Bromine is non-polar.
Polar- chlorine and bromine have different electronegativities.
Bromine gas is non-polar because it has a symmetrical arrangement of its atoms, resulting in a balanced distribution of charge. This symmetry cancels out any dipole moment, making the molecule non-polar.
Br2 (Bromine gas) is a nonpolar molecule because the two bromine atoms have the same electronegativity, resulting in a balanced distribution of electrons and no net dipole moment.
Elemental bromine would be expected to be soluble in hexane. Bromine, Br2(l), is non-polar; hexane, C6H14(l) is also non-polar. Like dissolves like.
A bromine-bromine covalent bond would be non-polar, because the two atoms in the bond have the same electronegativity (ability to pull electrons towards themselves).
Any two identical atoms must necessarily have non-polar bonds. Polarity is caused by differences in electronegativity between the atoms (in other words, one atom attracts electrons more than the other).
Br2 is non polar covalent
Bromine (Br2) dissolves in cyclohexane due to its nonpolar nature, which is similar to cyclohexane's nonpolar composition. In contrast, bromine does not dissolve in water because water is a polar solvent and bromine is nonpolar, leading to poor solubility due to the mismatch in polarity.
Bromine and iodine are both nonpolar molecules because they consist of two identical atoms, so there is no significant difference in electronegativity between them. This results in a symmetric distribution of electrons and a lack of partial charges on the atoms, making them nonpolar.
Bromine is a polar molecule because it contains two different atoms (bromine and hydrogen) with different electronegativities. This causes an uneven distribution of electron density, resulting in a slight negative charge on the bromine atom and a slight positive charge on the hydrogen atom, making the molecule polar.
If the difference in electronegativity is greater than 0.3 than it is Polar. Nitrogen and Bromine the difference is less than .3 so it is nonpolar
SBr2 is a polar molecule. This is because the S-Br bonds are polar due to the difference in electronegativity between sulfur and bromine. Additionally, the shape of the molecule is angular, which results in an uneven distribution of electron density, making it polar overall.