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No, carbon disulfide (CS2) is not miscible in water. This is because CS2 is a nonpolar compound while water is a polar molecule. Nonpolar and polar molecules do not mix easily due to their differing intermolecular forces.
Intermolecular forces are of the type(1) hydrogen bonds (2) dipole-dipole attractions (3) dispersion forces (van der Waals, etc.)
The dominant intermolecular forces in octane are London dispersion forces. These are relatively weak forces that result from temporary fluctuations in electron distribution within atoms and molecules.
Dispersion forces (London dispersion forces) are generally the weakest type of intermolecular force. These forces are caused by temporary fluctuations in electron distribution around atoms or molecules, leading to weak attractions between them.
Bonding affects intermolecular forces by influencing the strength of attractions between molecules. Covalent bonds within molecules contribute to intramolecular forces, while intermolecular forces, such as hydrogen bonding or van der Waals forces, occur between molecules. The type and strength of bonding within a molecule can impact the overall intermolecular forces affecting its physical properties.
Of CO2, CS2 and CSe2, CO2 is the smallest molecule whereas CSe2 is the largest molecule. The same pattern exists in the strength of the intermolecular forces. All three are linear, non polar molecules.
No, carbon disulfide (CS2) is not miscible in water. This is because CS2 is a nonpolar compound while water is a polar molecule. Nonpolar and polar molecules do not mix easily due to their differing intermolecular forces.
Dipole forces and London forces are present between these molecules.
CaO has a higher melting point than CS2. CaO (calcium oxide) is an ionic compound with strong electrostatic forces between its ions, resulting in a higher melting point. CS2 (carbon disulfide) is a covalent compound with weaker intermolecular forces, leading to a lower melting point.
CaO (calcium oxide) has a higher melting point than CS2 (carbon disulfide). This is because CaO is an ionic compound with strong electrostatic forces between ions, while CS2 is a covalent compound with weaker intermolecular forces.
Intramolecular forces are not intermolecular forces !
CS2 has stronger intermolecular forces, which result in a higher boiling point compared to CO2. CS2 molecules are more polarizable due to the presence of sulfur, leading to stronger London dispersion forces. As a result, CS2 exists as a liquid at room temperature while CO2, being nonpolar, exists as a gas.
Both CO2 and CS2 are held by Van der Waals' forces but CO2 has a smaller number of electrons than CS2.This leads to weaker forces between the molecules .Therefore, CO2 is a gas while CS2 is a liquid.
London forces are present in chlorine molecules.
CS2 is a liquid at room temperature due to its molecular structure and intermolecular forces. The linear structure of the CS2 molecule allows for strong van der Waals forces between molecules, keeping them close together and in a liquid state at room temperature. Additionally, the presence of polar covalent bonds in the CS2 molecule contributes to its liquid state.
Intermolecular forces are of the type(1) hydrogen bonds (2) dipole-dipole attractions (3) dispersion forces (van der Waals, etc.)
The dominant intermolecular forces in octane are London dispersion forces. These are relatively weak forces that result from temporary fluctuations in electron distribution within atoms and molecules.