180°
linear
The electron pair geometry for CS2 is Linear.
Linear
The molecular geometry of a molecule with two electron groups composed only of bonded pairs is linear. This occurs because the two bonding pairs are positioned 180 degrees apart to minimize electron pair repulsion, resulting in a straight-line arrangement. An example of such a molecule is carbon dioxide (CO₂).
sp, linear, linear
linear
The electron pair geometry for CS2 is Linear.
The electron pair geometry of C2H2 is linear.
The molecular geometry for a molecule with two electron groups and only bonded pairs is linear.
Linear
The electron domain geometry of XeF2 is linear. This is because the central atom Xe has two bonded atoms (F) and no lone pairs of electrons, resulting in a linear molecular geometry.
The electron domain geometry for CS2 is linear, as sulfur has two bonding pairs and no lone pairs of electrons around it.
The electron-pair geometry of CS2 is linear because the Lewis structure is S=C=S. Double bonds act as one electron pair to help determine electron-pair geometries of molecules according to VESPR theory
sp, linear, linear
The hybridization of the valence electrons on the nitrogen atom in NO+ is sp. The electron pair geometry is linear, and the shape of the ion is also linear.
tetrahedral, if it had three electron groups it would be trigonal planar
In hydrochloric acid, the hydrogen atom orients itself as far away as possible from each other due to the principle of electron repulsion. Hydrogen atoms in a molecule will position themselves to minimize repulsion between their electron clouds, leading to a linear molecular geometry in the case of HCl.