octahedral
electron-pair geometry is octahedral with no LPs and the molecule geometry is octahedral
its a trigonal pyramid but it can also be tetrahedral because it has a lone pair of electron bonded to the centrel atom (P)
noncoplaner
Basic geometry terms are lines, points segments and rays, so it should be "point".
q p r s t u v w x y z are the alphabets for logic branch of mathematics in fact logic and geometry help each other a lot
electron-pair geometry is octahedral with no LPs and the molecule geometry is octahedral
The PF6⁻ ion consists of one phosphorus (P) atom and six fluorine (F) atoms. Phosphorus has 5 valence electrons, and each fluorine atom has 7 valence electrons, contributing a total of 42 electrons from the six fluorine atoms. Adding the 5 from phosphorus and accounting for the extra electron due to the negative charge, the total number of valence electrons in PF6⁻ is 48.
lone-pair electronsbonded pairs of electronsi hate apextrue dat >~>S and P OrbitalsBonded pairs of electrons, Lone-pair electrons
It should be sp3d. first draw the Lewis structure. then you can see the central S atom has 4 bonding pair and 1 lone pair. then draw molecular orbital. Distribute electron according the bonding and lone pair. the paired electron represent lone pair in Lewis structure. and the other unpaired electron distribute in the molecular orbital represent the number of bonding pair in Lewis structure
Ionization is the process of removing one or more electrons from a neutral atom. This results in the loss of units of negative charge by the affected atom. The atom becomes electrically positive (a positive ion). The products of a single ionizing event are called an electron-ion pair.
its a trigonal pyramid but it can also be tetrahedral because it has a lone pair of electron bonded to the centrel atom (P)
In p-type semiconductors, electron-hole pairs can be created at room temperature by thermal excitation. When a hole is created by an electron moving from the valence band to the conduction band, a corresponding electron-hole pair is formed. This process can occur due to energy supplied by thermal vibrations even at room temperature.
The electron dot structure for PH3, or phosphine, is H: :P: :H: :H. It shows phosphorus in the center with three pairs of dots representing the three hydrogen atoms bound to it. Each hydrogen atom shares one electron with phosphorus to form a covalent bond.
The shape of the P atom in H2PO4 is tetrahedral. It has four electron domains around it, leading to a tetrahedral molecular geometry.
Lone pairs in p orbitals can affect the molecular geometry of a compound by influencing the bond angles and overall shape of the molecule. The presence of lone pairs can cause repulsion between electron pairs, leading to distortions in the molecule's geometry. This can result in deviations from the ideal bond angles predicted by the VSEPR theory, ultimately affecting the overall shape of the molecule.
~e → p
n[p