and in liquid HF but not in the dilute aqueous solution Consider the following molecules . A :Anti -pyridine -2-carboxaldoxime B :syn pyridine -2-carboaxaldoxime C : nickel -dimethyl glyoximate C : nickel-dimethyl glyoximate D : o-nitrophenol E : p-nitrophenol F : p-salicylaldehyde In which case chelate formation occurs ? .

To explain the abnormality in some molecules , the conecpt of H-bonding was introduced , Hydrogen bonding is defined as the phenomenon in which H-bonding beteen two molecules is called intermolecular H-bonding between two molecules is called intermolecular H-bonding .Hbonding within a molecule is called intramolecular H-bonding or within a molecule is called intramolecular H-bonding or chelation .Intermolecular H-bonding favoure for cluster formation whereas intramolecular H-bnding prevents the cluster formation HF_2^- exists in solid state and in liquid HF but bot in aqueous solution because :