Tetrahedral
The electron-domain geometry of ClO4- is tetrahedral. It has four electron domains around the central chlorine atom, resulting in a tetrahedral arrangement.
The electron domain geometry for CS2 is linear, as sulfur has two bonding pairs and no lone pairs of electrons around it.
Yes, hydrogen sulfide is a covalent compound.
The bond angle in H2S (92 degrees) is less than in H2O (104.5 degrees) due to the larger size of sulfur compared to oxygen. The larger size of sulfur results in weaker repulsions between the electron pairs, causing the bond angle to be smaller in H2S compared to H2O.
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.
Tetrahedral
There are two electron groups around the central sulfur atom in H2S. This gives H2S a bent molecular geometry.
It has a bent structure just like the H2O and H2S.
The electron-domain geometry of PF6 is Octahedral, since the central atom Phosphorus has an electron pair geometry which is octahedral
Electron Domain is Tetrahedral Molecular Geometry is Trigonal Pyramidal
H2=2 And S=6 So2+6=8
The electron-domain geometry of ClO4- is tetrahedral. It has four electron domains around the central chlorine atom, resulting in a tetrahedral arrangement.
The electron domain charge cloud geometry of ICI5 s usually positively charged. This is because the process involves the loss of electrons. The electron-domain charge-cloud geometry of ICl5 is octahedral.
3 bondings + 1 electron pair = 4 (electron domains)
tetrahedral
Tetrahedral
tetrahedral