The crystal field splitting energy for octahedral`(Delta_(0))` and tetrahedral `(Delta_(t))` complexes is related as .

The magnitude of crystal field stabilisation energy (CFSE of Delta_(1) ) in tetrahedral complexes is considerably less than that in the octahderal field. Because

The magnitude of crystal field stabilisation energy (CFSE of Delta_(1) ) in tetrahedral complexes is considerably less than that in the octahderal field. Because

Crystal field splitting energey (CFSE) for the complex [Fe(CN)_(4)]^(Θ) is when DeltagtP .

STATEMENT-1: Tetrahedral complexes are always high spin complexes . STATEMENT-2: Crystal field splitting energy in tetrahedral complexes is 2/3 of the Delta_(0) (crystal field splitting energy in octahedral complexes). STATEMENT-3: Tetrahedral complex [MABCD]^(pm n) is optically active .

In which structure crystal field splitting energey (CFSE) for octahedral complex will be zero when DeltaltP .

What is the crystal field stabalisation energy value of d^(5) configuration for tetrahedral complex ?

Corystal field splitting energy (CFSE) for the complex [Cr(H_(2)O)_(6)]^(2+) is when (DeltaltP) .

Crystal field stabilization energy for high spin d^4 octahedral complex is

The values of the crystal field stabilization energies for a high spin d^6 metal ion in octahedral and tetrahedral fields, respectively, are :

Crystal field splitting energy (CFSE) for the complex [Cr(NH_(3))_(6)]^(2+) is (when Delta gtP ) .